[1].Xu Ruibin, et al."A C-Terminal Encoded Peptide, ZmCEP1, is essential for kernel development in maize (Zea mays L.).." Journal of experimental botany 72.15(2021): doi:10.1093/JXB/ERAB224.(IF5.557)

[2].Wen Shaozhe, et al."A Major Quantitative Trait Loci Cluster Controlling Three Components of Yield and Plant Height Identified on Chromosome 4B of Common Wheat ." Frontiers in Plant Science .(2022): doi:10.3389/FPLS.2021.799520.(LA-S,IF4.568)

[3].Yuan Hua, et al."A natural allele of TAW1 contributes to high grain number and grain yield in rice." The Crop Journal 9.5(2021): doi:10.1016/J.CJ.2020.11.004.(SC-G)

[4].Liu Jiajia, et al."A promising crop for cadmium-contamination remediation: Broomcorn millet.." Ecotoxicology and environmental safety 224.(2021): doi:10.1016/J.ECOENV.2021.112669.(LA-S,IF5.248)

[5].Meng Tianyao, et al."Agronomic and physiological traits facilitating better yield performance of japonica/indica hybrids in saline fields." Field Crops Research 271.(2021): doi:10.1016/J.FCR.2021.108255.(LA-S,IF4.856)

[6].Ren Xiaoli, et al."Alternative Splicing of TaGS3 Differentially Regulates Grain Weight and Size in Bread Wheat." International Journal of Molecular Sciences 22.21(2021): doi:10.3390/IJMS222111692.(SC-G,IF4.602)

[7].Han, Xia, et al."Arbuscular Mycorrhizal Fungus and Exogenous Potassium Application Improved Lycium barbarum Salt Tolerance." Journal of Plant Growth Regulation .prepublish(2021): doi:10.1007/S00344-021-10489-X.(IF2.751)

[8].Li Yan, et al."Blocking miR530 Improves Rice Resistance, Yield, and Maturity ." Frontiers in Plant Science 12.(2021): doi:10.3389/FPLS.2021.729560.(SC-A,IF4.568)

[9].Li Yan, et al."Blocking Osa-miR1871 enhances rice resistance against Magnaporthe oryzae and yield.." Plant biotechnology journal .(2021): doi:10.1111/PBI.13743.(IF8.738)

[10].Jing Fanli, et al."Characterization of TaSPP-5A gene associated with sucrose content in wheat (Triticum aestivum L.)." BMC Plant Biology 22.1(2022): doi:10.1186/S12870-022-03442-X.(IF3.695)

[11].Dong Shiqing, et al."Cloning and functional analysis of LH2, a gene controlling late heading in rice." Crop Science 61.4(2021): doi:10.1002/CSC2.20501.(SC-G,IF2.003)

[12].Shi Shijie, et al."Comprehensive Evaluation of 17 Qualities of 84 Types of Rice Based on Principal Component Analysis." Foods 10.11(2021): doi:10.3390/FOODS10112883.(SC-E)

[13].Riaz Aamir, et al."Development of Chromosome Segment Substitution Lines and Genetic Dissection of Grain Size Related Locus in Rice." Rice Science 28.4(2021): doi:10.1016/J.RSCI.2021.05.003.

[14].Zheng Shilu, et al."Disentangling biotic and abiotic drivers of intraspecific trait variation in woody plant seedlings at forest edges." Ecology and Evolution 11.14(2021): doi:10.1002/ECE3.7799.(LA-S,IF2.621)

[15].Gao Yutian, et al."Dissecting the genetic basis of grain morphology traits in Chinese wheat by genome wide association study." Euphytica 217.4(2021): doi:10.1007/S10681-021-02795-Y.(SC-A,IF1.697)

[16].Xue Pao, et al."Dissection of Closely Linked Quantitative Trait Locis Controlling Grain Size in Rice ." Frontiers in Plant Science .(2022): doi:10.3389/FPLS.2021.804444.(SC-G,IF4.568)

[17].Li Shunda, et al."Dissection of Genetic Basis Underpinning Kernel Weight-Related Traits in Common Wheat." Plants 10.4(2021): doi:10.3390/PLANTS10040713.(SC-G)

[18].Niu Xiaojun, et al."Dissection of two quantitative trait loci for grain length linked on the long arm of chromosome 5 in rice." Crop Science 61.6(2021): doi:10.1002/CSC2.20633.(SC-G,IF2.003)

[19].Dai Shutao, et al."Diversity and association analysis of important agricultural trait based on miniature inverted-repeat transposable element specific marker in Brassica napus L.." Oil Crop Science 6.1(2021): doi:10.1016/J.OCSCI.2021.03.004.(SC-G)

[20].Liu Jing, et al."Ectopic Expression of VRT-A2 Underlies the Origin of Triticum polonicum and T. petropavlovskyi with Long Outer Glume and Grain.." Molecular plant 14.9(2021): doi:10.1016/J.MOLP.2021.05.021.(SC-G,IF11.631)

[21].Li Lin, et al."Effects of nitrogen deep placement coupled with straw incorporation on grain quality and root traits from paddy fields." Crop Science 61.5(2021): doi:10.1002/CSC2.20578.(SC-E,IF2.003)

[22].Yang Desheng, et al."Effects of nitrogen fertilization for bud initiation and tiller growth on yield and quality of rice ratoon crop in central China." Field Crops Research 272.(2021): doi:10.1016/J.FCR.2021.108286.(SC-E,IF4.856)

[23].Li Bo, et al."Effects of Ridge Tillage and Straw Mulching on Cultivation the Fresh Faba Beans." Agronomy 11.6(2021): doi:10.3390/AGRONOMY11061054.(LA-S)

[24].Gao Runhong, et al."Enhancement of root architecture and nitrate transporter gene expression improves plant growth and nitrogen uptake under long-term low-nitrogen stress in barley (Hordeum vulgare L.) seedlings." Plant Growth Regulation 95.3(2021): doi:10.1007/S10725-021-00744-2.(LA-S,IF2.483)

[25].Sun, Guangyan, et al."Exogenous Hemin Optimized Maize Leaf Photosynthesis, Root Development, Grain Filling, and Resource Utilization on Alleviating Cadmium Stress Under Field Condition." Journal of Soil Science and Plant Nutrition .prepublish(2021): doi:10.1007/S42729-021-00674-Y.(IF2.516)

[26].Yuzhan Li, et al."Exogenous Melatonin and Catechol Application Modulate Physio-Biochemical Attributes and Early Growth of Fragrant Rice Under Cd Toxicity." Journal of Soil Science and Plant Nutrition .prepublish(2021): doi:10.1007/S42729-021-00521-0.(LA-S,IF2.516)

[27].Potcho Pouwedeou Mouloumdema, et al."Fertilizer Deep Placement Significantly Affected Yield, Rice Quality, 2-AP Biosynthesis and Physiological Characteristics of the Fragrant Rice Cultivars." Agronomy 12.1(2022): doi:10.3390/AGRONOMY12010162.(SC-E)

[28].Yuchun Rao, et al."Fine mapping and candidate gene analysis of leaf tip premature senescence and Dwarf Mutant dls-1 in Rice." Plant Growth Regulation .prepublish(2021): doi:10.1007/S10725-021-00715-7.(SC-G,IF2.483)

[29].Yuan Hua, et al."Fine mapping and candidate gene analysis of qGSN5, a novel quantitative trait locus coordinating grain size and grain number in rice.." TAG. Theoretical and applied genetics. Theoretische und angewandte Genetik 135.1(2021): doi:10.1007/S00122-021-03951-7.

[30].Zhao Dehui, et al."Fine mapping and validation of a major QTL for grain weight on chromosome 5B in bread wheat.." TAG. Theoretical and applied genetics. Theoretische und angewandte Genetik 134.11(2021): doi:10.1007/S00122-021-03925-9.(SC-G)

[31].Chen Jin Feng, et al."Fine-Tuning Roles of Osa-miR159a in Rice Immunity Against Magnaporthe oryzae and Development." Rice 14.1(2021): doi:10.1186/S12284-021-00469-W.(SC-A,IF4.072)

[32].Meng Tianyao, et al."Genetic Improvement of Post-Heading Root Morphology and Physiology Facilitating Yield Increase of japonica Inbred Rice." Agronomy 11.12(2021): doi:10.3390/AGRONOMY11122457.(LA-S)

[33].Qu Xiangru, et al."Genetic Mapping and Validation of Loci for Kernel-Related Traits in Wheat (Triticum aestivum L.) ." Frontiers in Plant Science 12.(2021): doi:10.3389/FPLS.2021.667493.(SC-A,IF4.568)

[34].Kang Yiwei, et al."Genetic Mapping of Grain Shape Associated QTL Utilizing Recombinant Inbred Sister Lines in High Yielding Rice (Oryza sativa L.)." Agronomy 11.4(2021): doi:10.3390/AGRONOMY11040705.

[35].Gao Le, et al."Genome–wide association study of grain morphology in wheat." Euphytica 217.8(2021): doi:10.1007/S10681-021-02900-1.(SC-A,IF1.697)

[36].Wang Aijun, et al."Genome-wide association study-based identification genes influencing agronomic traits in rice (Oryza sativa L.)." Genomics 113.prepublish(2021): doi:10.1016/J.YGENO.2021.03.016.(SC-G)

[37].Zhanying Zhang, et al."GNP6 , a novel allele of MOC1 , regulates panicle and tiller development in rice." The Crop Journal .prepublish(2020): doi:10.1016/j.cj.2020.04.011.(SC-G)

[38].Chen Lin, et al."Growth and Nitrogen Retranslocation of Nutrient-Loaded Clonal Betula alnoides Transplanted with or without Fertilization." Forests 12.11(2021): doi:10.3390/F12111603.(LA-S,IF2.317)

[39].Li Fei, et al."High-Quality Genomes and High-Density Genetic Map Facilitate the Identification of Genes From a Weedy Rice ." Frontiers in Plant Science 12.(2021): doi:10.3389/FPLS.2021.775051.(IF4.568)

[40].Zhang Youfu, et al."Identification and development of a KASP functional marker of TaTAP46‐5A associated with kernel weight in wheat (Triticum aestivum)." Plant Breeding 140.4(2021): doi:10.1111/PBR.12922.(SC-G,IF1.794)

[41].Ji Guangsi, et al."Identification of a major and stable QTL on chromosome 5A confers spike length in wheat (Triticum aestivum L.)." Molecular Breeding 41.9(2021): doi:10.1007/S11032-021-01249-6.(SC-E,IF2.208)

[42].Zhang Jinpeng, et al."Identification of Genetic Loci on Chromosome 4B for Improving the Grain Number per Spike in Pre-Breeding Lines of Wheat." Agronomy 12.1(2022): doi:10.3390/AGRONOMY12010171.(SC-E)

[43].Liang Dangdi, et al."Increasing the performance of Passion fruit (Passiflora edulis) seedlings by LED light regimes." Scientific Reports 11.1(2021): doi:10.1038/S41598-021-00103-1.(IF4.149)

[44].Li Zhenyi, et al."Integrative analysis of the metabolome and transcriptome reveal the phosphate deficiency response pathways of alfalfa." Plant Physiology and Biochemistry 170.(2022): doi:10.1016/J.PLAPHY.2021.11.039.(LA-S,IF3.983)

[45].Duan Yanan, et al."Isolation, Identification, and Antibacterial Mechanisms of Bacillus amyloliquefaciens QSB-6 and Its Effect on Plant Roots ." Frontiers in Microbiology 12.(2021): doi:10.3389/FMICB.2021.746799.(LA-S,IF4.443)

[46].Yang Yang, et al."Large-scale integration of meta-QTL and genome-wide association study discovers the genomic regions and candidate genes for yield and yield-related traits in bread wheat." Theoretical and Applied Genetics 134.9(2021): doi:10.1007/S00122-021-03881-4.(SC-E,IF4.643)

[47].Hei Zewen, et al."Mix-cropping of rice and water mimosa (Neptunia oleracea Lour.) increases rice photosynthetic efficiency, yield, grain quality and soil available nutrients.." Journal of the science of food and agriculture .(2021): doi:10.1002/JSFA.11744.(SC-E,IF2.802)

[48].Jiang Pingping, et al."Moderate Mn accumulation enhances growth and alters leaf hormone contents in the hyperaccumulator Celosia argentea Linn.." Environmental and Experimental Botany 191.prepublish(2021): doi:10.1016/J.ENVEXPBOT.2021.104603.(SC-E,IF4.173)

[49].Zhang Xia, et al."Molecular cytogenetic characterization of a novel wheat-Thinopyrum intermedium introgression line tolerant to phosphorus deficiency." The Crop Journal .prepublish(2020): doi:10.1016/J.CJ.2020.08.014.(LA-S)

[50].Sun ChenDong, et al."OsRLR4 binds to the OsAUX1 promoter to negatively regulate primary root development in rice.." Journal of integrative plant biology 64.1(2021): doi:10.1111/JIPB.13183.(LA-S,IF6.19)

[51].Liu, J. , et al. "QMrl-7B Enhances Root System, Biomass, Nitrogen Accumulation and Yield in Bread Wheat." Plants 10.4(2021):764.(LA-S)

[52].Ren Tianheng, et al."QTL Mapping and Validation for Kernel Area and Circumference in Common Wheat via High-Density SNP-Based Genotyping ." Frontiers in Plant Science 12.(2021): doi:10.3389/FPLS.2021.713890.(SC-G,IF4.568)

[53].Xu, H. , et al. "Quality Evaluation and Important Quality Genes Genotyping of Introduced Rice Germplasm Resources." Rice Genomics and Genetics (2021).(SC-E)

[54].Cheng Yan, Ya-li Leng,and Jun-ting Wu."Quantitative microbial risk assessment for occupational health of temporary entrants and staffs equipped with various grade PPE and exposed to microbial bioaerosols in two WWTPs." International Archives of Occupational and Environmental Health .prepublish(2021): doi:10.1007/S00420-021-01663-5.(HICC-B,IF2.118)

[55].Wang Can, et al."Responses of photosynthetic characteristics and dry matter formation in waxy sorghum to row ratio configurations in waxy sorghum-soybean intercropping systems." Field Crops Research 263.(2021): doi:10.1016/J.FCR.2021.108077.(SC-G,IF4.856)

[56].Li Yan, et al."Rice miR1432 Fine-Tunes the Balance of Yield and Blast Disease Resistance via Different Modules." Rice 14.1(2021): doi:10.1186/S12284-021-00529-1.

[57].Jian Shao Fen, et al."Sulfur Regulates the Trade-Off Between Growth and Andrographolide Accumulation via Nitrogen Metabolism in Andrographis paniculata ." Frontiers in Plant Science 12.(2021): doi:10.3389/FPLS.2021.687954.(LA-S,4.568)

[58].Mao Ting, et al."Superior japonica rice variety YJ144 with improved rice blast resistance, yield, and quality achieved using molecular design and multiple breeding strategies." Molecular Breeding 41.10(2021): doi:10.1007/S11032-021-01259-4.(IF2.208)

[59].Li Jihu, et al."TaNAC100 acts as an integrator of seed protein and starch synthesis conferring pleiotropic effects on agronomic traits in wheat.." The Plant journal : for cell and molecular biology 108.3(2021): doi:10.1111/TPJ.15485.(SC-G)

[60].Hwa, B , et al. "The boron transporter SiBOR1 functions in cell wall integrity, cellular homeostasis, and panicle development in foxtail millet." The Crop Journal (2021).(SC-G)

[61].Feng, Zhiyu, et al."The decreased expression of GW2 homologous genes contributed to the increased grain width and thousand‑grain weight in wheat-Dasypyrum villosum 6VS·6DL translocation lines." Theoretical and Applied Genetics 134.12(2021): doi:10.1007/S00122-021-03934-8.(IF4.643)

[62].Hao Jianqin, et al."The GW2-WG1-OsbZIP47 pathway controls grain size and weight in rice.." Molecular plant 14.8(2021): doi:10.1016/J.MOLP.2021.04.011.(IF11.631)

[63].Yue Wenjie, et al."The Landscape of Autophagy-Related (ATG) Genes and Functional Characterization of TaVAMP727 to Autophagy in Wheat." International Journal of Molecular Sciences 23.2(2022): doi:10.3390/IJMS23020891.(SC-G,IF4.602)

[64].Ji Chen, et al."The O2-ZmGRAS11 transcriptional regulatory network orchestrates the coordination of endosperm cell expansion and grain filling in maize.." Molecular plant .(2021): doi:10.1016/J.MOLP.2021.11.013.(IF11.631)

[65].Li Yan, et al."The rice miR171b–SCL6-IIs module controls blast resistance, grain yield, and flowering." The Crop Journal 10.1(2022): doi:10.1016/J.CJ.2021.05.004.(SC-A)

[66].Li Huan, et al."Unraveling hydrogen sulfide-promoted lateral root development and growth in mangrove plant Kandelia obovata: Insight into regulatory mechanism by TMT-based quantitative proteomic approaches.." Tree physiology 41.9(2021): doi:10.1093/TREEPHYS/TPAB025.(LA-S,IF3.364)

[67].Liu Jiajia, et al."A promising crop for cadmium-contamination remediation: Broomcorn millet.." Ecotoxicology and environmental safety 224.(2021): doi:10.1016/J.ECOENV.2021.112669.(LA-S,IF5.248)

[68].Shi, Cai Yun, et al."Comparison of drought resistance of rootstocks 'M9-T337' and 'M26' grafted with 'Huashuo' apple." Horticulture, Environment, and Biotechnology .prepublish(2022): doi:10.1007/S13580-021-00398-Z.(IF1.776)

[69].Wang Xiaoqi, et al."Comprehensive Analysis of the Influence of Fulvic Acid from Paper Mill Effluent on Soil Properties, Soil Microbiome, and Growth of Malus hupehensis Rehd. Seedlings under Replant Conditions.." ACS omega 6.37(2021): doi:10.1021/ACSOMEGA.1C03201.(LA-S)

[70]. Zhu, L. , et al. "Development and Application of an in Vitro Method to Evaluate Anthracnose Resistance in Soybean Germplasm." (2021).(LA-S)

[71].Qi Kai, et al."Development and characterization of novel Triticum aestivum-Agropyron cristatum 6P Robertsonian translocation lines." Molecular Breeding 41.10(2021): doi:10.1007/S11032-021-01251-Y.(IF2.208)

[72].Zheng Shilu, et al."Disentangling biotic and abiotic drivers of intraspecific trait variation in woody plant seedlings at forest edges." Ecology and Evolution 11.14(2021): doi:10.1002/ECE3.7799.(LA-S,IF2.621)

[73].Liu Dapu, et al."Diversification of plant agronomic traits by genome editing of brassinosteroid signaling family genes in rice.." Plant physiology 187.4(2021): doi:10.1093/PLPHYS/KIAB394.(SC-G,IF7.444)

[74].Jin Meifang, et al."Effect of copper on the photosynthesis and growth of Eichhornia crassipes.." Plant biology (Stuttgart, Germany) 23.5(2021): doi:10.1111/PLB.13281.(LA-S)

[75].Hao Hao-xin, et al."Erosion-reducing effects of plant roots during concentrated flow under contrasting textured soils." Catena 203.(2021): doi:10.1016/J.CATENA.2021.105378.(LA-S,IF4.882)

[76].Yuzhan Li, et al."Exogenous Melatonin and Catechol Application Modulate Physio-Biochemical Attributes and Early Growth of Fragrant Rice Under Cd Toxicity." Journal of Soil Science and Plant Nutrition .prepublish(2021): doi:10.1007/S42729-021-00521-0.(LA-S,IF2.516)

[77].Yang Weifeng, et al."Fine mapping of two grain chalkiness QTLs sensitive to high temperature in rice." Rice 14.1(2021): doi:10.1186/S12284-021-00476-X.(SC-E)

[78].Li Tao, et al."Identification and Validation of a Novel Locus Controlling Spikelet Number in Bread Wheat (Triticum aestivum L.) ." Frontiers in Plant Science .(2021): doi:10.3389/FPLS.2021.611106.(SC-G,IF4.568)

[79].Chen Weili, et al."Arbuscular Mycorrhizal Fungus Alters Root System Architecture in Camellia sinensis L. as Revealed by RNA-Seq Analysis ." Frontiers in Plant Science 12.(2021): doi:10.3389/FPLS.2021.777357.(LA-S,IF4.568)

[80].Zheng Yaxiong, et al."Functional Trait Responses to Strip Clearcutting in a Moso Bamboo Forest." Forests 12.6(2021): doi:10.3390/F12060793.(LA-S,IF2.317)

[81].Li Tao, et al."Genetic dissection of quantitative trait loci for grain size and weight by high-resolution genetic mapping in bread wheat (Triticum aestivum L.).." TAG. Theoretical and applied genetics. Theoretische und angewandte Genetik 135.1(2021): doi:10.1007/S00122-021-03964-2.(SC-G)

[82].Chen, Shiliang, et al."Genetic loci and responsible genes for pod and seed traits under diverse environments via linkage mapping analysis in soybean [Glycine max (L.) Merr.]." Genetic Resources and Crop Evolution .prepublish(2021): doi:10.1007/S10722-021-01287-1.(IF1.211)

[83].Zhao Xinpeng, et al."Genome-wide association study of grain shapes in Aegilops tauschii." Euphytica 217.7(2021): doi:10.1007/S10681-021-02877-X.(SC-G,IF1.697)

[84].Sun Mingjie, et al."Genotypic diversity of quality traits in Chinese foxtail millet (Setaria italica L.) and the establishment of a quality evaluation system." Food Chemistry 353.(2021): doi:10.1016/J.FOODCHEM.2021.129421.(SC-E)

[85].Sun, Yangyang , et al. "Identification and fine mapping of alien fragments associated with enhanced grain weight from Agropyron cristatum chromosome 7P in common wheat backgrounds." Theoretical and Applied Genetics 5(2021).(SC-G,IF4.643)

[86].Li Tao, et al."Identification and validation of two major QTLs for spike compactness and length in bread wheat (Triticum aestivum L.) showing pleiotropic effects on yield-related traits.." TAG. Theoretical and applied genetics. Theoretische und angewandte Genetik 134.11(2021): doi:10.1007/S00122-021-03918-8.(SC-G)

[87].Niu Yanan, et al."Identification and allele mining of new candidate genes underlying rice grain weight and grain shape by genome-wide association study.." BMC genomics 22.1(2021): doi:10.1186/S12864-021-07901-X.(SC-G,IF3.675)

[88].Imaged-based phenotyping accelerated QTL mapping and qtl×environment interaction analysis of testa colour in peanut (Arachis hypogaea). Plant Breeding (2021).(SC-G,IF1.794)

[89].Raboanatahiry Nadia, et al."In Silico Analysis of Fatty Acid Desaturases Structures in Camelina sativa, and Functional Evaluation of Csafad7 and Csafad8 on Seed Oil Formation and Seed Morphology." International Journal of Molecular Sciences 22.19(2021): doi:10.3390/IJMS221910857.(SC-G,IF4.602)

[90].Peng Yan, et al."Influence of physicochemical properties and starch fine structure on the eating quality of hybrid rice with similar apparent amylose content." Food Chemistry 353.(2021): doi:10.1016/J.FOODCHEM.2021.129461.(SC-E,IF6.81)

[91].Zhou Yun, et al."Introgressing the Aegilops tauschii genome into wheat as a basis for cereal improvement.." Nature plants 7.6(2021): doi:10.1038/S41477-021-00934-W.(SC-G)

[92].Hu Zhanqiang, et al."Kinetics of water absorption expansion of rice during soaking at different temperatures and correlation analysis upon the influential factors.." Food chemistry 346.(2020): doi:10.1016/J.FOODCHEM.2020.128912.(SC-E,IF6.81)

[93].Ji, G. , et al. "Leaf surface characteristics affect the deposition and distribution of droplets in rice (Oryza sativa L.)." Scientific Reports 11.1(2021):17846.(LA-S,IF4.149)

[94].Ma Lin, et al."Melatonin and Nitrogen Applications Modulate Early Growth and Related Physio-biochemical Attributes in Maize Under Cd Stress." Journal of Soil Science and Plant Nutrition 21.2(2021): doi:10.1007/S42729-021-00415-1.(LA-S,IF2.516)

[95].Sun Yaqian, et al."Mining of quantitative trait loci and candidate genes for seed size and shape across multiple environments in soybean (Glycine max)." Plant Breeding 140.6(2021): doi:10.1111/PBR.12968.(SC-G,IF1.794)

[96].Jiang Pingping, et al."Moderate Mn accumulation enhances growth and alters leaf hormone contents in the hyperaccumulator Celosia argentea Linn.." Environmental and Experimental Botany 191.prepublish(2021): doi:10.1016/J.ENVEXPBOT.2021.104603.(LA-S,IF4.173)

[97].Huang Yuzhou, et al."New Insights into the Microplastic Enrichment in the Blue Carbon Ecosystem: Evidence from Seagrass Meadows and Mangrove Forests in Coastal South China Sea.." Environmental science & technology 55.8(2021): doi:10.1021/ACS.EST.0C07289.(AlgaeC,IF8.25)

[98].Huang Xiaorui, et al."Novel Wx alleles generated by base editing for improvement of rice grain quality.." Journal of integrative plant biology 63.9(2021): doi:10.1111/JIPB.13098.(SC-A,IF6.19)

[99].Zhu Xiuliang, et al."Overexpression of TaSTT3b-2B improves resistance to sharp eyespot and increases grain weight in wheat.." Plant biotechnology journal .(2021): doi:10.1111/PBI.13760.(SC-G,8.738)

[100].Qian Mingchao, et al."Petal size in rapeseed: novel QTL and candidate genes detected through genome-wide association study and transcriptome comparison.." Journal of experimental botany 72.10(2021): doi:10.1093/JXB/ERAB105.(LA-S,IF5.557)

[101].Kaseb Mohamed Omar, et al."Physio-Anatomical Study of Polyploid Watermelon Grafted by Different Methods." Agronomy 11.5(2021): doi:10.3390/AGRONOMY11050913.(LA-S)

[102].Wu Zhiyong, et al."Physiological and transcriptomic analyses of brassinosteroid function in kiwifruit root." Environmental and Experimental Botany 194.(2022): doi:10.1016/J.ENVEXPBOT.2021.104685.(LA-S,IF4.173)

[103].Liu, J. , et al. "QMrl-7B Enhances Root System, Biomass, Nitrogen Accumulation and Yield in Bread Wheat." Plants 10.4(2021):764.(SC-G)

[104].Zhang Dazhong, et al."Root characteristics critical for cadmium tolerance and reduced accumulation in wheat (Triticum aestivum L.).." Journal of environmental management 305.(2021): doi:10.1016/J.JENVMAN.2021.114365.(IF6.243)

[105].Wang, C. , et al. "Sedimentary Organic Matter Load Influences the Ecological Effects and Potential Risks of Submerged Macrophyte Restoration Through Rhizosphere Metabolites." (2021).(LA-S)

[106].Stable pleiotropic loci and candidate genes for fresh pod- and seed-related characteristics across multiple environments in soybean (Glycine max). Plant Breeding (2021).(SC-G,IF1.794)

[107].Yang Weifeng, et al."Substitution Mapping of Two Closely Linked QTLs on Chromosome 8 Controlling Grain Chalkiness in Rice.." Rice (New York, N.Y.) 14.1(2021): doi:10.1186/S12284-021-00526-4.(SC-E)

[108].Jia Meiling, et al."TaIAA21 represses TaARF25-mediated expression of TaERFs required for grain size and weight development in wheat.." The Plant journal : for cell and molecular biology 108.6(2021): doi:10.1111/TPJ.15541.

[109].Fan Weijuan, et al."The H+-pyrophosphatase IbVP1 regulates carbon flux to influence the starch metabolism and yield of sweet potato." Horticulture Research 8.1(2021): doi:10.1038/S41438-020-00454-2.(LA-S,IF6.793)

[110].Huang Luojiang, et al."The LARGE2-APO1/APO2 regulatory module controls panicle size and grain number in rice.." The Plant cell 33.4(2021): doi:10.1093/PLCELL/KOAB041.(SC-G,IF11.277)

[111].Luo Guangbin, et al."The MYB family transcription factor TuODORANT1 from Triticum urartu and the homolog TaODORANT1 from Triticum aestivum inhibit seed storage protein synthesis in wheat.." Plant biotechnology journal 19.9(2021): doi:10.1111/PBI.13604.(SC-G,IF9.803)

[112].Gao Xiuying, et al."The phosphoproteomic and interactomic landscape of qGL3/OsPPKL1-mediated brassinosteroid signaling in rice.." The Plant journal : for cell and molecular biology .(2021): doi:10.1111/TPJ.15613.

[113].Li Yuying, et al."Transcription Factor TaWRKY51 Is a Positive Regulator in Root Architecture and Grain Yield Contributing Traits ." Frontiers in Plant Science 12.(2021): doi:10.3389/FPLS.2021.734614.(SC-G,IF5.753)

[114].Ming-Yue Wei, et al."Transcriptomic Analyses Reveal the Effect of Nitric Oxide on the Lateral Root Development and Growth of Mangrove Plant Kandelia Obovata".Research Square.2021.10.21203/rs.3.rs-894970/v1.(LA-S)

[115].Xin Guan, Qun Li, Tusunniyaze Maimaiti, Suke Lan, Peng Ouyang, Bowei Ouyang, Xian Wu, Sheng-Tao Yang,Toxicity and photosynthetic inhibition of metal-organic framework MOF-199 to pea seedlings,Journal of Hazardous Materials,Volume 409,2021,124521,ISSN 0304-3894,https://doi.org/10.1016/j.jhazmat.2020.124521.

[116].Xu H.S., He W., Zhou L., Liu K., Yang X.L., and You A.Q., 2021, Rice quality evaluate and key quality genes genotyping of rice germplasm from Africa and Brazil, Rice Genomics and Genetics, 12(5): 1-8 (doi: 10.5376/rgg.2021.12.0005).(SC-E)

[117].Jia-xin Ma, Bei-bei Cui, Man-li Liu, Jie Yuan, Cheng Yan.Quantitative Health Risk Assessment of Wastewater Treatment Plant Worker Exposed to Staphylococcus Aureus Bioaerosol During Warm and Cold Periods: Disease Burden and Sensitivity Analysis..Research Square.2021.10.21203/rs.3.rs-1070258/v1.(HiCC)

[118].Xiuying Gao, Jiaqi Zhang, Guang Cai, Huaying Du, Jianbo Li, Ruqin Wang, Yuji Wang, Jing Yin, Wencai Zhang, Hongsheng Zhang, Ji Huang, qGL3/OsPPKL1 induces phosphorylation of 14-3-3 protein OsGF14b to inhibit OsBZR1 function in brassinosteroid signaling, Plant Physiology, Volume 188, Issue 1, January 2022, Pages 624–636, https://doi.org/10.1093/plphys/kiab484.

[119].Laibao Feng,et al.Mapping causal genes and genetic interactions for agronomic traits using a large F2 population in rice.G3, 2021, 11(11), jkab318.DOI: 10.1093/g3journal/jkab318.(SC-E)

[120].Huang, M., Cao, J., Liu, Y., Zhang, M., Hu, L., Xiao, Z., Chen, J., & Cao, F. (2021). Low-temperature stress during the flowering period alters the source–sink relationship and grain quality in field-grown late-season rice. Journal of Agronomy and Crop Science, 207, 833–839. https://doi.org/10.1111/jac.12542.(SC-E)

[121].GAO Hua-wei. et al.Identification of petiole length for soybean compact architecture mutant M657 and breeding of new line.Journal of Integrative Agriculture.2021.Doi: 10.1016/S2095-3119(21)63702-4.(SC-E)

[122].Piyi Xing, et al."High-Resolution Detection of Quantitative Trait Loci for Seven Important Yield Components in Wheat (Triticum aestivum L.) using a High-Density SALF-Seq Genetic Map".Research Square.2021.10.21203/rs.3.rs-783221/v1

[123].Piyi Xing, et al."Genome-Wide Association Study Identified Novel Genomic Loci Controlling Internode Lengths and Plant Height in Common Wheat under Different Nitrogen Treatments".Research Square.2021.10.21203/rs.3.rs-901017/v1

[124].Baojian Guo, Jiang Qi, Dongfang Li, Hongwei Sun, Chao Lyu, Feifei Wang, Juan Zhu, Ganggang Guo, Rugen Xu,Genetic analysis and gene mapping of a dwarf and liguleless mutation in barley,The Crop Journal,2022,ISSN 2214-5141,https://doi.org/10.1016/j.cj.2022.01.006.(SC-G)

[125].Yang, H.; Yang, Q.; Kang, Y.; Zhang, M.; Zhan, X.; Cao, L.; Cheng, S.; Wu, W.; Zhang, Y. Finding Stable QTL for Plant Height in Super Hybrid Rice. Agriculture 2022, 12, 165. https://doi.org/10.3390/agriculture12020165.

[126].Zhang, J., Jiao, X., Du, Q. et al. Effects of Vapor Pressure Deficit and Potassium Supply on Root Morphology, Potassium Uptake, and Biomass Allocation of Tomato Seedlings. J Plant Growth Regul 40, 509–518 (2021). https://doi.org/10.1007/s00344-020-10115-2.(LA-S)

[127].Huang, Jinpeng, et al.Natural Variation of BRD2 Allele Plays an Important Role in the Plant Height and Grain Size. Available at SSRN: https://ssrn.com/abstract=3983811 or http://dx.doi.org/10.2139/ssrn.3983811.(SC-G)

[128].D.T. GAO, et al."Drought tolerance monitoring of apple rootstock M.9-T337 based on infrared and fluorescence imaging".PHOTOSYNTHETICA 59 (SI): 458-467, 2021.10.32615/ps.2021.035.(LA-S)

[129].Manman Liu, et al."Creation of Elite Rice With High-yield, Superior-quality and Strong Resistance to Brown Planthopper Based on Molecular Design".Research Square.2021.10.21203/rs.3.rs-992897/v1.(LA-S)

[130].Duan Yanan, et al."Biocontrol Potential of The Phloridin-Degrading Bacillus Licheniformis XNRB-3 Against Apple Replant Disease".Research Square.2021.10.21203/rs.3.rs-1039511/v1.(LA-S)

[131].Wan, Lian-Jie, Yang Tian, Man He, Yong-Qiang Zheng, Qiang Lyu, Rang-Jin Xie, Yan-Yan Ma, Lie Deng, and Shi-Lai Yi. 2021. "Effects of Chemical Fertilizer Combined with Organic Fertilizer Application on Soil Properties, Citrus Growth Physiology, and Yield" Agriculture 11, no. 12: 1207. https://doi.org/10.3390/agriculture11121207

[132].黃曉瑞. 編輯水稻中Waxy基因調(diào)節(jié)稻米品質(zhì)的研究[D].山東師范大學,2021.DOI:10.27280/d.cnki.gsdsu.2021.000116.

[133].MOHAMED OMAR MOHAMED HUSSEIN KASEB. 不同倍性西瓜嫁接愈合的分子生理機制研究[D].中國農(nóng)業(yè)科學院,2021.DOI:10.27630/d.cnki.gznky.2021.000142.

[134].丁崌平. 不同溫度下水汽壓差對番茄光合特性及營養(yǎng)吸收的影響[D].西北農(nóng)林科技大學,2021.DOI:10.27409/d.cnki.gxbnu.2021.000599.

[135].陳春. 片段化生境中常見植物檵木和短尾越橘種內(nèi)葉功能性狀研究[D].浙江大學,2021.DOI:10.27461/d.cnki.gzjdx.2021.002210.

[136].唐詩聞. 水稻突變體zsd11和lmm3的表型鑒定及其候選基因分析[D].西南科技大學,2021.DOI:10.27415/d.cnki.gxngc.2021.000263.

[137].雷昌菊,戴小英,伍艷芳,劉新亮,鄭永杰,符潮.3種楠屬植物形態(tài)及顯微特征分析[J].南方林業(yè)科學,2021,49(06):4-7+31.DOI:10.16259/j.cnki.36-1342/s.2021.06.002.

[138].李照杰. 23個油菜品種產(chǎn)油量和倒伏抗性鑒定與綜合性能評價[D].西北農(nóng)林科技大學,2021.DOI:10.27409/d.cnki.gxbnu.2021.001509.

[139].李傳廣,付沙,李峰,溫亮,劉士峰,程云吉,顏石,公愛琴,張麗,侯欣.28-高蕓苔素內(nèi)酯對烤煙幼苗生長發(fā)育的影響[J].山東農(nóng)業(yè)科學,2021,53(08):107-111.DOI:10.14083/j.issn.1001-4942.2021.08.019.

[140].馬國江,馬靖福,張沛沛,劉媛,陳濤,楊德龍.128份抗旱冬小麥新品系農(nóng)藝性狀遺傳多樣性分析[J].甘肅農(nóng)業(yè)大學學報,2021,56(03):37-44.DOI:10.13432/j.cnki.jgsau.2021.03.006.

[141].張紅杰. 152份合成小麥產(chǎn)量相關(guān)性狀全基因組關(guān)聯(lián)分析[D].山西大學,2021.DOI:10.27284/d.cnki.gsxiu.2021.000030.

[142].儲零逸. AP2/ERF轉(zhuǎn)錄因子OsERF44調(diào)控水稻穗發(fā)芽的效應(yīng)及其機制研究[D].揚州大學,2021.DOI:10.27441/d.cnki.gyzdu.2021.001857.

[143].郭寧. BnVIK和BnNAC13調(diào)控油菜種子含油量的功能研究[D].華中農(nóng)業(yè)大學,2021.DOI:10.27158/d.cnki.ghznu.2021.000374.

[144].黎詩艷,阮景軍,范昱,周美亮,王俊珍,李發(fā)良,程劍平.EMS誘變劑處理對苦蕎種子萌發(fā)及主要農(nóng)藝性狀的影響[J].分子植物育種,2021,19(03):914-922.DOI:10.13271/j.mpb.019.000914.

[145].徐珊珊,劉小金,徐大平,洪舟,郭俊譽,楊曾獎.IAA和NAA對降香黃檀扦插繁殖的影響[J].林業(yè)科學研究,2021,34(05):168-176.DOI:10.13275/j.cnki.lykxyj.2021.005.020.

[146].牛小軍. qGS5.1和qGS5.2對水稻粒重和粒形的遺傳控制作用[D].華中農(nóng)業(yè)大學,2021.DOI:10.27158/d.cnki.ghznu.2021.000135.

[147].李志永. SRN1-Tre6P-SnRK1正向調(diào)控回路協(xié)調(diào)水稻源-庫碳源分配的機制研究[D].華中農(nóng)業(yè)大學,2021.DOI:10.27158/d.cnki.ghznu.2021.000206.

[148].宋麗雙. 澳洲野生稻與亞洲栽培稻種間雜種后代的篩選和鑒定[D].揚州大學,2021.DOI:10.27441/d.cnki.gyzdu.2021.001780.

[149].梁芳,檀小輝,鄧旭,吳玉霜,吳敏,楊香春,李金玲.半紅樹植物玉蕊對淹水-鹽度脅迫的生長及生理響應(yīng)[J].廣西植物,2021,41(06):872-882.

[150].劉杰,吳國瑞,張金偉,孫周平.保健型中藥渣基質(zhì)對日光溫室袋培番茄產(chǎn)量及品質(zhì)的影響[J].核農(nóng)學報,2021,35(07):1687-1695.

[151].蔣偉勤. 缽苗機插優(yōu)質(zhì)食味遲熟中粳稻控混肥一次性施用效應(yīng)研究[D].揚州大學,2021.DOI:10.27441/d.cnki.gyzdu.2021.001381.

[152].蔡曉惠. 播期對關(guān)中地區(qū)冬油菜籽粒產(chǎn)量和品質(zhì)的影響[D].西北農(nóng)林科技大學,2021.DOI:10.27409/d.cnki.gxbnu.2021.001520.

[153].李照杰,蔡曉惠,吳偉.不同播期對油菜產(chǎn)量及根系電容值的影響[J].西北農(nóng)業(yè)學報,2021,30(09):1321-1330.

[154].郝鳳,于鐵峰,劉曉靜,高凱.不同氮效率型苜蓿氮素吸收差異與根系形態(tài)的關(guān)系及其對氮的響應(yīng)[J].草地學報,2021,29(11):2428-2434.

[155].于洋. 不同氮效率玉米對供氮的響應(yīng)特征及轉(zhuǎn)錄組蛋白質(zhì)組分析[D].東北農(nóng)業(yè)大學,2021.DOI:10.27010/d.cnki.gdbnu.2021.000034.

[156].曲文蕊,韓曉莉,翟軍團,李志軍.不同發(fā)育階段胡楊、灰楊異形葉形態(tài)結(jié)構(gòu)變化特征[J].塔里木大學學報,2021,33(02):14-24.

[157].吳元華,高華軍,劉好寶,馬興華.不同規(guī)格育苗盤的雪茄煙煙苗生長差異及對干旱脅迫的響應(yīng)[J].江蘇農(nóng)業(yè)科學,2021,49(16):101-106.DOI:10.15889/j.issn.1002-1302.2021.16.018.

[158].付正豪. 不同機插方式下控釋肥配比對遲熟中粳水稻產(chǎn)量及稻米品質(zhì)的影響[D].揚州大學,2021.DOI:10.27441/d.cnki.gyzdu.2021.001094.

[159].李俊杰,杜蒲芳,石婷瑞,侯沛佳,柴新宇,趙瑞,汪妤,李紅霞.不同基因型小麥苗期耐低氮性評價及篩選[J].中國農(nóng)業(yè)科技導報,2021,23(07):21-32.DOI:10.13304/j.nykjdb.2020.0927.

[160].熊潔,丁戈,陳倫林,李書宇,鄒小云,黃楊,宋來強.不同基因型油菜耐鋁性及其根系形態(tài)對鋁脅迫的響應(yīng)[J].中國油料作物學報,2021,43(04):673-682.DOI:10.19802/j.issn.1007-9084.2020073.

[161].徐誠,楊建超,楊鴻基,楊平,軒正英,張娟.不同基質(zhì)配比對黃瓜穴盤育苗的影響[J].陜西農(nóng)業(yè)科學,2021,67(06):38-41.

[162].韓麗君,陳思,周帥,郝向春.不同基質(zhì)配方對遼東櫟容器苗生長的影響[J].林業(yè)科技通訊,2021(10):45-48.DOI:10.13456/j.cnki.lykt.2020.11.16.0003.

[163].盧廣. 不同來源大麥的進化關(guān)系及其受選擇代謝物的分化機理[D].華中農(nóng)業(yè)大學,2021.DOI:10.27158/d.cnki.ghznu.2021.000495.

[164].許芳維. 不同密度玉米與苜蓿間作對玉米生產(chǎn)潛能的研究[D].東北農(nóng)業(yè)大學,2021.

[165].于玉梅,嚴青青.不同品種海島棉苗期根系耐鹽堿性比較[J].農(nóng)村科技,2021(04):16-17.DOI:10.19777/j.cnki.issn1002-6193.2021.04.006.

[166].賈廷偉,江曉林,劉艷陽,崔承齊,杜俊偉,杜振偉,武軻,梅鴻獻,鄭永戰(zhàn).不同品種類型芝麻品質(zhì)性狀的比較分析[J].中國油脂,2021,46(08):81-86.DOI:10.19902/j.cnki.zgyz.1003-7969.210216.

[167].何玉友,陳雙林,郭子武,張瑋,汪舍平.不同棄管年限毛竹林立竹葉片功能性狀的變化特征[J].福建農(nóng)林大學學報(自然科學版),2021,50(05):641-648.DOI:10.13323/j.cnki.j.fafu(nat.sci.).2021.05.010.

[168].倪勝利,何瑞,劉媛,張沛沛,李興茂,楊德龍.不同水分條件下小麥粒重QTL定位及其元分析[J].甘肅農(nóng)業(yè)大學學報,2021,56(03):45-54.DOI:10.13432/j.cnki.jgsau.2021.03.007.

[169].康佳惠,梁秀芝,鄭敏娜,韓志順,陳燕妮.不同外源氮素形態(tài)對紫花苜蓿根系的影響[J].山西農(nóng)業(yè)科學,2021,49(04):467-471.

[170].王胤,姚瑞玲.不同形態(tài)氮素配比對馬尾松組培苗生長的影響[J].中南林業(yè)科技大學學報,2021,41(03):18-24+71.DOI:10.14067/j.cnki.1673-923x.2021.03.003.

[171].田雅楠,曹玲玲,趙立群,曹彩紅.不同營養(yǎng)液配方對番茄潮汐式灌溉育苗質(zhì)量的影響[J].中國果菜,2021,41(09):83-87.DOI:10.19590/j.cnki.1008-1038.2021.09.015.

[172].厲廣輝,王興軍,張斌,藺儒俠,侯蕾.不同油莎豆品種在山東種植的產(chǎn)量與品質(zhì)研究[J].山東農(nóng)業(yè)科學,2021,53(03):61-64.DOI:10.14083/j.issn.1001-4942.2021.03.011.

[173].郝向春,周帥,韓麗君,翟瑜,陳天成.不同種源遼東櫟種子和幼樹指標變異及相關(guān)分析[J].植物資源與環(huán)境學報,2021,30(04):1-11.

[174].歐文慧. 常見真水生植物功能性狀變異與環(huán)境適應(yīng)[D].湖北大學,2021.DOI:10.27130/d.cnki.ghubu.2021.000494.

[175].張毛寧,黃冰艷,苗利娟,徐靜,石磊,張忠信,孫子淇,劉華,齊飛艷,董文召,鄭崢,張新友.巢式雜交分離群體的花生籽仁性狀的主基因+多基因混合遺傳模型分析[J].中國農(nóng)業(yè)科學,2021,54(13):2916-2939.

[176].張毛寧,張新友,孫子淇,黃冰艷,劉華,徐靜,張忠信,齊飛艷,董文召.巢式雜交群體的花生莢果性狀遺傳模型分析[J].中國油料作物學報,2021,43(04):573-581.DOI:10.19802/j.issn.1007-9084.2020247.

[177].藍雅華. 成品散卵一代雜交蠶種的均勻性評價研究[D].浙江大學,2021.DOI:10.27461/d.cnki.gzjdx.2021.001740.

[178].王若輝,鄭悅雯,吳書天,沈丹玉,莫潤宏,倪張林,劉毅華.儲藏溫度對干核桃品質(zhì)的影響效應(yīng)[J].中國糧油學報,2021,36(10):131-137.

[179].張業(yè)倫,孟雅寧,呂亮杰,梁丹,羅巧玲,蘭素缺,張凱,何飛飛,蘭彩霞,李杏普.春小麥千粒重相關(guān)性狀的QTL定位及其耐熱性分析[J].植物遺傳資源學報,2021,22(01):83-94.DOI:10.13430/j.cnki.jpgr.20200301001.

[180].劉新亮,戴小英,章挺,吳巧花,江斌,唐星林.大量元素缺乏對樟樹幼苗生長的影響[J].南方林業(yè)科學,2021,49(05):16-20.DOI:10.16259/j.cnki.36-1342/s.2021.05.004.

[181].王瑞. 氮素對油茶苗木生長的影響研究[D].中南林業(yè)科技大學,2021.DOI:10.27662/d.cnki.gznlc.2021.000003.

[182].楊建超. 氮素指數(shù)施肥處理對設(shè)施甜瓜生長及養(yǎng)分承載的影響[D].塔里木大學,2021.DOI:10.27708/d.cnki.gtlmd.2021.000219.

[183].田孝志,徐龍曉,宋建飛,荀咪,張瑋瑋,楊洪強.稻殼炭對緊實土壤中蘋果根系硫同化酶活性、H_2S含量及根系構(gòu)型的影響[J].植物營養(yǎng)與肥料學報,2021,27(05):869-877.

[184].饒文婷. 稻米外觀品質(zhì)和食味品質(zhì)相關(guān)性狀QTL定位及其效應(yīng)驗證[D].華中農(nóng)業(yè)大學,2021.DOI:10.27158/d.cnki.ghznu.2021.000736.

[185].劉合芹,陳合云,張小明,鄒桂花,鄭學強,劉秀慧.地方種質(zhì)資源東陽紅粟的調(diào)查收集與鑒定評價[J].浙江農(nóng)業(yè)科學,2021,62(04):678-680.DOI:10.16178/j.issn.0528-9017.20210411.

[186].張璇. 電容法和rDNA濃度法估測小麥根系性狀的研究[D].西北農(nóng)林科技大學,2021.

[187].盧林. 電子舌多傳感陣列信息交互及秈稻米食味量化研究[D].浙江工商大學,2021.DOI:10.27462/d.cnki.ghzhc.2021.000004.

[188].范鍇. 鄂爾多斯沙地栽培苜蓿根系形態(tài)及生理特性的研究[D].中國農(nóng)業(yè)科學院,2021.DOI:10.27630/d.cnki.gznky.2021.000817.

[189].張靜亞. 番茄IAA甲基轉(zhuǎn)移酶基因SlIAMT對胚軸伸長和根系發(fā)育的調(diào)控[D].中國農(nóng)業(yè)科學院,2021.DOI:10.27630/d.cnki.gznky.2021.000319.

[190].徐巍. 番茄低溫下矮化壞死調(diào)控基因ndw的克隆及功能鑒定[D].石河子大學,2021.DOI:10.27332/d.cnki.gshzu.2021.000013.

[191].徐欣韻,王寧,丁佳,陳妍,田光明.番茄青枯病拮抗菌的定向篩選及其抗病促生機制研究[J].微生物學報,2021,61(10):3276-3290.DOI:10.13343/j.cnki.wsxb.20210033.

[192].楊瑩瑩. 非洲栽培稻基因滲入系重要農(nóng)藝性狀QTL分析及qHD6的精細定位[D].中國農(nóng)業(yè)科學院,2021.DOI:10.27630/d.cnki.gznky.2021.000686.

[193].于國琦. 肥料運籌對大麥產(chǎn)量和品質(zhì)的影響研究[D].揚州大學,2021.DOI:10.27441/d.cnki.gyzdu.2021.000550.

[194].李格格. 分蘗期干旱脅迫對不同抗旱性水稻根際微生物群落的影響及其機制[D].西北農(nóng)林科技大學,2021.DOI:10.27409/d.cnki.gxbnu.2021.000218.

[195].徐森,谷瑞,陳雙林,郭子武,楊麗婷.覆蓋下雷竹筍籜葉性狀和食味品質(zhì)的變化及其相關(guān)性[J].林業(yè)科學,2021,57(09):34-41.

[196].張曉暉. 甘藍型油菜粒重主效QTL qSW.C9精細定位及候選基因BnaC9.RINGb功能分析[D].華中農(nóng)業(yè)大學,2021.DOI:10.27158/d.cnki.ghznu.2021.000188.

[197].燕佳琦. 甘藍型油菜種質(zhì)資源農(nóng)藝與抗逆性狀的評價及優(yōu)異種質(zhì)篩選[D].西北農(nóng)林科技大學,2021.

[198].劉家材. 高鉀水溶肥對設(shè)施草莓生長發(fā)育和果實品質(zhì)的影響[D].塔里木大學,2021.

[199].白瑤. 根系特征對小麥氮效率的影響[D].西北農(nóng)林科技大學,2021.DOI:10.27409/d.cnki.gxbnu.2021.001817.

[200].梁悅. 供氮水平和氮肥形態(tài)對棉花生長發(fā)育及養(yǎng)分吸收的影響[D].新疆農(nóng)業(yè)大學,2021.

[201].徐一荻,劉春花,謝富,王陽,胡凱紅,張建良,張銳.供磷水平對核桃實生苗生長生理特性及酶活性的影響[J].西南林業(yè)大學學報(自然科學),2021,41(05):27-35.

[202].李俊杰. 供磷水平與施肥方法對臍橙生長發(fā)育的影響[D].西南大學,2021.DOI:10.27684/d.cnki.gxndx.2021.000516.

[203].解云,郭世華.谷子品種農(nóng)藝性狀的灰色關(guān)聯(lián)度分析及綜合評價[J].分子植物育種,2021,19(06):2064-2072.DOI:10.13271/j.mpb.019.002064.

[204].安麗東. 固定化粉紅粘帚霉微球的制備及其對番茄的生防作用研究[D].東北農(nóng)業(yè)大學,2021.

[205].顧晶晶,丁志強,楊樂,田文仲.灌漿中后期高溫脅迫對小麥品種耐熱性的影響[J].山西農(nóng)業(yè)科學,2021,49(10):1152-1157.

[206].劉雅婷. 河岸帶紫花苜蓿根-土相互力學作用時間效應(yīng)研究[D].太原理工大學,2021.DOI:10.27352/d.cnki.gylgu.2021.000120.

[207].崔亞琴,宗世祥.核桃緣吉丁成蟲的取食選擇行為及機制[J].北京林業(yè)大學學報,2021,43(09):121-130.

[208].李金霞,孫小妹,劉娜,李良,陳年來.黑果枸杞功能性狀對氮磷添加的響應(yīng)及其可塑性[J].應(yīng)用生態(tài)學報,2021,32(04):1279-1288.DOI:10.13287/j.1001-9332.202104.025.

[209].李震. 胡麻LEA基因家族的鑒定及其在種子發(fā)育過程中的遺傳效應(yīng)[D].中國農(nóng)業(yè)科學院,2021.DOI:10.27630/d.cnki.gznky.2021.000355.

[210].范鵬敏. 花生白絹病抗性評價及轉(zhuǎn)錄組和代謝組分析[D].中國農(nóng)業(yè)科學院,2021.DOI:10.27630/d.cnki.gznky.2021.000691.

[211].李蓉蓉. 華南沿海風鈴木類植物鑒定與遺傳多樣性研究[D].東北林業(yè)大學,2021.DOI:10.27009/d.cnki.gdblu.2021.000586.

[212].任高磊. 淮北地區(qū)不同機插條件下優(yōu)質(zhì)中熟中粳控混肥一次性施用技術(shù)研究[D].揚州大學,2021.DOI:10.27441/d.cnki.gyzdu.2021.001410.

[213].張培,龐圣江,劉士玲,楊保國,勞慶祥,段潤梅,蔡道雄,諶紅輝.緩釋肥對江南油杉容器苗生長的影響[J].西北農(nóng)林科技大學學報(自然科學版),2021,49(09):92-98.DOI:10.13207/j.cnki.jnwafu.2021.09.011.

[214].李靜雯, et al."黃淮麥區(qū)部分小麥品種粒重基因TaGS5-A1的等位變異分布及其效應(yīng)分析." 麥類作物學報 41.03(2021):272-280. doi:

[215].王鑫.灰棗優(yōu)系的比較及鑒定.2021.塔里木大學,MA thesis.

[216].黎松松.混播箭筈豌豆或施肥對燕麥草地減肥增效的影響.2021.新疆農(nóng)業(yè)大學,MA thesis.

[217].白晨陽, et al."機械收獲方式對油菜籽粒關(guān)鍵性狀的影響." 中國農(nóng)業(yè)科學 54.14(2021):2991-3003. doi:

[218].曹城華, 武文波,and 王鈺."基于Radon變換的空間目標運動方向檢測." 光學精密工程 29.07(2021):1678-1685. doi:

[219].張芳, et al."基于SNP標記的小麥籽粒性狀全基因組關(guān)聯(lián)分析." 中國農(nóng)業(yè)科學 54.10(2021):2053-2064. doi:

[220].李金龍, et al."基于表型性狀和SSR分子標記構(gòu)建甜蕎初級核心種質(zhì)." 植物遺傳資源學報 22.05(2021):1240-1247. doi:10.13430/j.cnki.jpgr.20210308001.

[221].王安貴, et al."基于高密度SNP標記對玉米籽粒相關(guān)性狀的QTL定位." 分子植物育種 19.10(2021):3323-3328. doi:10.13271/j.mpb.019.003323.

[222].胡曉輝,崔鳳高,楊偉強,侯名語,張勝忠,王嵩,侯剛,王晶珊,苗華榮,陳靜.基于高密度遺傳圖譜的花生籽仁大小相關(guān)性狀QTL定位[J].花生學報,2021,50(03):19-25+54.DOI:10.14001/j.issn.1002-4093.2021.03.003.

[223].陳曉軍, et al."基于基因編輯技術(shù)創(chuàng)制高亞油酸水稻材料." 中國農(nóng)業(yè)科學 54.14(2021):2931-2940. doi:

[224].王安貴, et al."基于溫熱玉米F_(2:3)家系產(chǎn)量相關(guān)性狀的遺傳解析." 種子 40.07(2021):130-134. doi:10.16590/j.cnki.1001-4705.2021.07.130.

[225].郭燕, et al."基于葉片解剖結(jié)構(gòu)的京津冀主栽板栗品種抗旱性評價." 核農(nóng)學報 35.08(2021):1771-1782. doi:

[226].董泉彬.基于雜化交聯(lián)策略的可注射抗菌透明質(zhì)酸水凝膠的構(gòu)建及其預防CIED囊袋感染的研究.2021.南昌大學,PhD dissertation.

[227].葉廷紅.鉀肥施用量對水稻產(chǎn)量、鉀素吸收利用及稻米品質(zhì)的影響.2021.華中農(nóng)業(yè)大學,MA thesis.

[228].張江林.鉀素營養(yǎng)增強水稻抵抗葉鞘腐敗病的生理機制.2021.華中農(nóng)業(yè)大學,PhD dissertation.

[229].艾鵬睿,and 馬英杰."間作模式農(nóng)田小氣候效應(yīng)對棉花生理生態(tài)指標的影響." 新疆農(nóng)業(yè)科學 58.09(2021):1594-1602. doi:

[230].羅惠.箭葉淫羊藿復合群的形態(tài)變異與系統(tǒng)發(fā)育研究.2021.湖北民族大學,MA thesis.

[231].劉秋員.江淮東部中粳優(yōu)質(zhì)高產(chǎn)氮高效類型及其若干形態(tài)生理特征.2021.揚州大學,PhD dissertation.

[232].田錚, et al."江蘇省半糯型粳稻蒸煮食味品質(zhì)性狀的差異分析." 中國水稻科學 35.03(2021):249-258. doi:10.16819/j.1001-7216.2021.01103.

[233].朱娟娟, et al."解鉀菌與鹽脅迫對枸杞幼苗根系特征和生理代謝的影響." 干旱地區(qū)農(nóng)業(yè)研究 39.05(2021):50-58+65. doi:

[234].段義三, et al."粳稻谷低溫倉儲期間糧堆特性及加工品質(zhì)的變化." 食品工業(yè)科技 42.09(2021):289-298. doi:10.13386/j.issn1002-0306.2020070046.

[235].龍麗.聚乙烯微塑料和鹽酸環(huán)丙沙星單一及聯(lián)合作用對漂浮植物的影響.2021.湖北大學,MA thesis.

[236].盧培娜.菌肥與腐熟秸稈對鹽堿地燕麥土壤微生態(tài)環(huán)境的調(diào)控機制.2021.內(nèi)蒙古農(nóng)業(yè)大學,PhD dissertation.

[237].阮俊梅.開放式增溫對東北水稻產(chǎn)量、氮素利用及農(nóng)田溫室氣體排放的影響.2021.中國農(nóng)業(yè)科學院,MA thesis.

[238].李明珠.抗白粉病、葉銹病小偃麥衍生系的分子細胞遺傳學鑒定.2021.山東農(nóng)業(yè)大學,MA thesis.

[239].李春花, et al."苦蕎種質(zhì)資源性狀評價及優(yōu)異資源篩選." 干旱地區(qū)農(nóng)業(yè)研究 39.06(2021):19-27. doi:

[240].鄭俊青, et al."苦蕎重組自交系群體粒重、粒形與蛋白組分含量的變異." 浙江農(nóng)業(yè)學報 33.04(2021):565-575. doi:

[241].鄭冉, et al."苦蕎重組自交系群體籽粒黃酮含量與產(chǎn)量性狀分析." 廣西植物 41.02(2021):216-224. doi:

[242].梁龍, et al."樂昌含笑不同家系的葉形態(tài)與生長差異分析." 熱帶亞熱帶植物學報 29.05(2021):503-508. doi:

[243].李秋鳳.利用CRISPR/Cas9技術(shù)編輯水稻SD1基因改良環(huán)江香糯株高的研究.2021.廣西大學,MA thesis.

[244].吳嫻, et al."利用CRISPR/Cas9基因編輯技術(shù)改良大粒香稻瘟病抗性." 種子 40.07(2021):50-55. doi:10.16590/j.cnki.1001-4705.2021.07.050.

[245].張波, et al."利用單片段代換系鑒定巴西陸稻IAPAR9中的粒型基因." 作物學報 47.08(2021):1472-1480. doi:

[246].周圣.利用機器學習優(yōu)化油菜含油量和脂肪酸的快速分析模型.2021.武漢輕工大學,MA thesis.

[247].邢運高, et al."兩系亞種間雜交水稻組合的產(chǎn)量和品質(zhì)性狀雜種優(yōu)勢分析." 江蘇農(nóng)業(yè)科學 49.01(2021):59-63. doi:10.15889/j.issn.1002-1302.2021.01.011.

[248].馮榮梅, 周玉竹,and 趙琳琳."兩種不同消毒方法用于口腔牙椅水路消毒效果觀察." 齊魯護理雜志 27.21(2021):167-169. doi:

[249].楊貴婷.磷酸脲基復合肥制備工藝優(yōu)化及其在濱海鹽漬土中的磷素增效機制.2021.山東農(nóng)業(yè)大學,PhD dissertation.

[250].張燕.磷添加對青海扁莖早熟禾養(yǎng)分重吸收的影響.2021.青海大學,MA thesis.

[251].張瀟.陸地棉野生系闊葉棉產(chǎn)量和纖維品質(zhì)QTL有利等位基因鑒定.2021.西南大學,MA thesis.

[252].涂晶晶, et al."馬尾松不同葉型幼苗外生菌根真菌群落特征." 菌物學報 40.01(2021):124-134. doi:10.13346/j.mycosystema.200222.

[253].譚著明, et al."馬尾松林分大徑材個體異型生長模式解析." 湖南林業(yè)科技 48.03(2021):8-14. doi:

[254].王胤,and 姚瑞玲."馬尾松組培苗對氮素形態(tài)的生長響應(yīng)." 廣西植物 41.06(2021):922-929. doi:

[255].張旭, et al."麥稈還田對直播和移栽棉花產(chǎn)量及氮素吸收的影響." 中國農(nóng)業(yè)科技導報 23.03(2021):122-131. doi:10.13304/j.nykjdb.2019.0964.

[256].馬霜.毛竹擴展蛋白家族全基因組分析及PeEXPA8功能研究.2021.西南科技大學,MA thesis.

[257].胡瑞財, et al."毛竹葉片性狀及其異速增長關(guān)系的海拔梯度效應(yīng)." 竹子學報 40.01(2021):52-58. doi:10.19560/j.cnki.issn1000-6567.2021.01.010.

[258].王學成, et al."棉花秸稈不同埋深對土壤水鹽分布及棉花根系構(gòu)型的影響." 節(jié)水灌溉 .09(2021):77-82. doi:

[259].張曉蕊, 董春娟,and 尚慶茂."苗齡對茄果類蔬菜扦插苗莖基不定根發(fā)生的影響." 中國蔬菜 .05(2021):58-63. doi:10.19928/j.cnki.1000-6346.2021.2014.

[260].楊亞飛, et al."某市政污水處理廠的微生物氣溶膠排放特征及其定量風險評價研究." 給水排水 57.S1(2021):104-109. doi:10.13789/j.cnki.wwe1964.2021.S1.022.

[261].劉鵬翀.苜蓿和香根草根系-黃土抗剪力學特性研究.2021.太原理工大學,MA thesis.

[262].張俊, et al."鉬肥拌種量對旱薄地花生發(fā)育及氮素積累的影響." 河南農(nóng)業(yè)科學 50.03(2021):59-66. doi:10.15933/j.cnki.1004-3268.2021.03.008.

[263].王吉祥, et al."耐亞磷酸鹽紫花苜蓿品種篩選及評價指標的鑒定." 草業(yè)學報 30.05(2021):186-199. doi:

[264].姜朋, et al."寧麥9號/揚麥158重組自交系群體產(chǎn)量性狀的遺傳解析." 作物學報 47.05(2021):869-881. doi:

[265].景亮亮.噴霧助劑對3種藥劑的增效機制及應(yīng)用研究.2021.寧夏大學,MA thesis.

[266].陶利思, et al."偏高水分粳稻谷儲藏期間糧堆空氣特性與品質(zhì)指標的變化." 食品工業(yè)科技 43.02(2022):328-337. doi:10.13386/j.issn1002-0306.2021060097.

[267].陳春, et al."片段化森林中檵木幼苗種內(nèi)葉經(jīng)濟性狀變異及其驅(qū)動因子." 浙江大學學報(理學版) 48.06(2021):718-727. doi:

[268].陳春.片段化生境中常見植物檵木和短尾越橘種內(nèi)葉功能性狀研究.2021.浙江大學,MA thesis.

[269].阮振.片段化生境中凋落葉和細枝分解特征及其影響因素.2021.浙江大學,MA thesis.

[270].桑金盛.蘋果根際土壤銅的形態(tài)及其對幼樹養(yǎng)分吸收和分配的影響.2021.山東農(nóng)業(yè)大學,MA thesis.

[271].李昊.蘋果根區(qū)土壤鈣形態(tài)及其對根系生長發(fā)育的影響.2021.山東農(nóng)業(yè)大學,MA thesis.

[272].劉焱, et al."掐葉時期對宛芝16芝麻種植效益的影響." 河北農(nóng)業(yè)科學 25.01(2021):40-43. doi:

[273].李鵬.蕎麥直鏈淀粉含量測定及Waxy克隆分析.2021.貴州師范大學,MA thesis.

[274].劉曉偉, et al."缺鉀對不同品種冬小麥土壤鉀素和品質(zhì)的影響." 新疆農(nóng)業(yè)科學 58.02(2021):332-341. doi:

[275].許明宸.溶藻菌篩選、復合菌劑制備及在養(yǎng)殖尾水中的應(yīng)用研究.2021.常州大學,MA thesis.

[276].李傳廣.三種植物生長調(diào)節(jié)劑對烤煙幼苗生長發(fā)育的影響.2021.山東農(nóng)業(yè)大學,MA thesis.

[277].馬玲, et al."沙河水庫浮游植物季節(jié)變化特征." 江蘇水利 .01(2022):19-22. doi:10.16310/j.cnki.jssl.2022.01.007.

[278].王文越, et al."山楂與野山楂的化學成分對比研究." 山東中醫(yī)藥大學學報 45.05(2021):672-679. doi:10.16294/j.cnki.1007-659x.2021.05.020.

[279].馬佳琳, et al."深秋紅沙棘嫩枝扦插育苗試驗研究." 山西林業(yè)科技 50.03(2021):4-7+12. doi:

[280].趙偉亮.生草對蘋果園微域環(huán)境及果實品質(zhì)的影響.2021.塔里木大學,MA thesis.

[281].許明宸, et al."生態(tài)溝渠凈化稻田排水動力學分析和生物相特征." 環(huán)境化學 40.02(2021):592-602. doi:

[282].謝呈輝, et al."施氮量對寧夏引黃灌區(qū)麥后復種糜子生長、產(chǎn)量及氮素利用的影響." 作物學報 48.02(2022):463-477. doi:

[283].吳子帥, et al."施氮量和栽插密度對桂育11號產(chǎn)量和稻米品質(zhì)的影響." 中國農(nóng)業(yè)科技導報 23.08(2021):154-162. doi:10.13304/j.nykjdb.2021.0102.

[284].凌晨, et al."雙季稻栽培對水稻DUS測試標準品種數(shù)量性狀表達的影響." 作物雜志 .04(2021):18-25. doi:10.16035/j.issn.1001-7283.2021.04.003.

[285].陳庭木, et al."水稻低直鏈淀粉資源篩選." 中國農(nóng)學通報 37.05(2021):21-25. doi:

[286].李輝.水稻覆膜旱直播技術(shù)與裝備研究.2021.吉林大學,PhD dissertation.

[287].顧正文.水稻可溶性淀粉合成酶不同突變組合創(chuàng)建與初步品質(zhì)分析.2021.揚州大學,MA thesis.

[288].來桂玉.水稻粒長QTL GL3.4的遺傳解析與OsGATA7的功能研究.2021.中國農(nóng)業(yè)科學院,MA thesis.

[289].程一臣.水稻粒重粒形QTLqTGW1-2的分解和驗證.2021.中國農(nóng)業(yè)科學院,MA thesis.

[290].杜成興, et al."水稻粒重粒形QTL的定位及qTGW1.2/qGL1.2的驗證." 中國水稻科學 35.04(2021):359-372. doi:10.16819/j.1001-7216.2021.201205.

[291].田彪, et al."水稻苗期根部性狀的遺傳分析和最長根長QTL qLRL4的精細定位." 作物學報 47.10(2021):1863-1873. doi:

[292].殷春淵, et al."水稻食味品質(zhì)性狀間相關(guān)性分析及其與葉片光合作用的關(guān)系." 中國農(nóng)業(yè)科技導報 23.04(2021):119-127. doi:10.13304/j.nykjdb.2020.0218.

[293].田彪.水稻穗部性狀雜種優(yōu)勢的QTL分析和最長根長QTL qLRL4的精細定位.2021.中國農(nóng)業(yè)科學院,MA thesis.

[294].唐詩聞.水稻突變體zsd11和lmm3的表型鑒定及其候選基因分析.2021.西南科技大學,MA thesis.

[295].王大川.水稻直穗密粒CSSL-Z749和短寬粒CSSL-Z357鑒定及重要性狀QTL分析.2021.西南大學,MA thesis.

[296].王肖鳳, et al."水分管理對再生稻稻米品質(zhì)的影響." 華中農(nóng)業(yè)大學學報 40.02(2021):103-111. doi:10.13300/j.cnki.hnlkxb.2021.02.011.

[297].李江艷.水分脅迫下7份鴨茅材料苗期耗水特性及抗旱性研究.2021.新疆農(nóng)業(yè)大學,MA thesis.

[298].齊琦, 王洪芬,and 陳守剛."酸摻雜聚苯胺復合材料的制備及其pH敏感性研究." 表面技術(shù) 50.04(2021):267-274. doi:10.16490/j.cnki.issn.1001-3660.2021.04.027.

[299].施林林.太湖稻區(qū)優(yōu)質(zhì)食味粳稻產(chǎn)量品質(zhì)形成的溫光生態(tài)及利用研究.2021.揚州大學,PhD dissertation.

[300].付均惠, et al."泰山白首烏葉片性狀變異分析." 山東林業(yè)科技 51.02(2021):7-11. doi:

[301].舒海燕, et al."通過轉(zhuǎn)化脂肪酸去飽和酶基因AcoFAD2提高菠蘿植株的抗寒能力." 分子植物育種 19.21(2021):7132-7137. doi:10.13271/j.mpb.019.007132.

[302].宋書婷.通氣灌溉對蘋果根區(qū)環(huán)境及根系發(fā)育和養(yǎng)分吸收的影響.2021.山東農(nóng)業(yè)大學,MA thesis.

[303].田孝志.土壤緊實度對蘋果幼樹硫代謝的影響及稻殼炭的改良作用.2021.山東農(nóng)業(yè)大學,MA thesis.

[304].高陽.土壤水分梯度變化對內(nèi)蒙古典型草原草本植物形態(tài)及成分的影響.2021.中央民族大學,MA thesis.

[305].周曉鑫.土壤質(zhì)地和含水量對紫花苜蓿苗期生長和根系形態(tài)的影響.2021.中國農(nóng)業(yè)科學院,MA thesis.

[306].馬旭輝, et al."褪黑素對玉米幼苗根系發(fā)育和抗旱性的影響." 生物技術(shù)通報 37.02(2021):1-14. doi:10.13560/j.cnki.biotech.bull.1985.2020-0575.

[307].徐華山, et al."外引水稻種質(zhì)資源的品質(zhì)評價與重要品質(zhì)基因的基因型鑒定." 分子植物育種 19.17(2021):5891-5898. doi:10.13271/j.mpb.019.005891.

[308].李丹丹, et al."外源激素對比利時杜鵑扦插根系特征的影響." 生態(tài)科學 40.02(2021):82-88. doi:10.14108/j.cnki.1008-8873.2021.02.011.

[309].孟姝婷.外源水楊酸對鹽堿條件下蘋果根系生長和養(yǎng)分吸收的影響.2021.山東農(nóng)業(yè)大學,MA thesis.

[310].寇津銘.外源棕櫚酸介導西瓜對枯萎病抗性機理的初步研究.2021.東北農(nóng)業(yè)大學,MA thesis.

[311].閆思華.微咸水-碳肥-根系協(xié)同調(diào)控對番茄生長發(fā)育的影響.2021.寧夏大學,MA thesis.

[312].冉盼.西藏栽培和野生苦蕎資源評價及其分子標記系統(tǒng)關(guān)系研究.2021.貴州師范大學,MA thesis.

[313].甄子龍.向日葵苗期抗旱性鑒定及抗旱相關(guān)性狀的全基因組關(guān)聯(lián)分析.2021.內(nèi)蒙古農(nóng)業(yè)大學,MA thesis.

[314].甄子龍, et al."向日葵種質(zhì)資源苗期抗旱性鑒定及抗旱指標篩選." 干旱地區(qū)農(nóng)業(yè)研究 39.04(2021):228-238. doi:

[315].裴婕,and 余春梅."小麥8親本高世代互交群體的創(chuàng)制與應(yīng)用." 南通大學學報(自然科學版) 20.04(2021):65-71. doi:

[316].魯星.小麥產(chǎn)量和抗旱性狀的鑒定及GWAS分析.2021.山東農(nóng)業(yè)大學,MA thesis.

[317].范濤, et al."小麥單位面積穗數(shù)和粒長主效QTL緊密連鎖KASP標記的開發(fā)及其效應(yīng)評價." 中國農(nóng)業(yè)科學 54.14(2021):2941-2951. doi:

[318].時曉磊, et al."小麥根部耐鹽性狀全基因組關(guān)聯(lián)分析." 植物遺傳資源學報 22.01(2021):57-73. doi:10.13430/j.cnki.jpgr.20200322001.

[319].劉佳熠.小麥根系性狀相關(guān)基因TaEXPA5和TaDGL1的克隆及其優(yōu)異單倍型發(fā)掘.2021.西北農(nóng)林科技大學,MA thesis.

[320].陳華斌.小麥粒形、品質(zhì)和農(nóng)藝相關(guān)性狀的全基因組關(guān)聯(lián)分析.2021.浙江大學,MA thesis.

[321].劉佳熠, et al."小麥苗期和灌漿中期根系性狀與地上形態(tài)及產(chǎn)量性狀的相關(guān)性." 麥類作物學報 41.07(2021):875-882. doi:

[322].霍志學.小麥耐鹽主效QTL的挖掘及分子標記開發(fā).2021.山東農(nóng)業(yè)大學,MA thesis.

[323].石曉涵.小麥品種抗白粉病基因功能標記分析和良星99成株期抗白粉病基因定位.2021.中國農(nóng)業(yè)科學院,MA thesis.

[324].郝佳敏.小麥新矮源鑒定及小麥矮稈基因Rht12 和 Rht-B1b在六倍體小黑麥中的遺傳效應(yīng)研究.2021.西北農(nóng)林科技大學,MA thesis.

[325].董魯浩.小麥馴化過程中亞基因組差異核苷酸模式及粒型調(diào)控位點的研究.2021.山東農(nóng)業(yè)大學,PhD dissertation.

[326].李昊哲.小麥煙農(nóng)999優(yōu)質(zhì)高產(chǎn)遺傳基礎(chǔ)解析.2021.煙臺大學,MA thesis.

[327].趙瑞, et al."小麥種質(zhì)資源成株期氮效率評價及篩選." 中國農(nóng)業(yè)科學 54.18(2021):3818-3833. doi:

[328].梅冬旭.小蘇打?qū)Σ诿渍糁笃焚|(zhì)及其淀粉性質(zhì)的影響研究.2021.中南林業(yè)科技大學,MA thesis.

[329].張霞.小偃麥種質(zhì)系SN304的鑒定及重要性狀QTL分析.2021.山東農(nóng)業(yè)大學,PhD dissertation.

[330].李雅菲.鋅與吡蟲啉或其它微肥配合噴施對小麥籽粒富鋅效果及蛋白組分的影響.2021.西北農(nóng)林科技大學,MA thesis.

[331].李鵬, 田嘉,and 李疆."新疆扁桃表型指標多樣性及育種方向分析." 中南林業(yè)科技大學學報 41.05(2021):29-41. doi:10.14067/j.cnki.1673-923x.2021.05.004.

[332].閆龍翔, et al."新型含硒納米硅肥在水稻上的施用效果初探." 上海農(nóng)業(yè)科技 .03(2021):85-87. doi:

[333].海日汗, et al."興安盟地區(qū)優(yōu)質(zhì)水稻品種比較試驗." 中國種業(yè) .11(2021):64-70. doi:10.19462/j.cnki.1671-895x.2021.11.021.

[334].王文婷.沿江地區(qū)溫光要素對優(yōu)質(zhì)粳稻產(chǎn)量與品質(zhì)的影響研究.2021.揚州大學,PhD dissertation.

[335].王偉, 萬佳,and 蔡夢影."鹽脅迫對黃山欒樹幼苗生長的影響." 南方林業(yè)科學 49.01(2021):12-14+20. doi:10.16259/j.cnki.36-1342/s.2021.01.003.

[336].韋還和, et al."鹽脅迫對水稻穎花形成及籽粒充實的影響." 作物學報 47.12(2021):2471-2480. doi:

[337].齊冰潔, et al."燕麥不同鋅效率品種苗期耐低鋅脅迫的根系形態(tài)差異." 江蘇農(nóng)業(yè)學報 37.05(2021):1119-1124. doi:

[338].丁紅元.燕山板栗不同品種（系）實生苗抗旱性評價.2021.河北科技師范學院,MA thesis.

[339].盧廣, et al."野生大麥和栽培大麥籽粒性狀及蛋白質(zhì)含量的多樣性分析." 華中農(nóng)業(yè)大學學報 40.03(2021):113-125. doi:10.13300/j.cnki.hnlkxb.2021.03.013.

[340].蘇凱, et al."葉面滯塵量對大葉黃楊光譜特征影響研究." 北京林業(yè)大學學報 43.11(2021):40-49. doi:

[341].徐誠, et al."以蛭石為主的復配基質(zhì)對黃瓜育苗的影響." 江蘇農(nóng)業(yè)科學 49.20(2021):148-154. doi:10.15889/j.issn.1002-1302.2021.20.023.

[342].徐誠.以蛭石為主的黃瓜基質(zhì)配方篩選.2021.塔里木大學,MA thesis.

[343].程欣然, et al."異源過表達Atvip1基因增強轉(zhuǎn)基因高粱對鹽堿脅迫的抗性." 華北農(nóng)學報 36.04(2021):1-9. doi:

[344].楊瑀.有機物料對退化黑土酶活性和有機碳組分及大豆幼苗生長的影響.2021.東北農(nóng)業(yè)大學,MA thesis.

[345].楚光紅, et al."幼苗期不同節(jié)位摘心對高產(chǎn)春大豆根系生長和產(chǎn)量的影響." 作物雜志 .03(2021):195-201. doi:10.16035/j.issn.1001-7283.2021.03.030.

[346].楚光紅, et al."幼苗期摘心對高產(chǎn)春大豆根系生長和產(chǎn)量的影響." 干旱地區(qū)農(nóng)業(yè)研究 39.02(2021):102-110. doi:

[347].褚夢寒.玉米SBP基因的遺傳演化及其與產(chǎn)量相關(guān)性狀的關(guān)聯(lián)分析.2021.揚州大學,MA thesis.

[348].范震, et al."玉米秸稈基纖維素保水劑對土壤持水性能及冬小麥根系生長的影響." 中國農(nóng)學通報 37.17(2021):51-57. doi:

[349].王新濤, et al."玉米籽粒相關(guān)性狀的QTL定位." 河南農(nóng)業(yè)科學 50.09(2021):9-15. doi:10.15933/j.cnki.1004-3268.2021.09.002.

[350].王雁青.圓果化香（Platycarya longipes）與香葉樹（Lindera communis）共生的水分競爭和干旱響應(yīng).2021.貴州師范大學,MA thesis.

[351].楊晨, et al."再生稻肥料管理對不同品種產(chǎn)量和品質(zhì)的影響." 中國水稻科學 36.01(2022):65-76. doi:10.16819/j.1001-7216.2022.210315.

[352].曠娜, et al."再生季稻米蛋白質(zhì)含量與外觀、加工品質(zhì)及營養(yǎng)品質(zhì)的關(guān)系." 中國糧油學報 36.05(2021):1-7. doi:

[353].楊植.棗與酸棗雜交后代花與果實性狀遺傳規(guī)律研究.2021.塔里木大學,MA thesis.

[354].仇倩倩, 馮一峰,and 吳翠云."棗種質(zhì)資源葉表型性狀遺傳多樣性分析." 新疆農(nóng)業(yè)科學 58.02(2021):282-293. doi:

[355].陳媛媛.長鏈非編碼RNA SCARNA2介導的DNA損傷修復在結(jié)直腸癌放療敏感性中的作用及機制.2021.中國人民解放軍海軍軍醫(yī)大學,PhD dissertation.

[356].邊成貴.植物根際菌鹽堿條件下促生的應(yīng)用.2021.山東農(nóng)業(yè)大學,MA thesis.

[357].馬會珍, et al."中國部分優(yōu)質(zhì)粳稻外觀及蒸煮食味品質(zhì)特征比較." 中國農(nóng)業(yè)科學 54.07(2021):1338-1353. doi:

[358].李金龍.中國甜蕎種質(zhì)資源性狀評價及其遺傳多樣性分析.2021.中國農(nóng)業(yè)科學院,MA thesis.

[359].王潤潤.種植密度和化學調(diào)控對油莎豆農(nóng)藝性狀及產(chǎn)量的影響.2021.石河子大學,MA thesis.

[360].]陳韜."種子包衣劑對小麥種子萌發(fā)及幼苗生長的影響." 農(nóng)業(yè)工程 11.06(2021):131-136. doi:

[361].麻和平, et al."重離子束輻照選育高產(chǎn)細菌素植物乳桿菌." 食品工業(yè)科技 42.15(2021):139-143. doi:10.13386/j.issn1002-0306.2021030234.

[362].張鈺, et al."重慶江津復興河流域浮游生物群落結(jié)構(gòu)、水質(zhì)及魚類資源現(xiàn)狀." 重慶師范大學學報(自然科學版) 38.04(2021):36-47. doi:

[363].韓麗君, 周帥,and 郝向春."主根長度對遼東櫟幼苗形態(tài)和光合作用的影響." 植物生理學報 57.01(2021):139-148. doi:10.13592/j.cnki.ppj.2020.0388.

[364].邵星宇.壯秧劑與播量對機插水稻不同秧齡秧苗素質(zhì)及產(chǎn)量品質(zhì)的影響.2021.揚州大學,MA thesis.

[365].胡警勻, et al."紫花苜蓿對低磷酸鹽和亞磷酸鹽脅迫響應(yīng)機制的比較分析." 中國草地學報 43.08(2021):26-33. doi:10.16742/j.zgcdxb.20200365.

[366].郭雅琪, 姚振,and 陳中義."組培條件下空心蓮子草匍匐莖段根系發(fā)育的研究." 生物災害科學 44.02(2021):212-218. doi:

[367].Monsur, Mahmuda Binte . 利用ABE技術(shù)編輯中嘉早17 Waxya基因進而改良秈稻品種食味品質(zhì). Diss. 中國農(nóng)業(yè)科學院.

[368].管紅嬌等. "兩種不同閩楠葉片的形態(tài)比較." 農(nóng)業(yè)科學與技術(shù):英文版.

[369].Cao J, Shang Y, Xu D, et al. Identification and Validation of New Stable QTLs for Grain Weight and Size by Multiple Mapping Models in Common Wheat. Front Genet. 2020;11:584859. Published 2020 Nov 11. doi:10.3389/fgene.2020.584859

[370].Chan, A.N., Wang, LL., Zhu, YJ. et al. Identification through fine mapping and verification using CRISPR/Cas9-targeted mutagenesis for a minor QTL controlling grain weight in rice. Theor Appl Genet 134, 327–337 (2021). https://doi.org/10.1007/s00122-020-03699-6.(SC-G,IF4.439)

[371].Chang, S., Chang, T., Song, Q. et al. Architectural and Physiological Features to Gain High Yield in an Elite Rice Line YLY1. Rice 13, 60 (2020). https://doi.org/10.1186/s12284-020-00419-y.(SC-G,IF3.912)

[372].Changquan Zhang, Yong Yang, Zhuanzhuan Chen, Fei Chen, Lixu Pan, Yan Lu, Qianfeng Li, Xiaolei Fan, Zhizhong Sun, and Qiaoquan Liu, Characteristics of Grain Physicochemical Properties and the Starch Structure in Rice Carrying a Mutated ALKSSIIa Gene, Journal of Agricultural and Food Chemistry 2020 68 (47), 13950-13959, DOI: 10.1021/acs.jafc.0c01471.(IF4.192)

[373].Chen J, Zhao Z, Li Y, et al. Fine-tuning roles of Osa-miR159a in rice immunity against Magnaporthe oryzae and development. Research Square; 2020. DOI: 10.21203/rs.3.rs-66826/v1.(SC-A)

[374].Chen Yuyu, Zhu Aike, Xue Pao, Wen Xiaoxia, Cao Yongrun, Wang Beifang, Zhang Yue, Shah Liaqat, Cheng Shihua, Cao Liyong, Zhang Yingxin, Effects of GS3 and GL3.1 for Grain Size Editing by CRISPR/Cas9 in Rice, Rice Science, Volume 27, Issue 5, 2020, Pages 405-413, ISSN 1672-6308, https://doi.org/10.1016/j.rsci.2019.12.010.(SC-G,IF3.162)

[375].Chen Yuyu, Zhu Aike, Xue Pao, Wen Xiaoxia, Cao Yongrun, Wang Beifang, Zhang Yue, Shah Liaqat, Cheng Shihua, Cao Liyong, Zhang Yingxin, Effects of GS3 and GL3.1 for Grain Size Editing by CRISPR/Cas9 in Rice, Rice Science, Volume 27, Issue 5, 2020, Pages 405-413, ISSN 1672-6308, https://doi.org/10.1016/j.rsci.2019.12.010.(SC-G,IF3.162)

[376].Cheng Yan, Rui-ning Wang, Xiao-yan Zhao, Emission characteristics of bioaerosol and quantitative microbiological risk assessment for equipping individuals with various personal protective equipment in a WWTP, Chemosphere, Volume 265, 2021, 129117, ISSN 0045-6535, https://doi.org/10.1016/j.chemosphere.2020.129117.(IF5.778)

[377].Dawei Zhu, Changyun Fang, Zihui Qian, Baowei Guo, Zhongyang Huo, Differences in starch structure, physicochemical properties and texture characteristics in superior and inferior grains of rice varieties with different amylose contents, Food Hydrocolloids, Volume 110, 2021, 106170, ISSN 0268-005X, https://doi.org/10.1016/j.foodhyd.2020.106170.(SC-E,IF7.053)

[378].Dong N, Yin W, Liu D, et al. Regulation of Brassinosteroid Signaling and Salt Resistance by SERK2 and Potential Utilization for Crop Improvement in Rice. Front Plant Sci. 2020;11:621859. Published 2020 Dec 10. doi:10.3389/fpls.2020.621859.(SC-G,IF4.402)

[379].Fan X, Xu Z, Wang F, Feng B, Zhou Q, et al. (2020) Identification of colored wheat genotypes with suitable quality and yield traits in response to low nitrogen input. PLOS ONE 15(4): e0229535. https://doi.org/10.1371/journal.pone.0229535.(SC-G)

[380].Fang Y, Zhang X, Zhang X, et al. A High-Density Genetic Linkage Map of SLAFs and QTL Analysis of Grain Size and Weight in Barley (Hordeum vulgare L.). Front Plant Sci. 2020;11:620922. Published 2020 Dec 17. doi:10.3389/fpls.2020.620922.(SC-G,IF4.402)

[381].Fu, L., Wu, J., Yang, S. et al. Genome-wide association analysis of stem water-soluble carbohydrate content in bread wheat. Theor Appl Genet 133, 2897–2914 (2020). https://doi.org/10.1007/s00122-020-03640-x.(IF4.439)

[382].Gongduan Fan, Zhuoyi Chen, Mingqian Xia, Banghao Du, Minchen Bao, Shimin Wu, Jiajun Zhan, Jing Luo, Optimization of remedial nano-agent and its effect on dominant algal species succession in eutrophic water body, Journal of Environmental Management, Volume 281, 2021, 111884, ISSN 0301-4797, https://doi.org/10.1016/j.jenvman.2020.111884.(AlgaeC,IF5.647)

[383].Guan, P., Shen, X., Mu, Q. et al. Dissection and validation of a QTL cluster linked to Rht-B1 locus controlling grain weight in common wheat (Triticum aestivum L.) using near-isogenic lines. Theor Appl Genet 133, 2639–2653 (2020). https://doi.org/10.1007/s00122-020-03622-z.(SC-G,IF4.439)

[384].Guihua Zou, Guowei Zhai, Song Yan, Sujuan Li, Lengbo Zhou, Yanqing Ding, Heqin Liu, Zhipeng Zhang, Jianqiu Zou, Liyi Zhang, Junping Chen, Zhanguo Xin, Yuezhi Tao, Sorghum qTGW1a encodes a G-protein subunit and acts as a negative regulator of grain size, Journal of Experimental Botany, Volume 71, Issue 18, 19 September 2020, Pages 5389–5401, https://doi.org/10.1093/jxb/eraa277.(IF5.908)

[385].Hao, H, Cheng, L, Guo, Z, Wang, L, Shi, Z. Plant community characteristics and functional traits as drivers of soil erodibility mitigation along a land degradation gradient. Land Degrad Dev. 2020; 31: 1851– 1863. https://doi.org/10.1002/ldr.3579.(LA-S,IF3.775)

[386].He C, Ding Z, Mubeen S, Guo X, Fu H, Xin G. 2020. Evaluation of three wheat (Triticum aestivum L.) cultivars as sensitive Cd biomarkers during the seedling stage. PeerJ 8:e8478 https://doi.org/10.7717/peerj.8478.(LA-S)

[387].Huan Li, Junyuan Shi, Zepeng Wang, Weiwei Zhang, Hongqiang Yang, H2S pretreatment mitigates the alkaline salt stress on Malus hupehensis roots by regulating Na+/K+ homeostasis and oxidative stress, Plant Physiology and Biochemistry, Volume 156, 2020, Pages 233-241, ISSN 0981-9428, https://doi.org/10.1016/j.plaphy.2020.09.009.(LA-S,IF3.72)

[388].Jia Lyu, Dekai Wang, Penggen Duan, Yapei Liu, Ke Huang, Dali Zeng, Limin Zhang, Guojun Dong, Yingjie Li, Ran Xu, Baolan Zhang, Xiahe Huang, Na Li, Yingchun Wang, Qian Qian, Yunhai Li, Control of Grain Size and Weight by the GSK2-LARGE1/OML4 Pathway in Rice, The Plant Cell Jun 2020, 32 (6) 1905-1918; DOI: 10.1105/tpc.19.00468

[389].Jianqing Niu, Shusong Zheng, Xiaoli Shi, Yaoqi Si, Shuiquan Tian, Yilin He, Hong-Qing Ling, Fine mapping and characterization of the awn inhibitor B1 locus in common wheat (Triticum aestivum L.), The Crop Journal, Volume 8, Issue 4, 2020, Pages 613-622, ISSN 2214-5141, https://doi.org/10.1016/j.cj.2019.12.005.(IF3.395)

[390].Jianqing Niu, Shusong Zheng, Xiaoli Shi, Yaoqi Si, Shuiquan Tian, Yilin He, Hong-Qing Ling, Fine mapping and characterization of the awn inhibitor B1 locus in common wheat (Triticum aestivum L.), The Crop Journal, Volume 8, Issue 4, 2020, Pages 613-622, ISSN 2214-5141, https://doi.org/10.1016/j.cj.2019.12.005.(SC-G,IF3.395)

[391].Jingyi Wang, Ruitong Wang, Xinguo Mao, Jialing Zhang, Yanna Liu, Qi Xie, Xiaoyuan Yang, Xiaoping Chang, Chaonan Li, Xueyong Zhang, Ruilian Jing, RING finger ubiquitin E3 ligase gene TaSDIR1-4A contributes to determination of grain size in common wheat, Journal of Experimental Botany, Volume 71, Issue 18, 19 September 2020, Pages 5377–5388, https://doi.org/10.1093/jxb/eraa271.(SC-A,IF5.908)

[392].Jinshan Zhang, Zhenyu Zhou, Jinjuan Bai, Xiaoping Tao, Ling Wang, Hui Zhang, Jian-Kang Zhu, Disruption of MIR396e and MIR396f improves rice yield under nitrogen-deficient conditions, National Science Review, Volume 7, Issue 1, January 2020, Pages 102–112, https://doi.org/10.1093/nsr/nwz142.(SC-A,IF16.693)

[393].Kashif Hussain, Zhang Yingxing, Workie Anley, Aamir Riaz, Adil Abbas, Md. Hasanuzzaman Rani, Wang Hong, Shen Xihong, Cao Liyong, Cheng Shihua, Association Mapping of Quantitative Trait Loci for Grain Size in Introgression Line Derived from Oryza Rufipogon, Rice Science, Volume 27, Issue 3, 2020, Pages 246-254, ISSN 1672-6308, https://doi.org/10.1016/j.rsci.2020.04.007.(IF3.162)

[394].Kong, M, Qiao, Q, Ma, X, Tao, Y, Maharjan Raj, P, Zhen, W. Isolation and functional analysis of the zmARM4 locus in a novel maize (Zea mays) grain‐filling mutant. Plant Breed. 2020; 139: 217– 226. https://doi.org/10.1111/pbr.12786.(SC-G)

[395].Lei L, Wang L, Wang S and Wu J (2020) Marker-Trait Association Analysis of Seed Traits in Accessions of Common Bean (Phaseolus vulgaris L.) in China. Front. Genet. 11:698. doi: 10.3389/fgene.2020.00698.(SC-G,IF3.26)

[396].Lei Wang, Qing-Lai Dang, Binyam Tedla, Biochar and alternate partial root-zone irrigation greatly enhance the effectiveness of mulberry in remediating lead-contaminated soils, Journal of Plant Ecology, Volume 13, Issue 6, December 2020, Pages 757–764, https://doi.org/10.1093/jpe/rtaa063

[397].Li Zhang, Bill Shipley, Shurong Zhou, Exploring the relationship between functional structure and ecosystem multifunctionality requires intraspecific trait variability, bioRxiv 2020.11.03.366054; doi: https://doi.org/10.1101/2020.11.03.366054.(LA-S)

[398].Li, H., Zeng, S., Luo, X. et al. Effects of small ridge and furrow mulching degradable film on dry direct seeded rice. Sci Rep 11, 317 (2021). https://doi.org/10.1038/s41598-020-79227-9.(IF3.998)

[399].LI, H., ZENG, S., LUO, X. W, et al. EFFECTS OF DEGRADABLE MULCHING FILM ON SOIL TEMPERATURE, SEED GERMINATION AND SEEDLING GROWTH OF DIRECT-SEEDED RICE (ORYZA SATIVA L.), APPLIED ECOLOGY AND ENVIRONMENTAL RESEARCH 18(6):8233-8249.(LA-S)

[400].Li, X., Chen, Z., Zhang, G. et al. Analysis of genetic architecture and favorable allele usage of agronomic traits in a large collection of Chinese rice accessions. Sci. China Life Sci. 63, 1688–1702 (2020). https://doi.org/10.1007/s11427-019-1682-6.(SC-G,IF4.611)

[401].Li, XP., Ma, XC., Wang, H. et al. Osa-miR162a fine-tunes rice resistance to Magnaporthe oryzae and Yield. Rice 13, 38 (2020). https://doi.org/10.1186/s12284-020-00396-2.(SC-A,IF3.912)

[402].Liu J, Li H, Zhang N, et al. Transcriptomic Analysis Reveals the Contribution of QMrl-7B to Wheat Root Growth and Development. Research Square; 2020. DOI: 10.21203/rs.3.rs-124839/v1.

[403].Liu L, Shi H, Li S, Sun M, Zhang R, Wang Y and Ren F (2020) Integrated Analysis of Molybdenum Nutrition and Nitrate Metabolism in Strawberry. Front. Plant Sci. 11:1117. doi: 10.3389/fpls.2020.01117.(LA-S,IF4.402)

[404].Liu, H., Sun, Z., Zhang, X. et al. QTL mapping of web blotch resistance in peanut by high-throughput genome-wide sequencing. BMC Plant Biol 20, 249 (2020). https://doi.org/10.1186/s12870-020-02455-8.(LA-S,IF3.497)

[405].Liu, H., Zhang, X., Xu, Y. et al. Identification and validation of quantitative trait loci for kernel traits in common wheat (Triticum aestivum L.). BMC Plant Biol 20, 529 (2020). https://doi.org/10.1186/s12870-020-02661-4.(SC-G,IF3.497)

[406].Lu P, Yang T, Li L, Zhao B, Liu J (2020) Response of oat morphologies, root exudates, and rhizosphere fungal communities to amendments in a saline-alkaline environment. PLOS ONE 15(12): e0243301. https://doi.org/10.1371/journal.pone.0243301.(LA-S)

[407].Lu Z, Fang Z, Liu W, et al. Grain Quality Characteristics and RVA Profile Analysis of Yuenongsimiao, a High Yield and Disease-resistant Rice Variety. Research Square; 2020. DOI: 10.21203/rs.3.rs-119602/v1.(SC-E)

[408].Luo, Q., Zheng, Q., Hu, P. et al. Mapping QTL for agronomic traits under two levels of salt stress in a new constructed RIL wheat population. Theor Appl Genet 134, 171–189 (2021). https://doi.org/10.1007/s00122-020-03689-8.(IF4.439)

[409].Min Xi, Wenge Wu, Youzun Xu, Yongjin Zhou, Gang Chen, Yalan Ji, Xueyuan Sun, iTRAQ-based quantitative proteomic analysis reveals the metabolic pathways of grain chalkiness in response to nitrogen topdressing in rice, Plant Physiology and Biochemistry, Volume 154, 2020, Pages 622-635, ISSN 0981-9428, https://doi.org/10.1016/j.plaphy.2020.06.012.(IF3.72)

[410].Niu Y, Chen T, Chen K, et al. Identification and Allele Mining of New Candidate Genes Underlying Rice Grain Weight and Grain Shape by Genome-Wide Association Study. Research Square; 2020. DOI: 10.21203/rs.3.rs-28490/v1.(SC-G)

[411].Pan, L., Lin, Wq., Yu, M. et al. Effects of Elevated Ozone Concentrations on Root Characteristics and Soil Properties of Elaeocarpus sylvestris and Michelia chapensis. Bull Environ Contam Toxicol 104, 682–688 (2020). https://doi.org/10.1007/s00128-020-02832-x.(LA-S)

[412].Peng Y, Mao B, Zhang C, Shao Y, Wu T, Hu L, Hu Y, Tang L, Li Y, Zhao B, Tang W and Xiao Y (2021) Correlations Between Parental Lines and Indica Hybrid Rice in Terms of Eating Quality Traits. Front. Nutr. 7:583997. doi: 10.3389/fnut.2020.583997.(IF3.365)

[413].Peng Zhang, Yuxiang Wen, Lei Wang, Hui Zhang, G. Geoff Wang, Tonggui Wu. Leaf Structural Carbohydrate Decreased for Pinus thunbergii along Coast–Inland Gradients. Forests 2020, 11, 449; doi:10.3390/f11040449.(LA-S)

[414].Rehman, F., Gong, H., Li, Z. et al. Identification of fruit size associated quantitative trait loci featuring SLAF based high-density linkage map of goji berry (Lycium spp.). BMC Plant Biol 20, 474 (2020). https://doi.org/10.1186/s12870-020-02567-1.(IF3.497)

[415].Ren, T., Fan, T., Chen, S. et al. Utilization of a Wheat55K SNP array-derived high-density genetic map for high-resolution mapping of quantitative trait loci for important kernel-related traits in common wheat. Theor Appl Genet (2021). https://doi.org/10.1007/s00122-020-03732-8.(IF4.439)

[416].Shi‐Rong Zhou, Hong‐Wei Xue. The rice PLATZ protein SHORT GRAIN6 determines grain size by regulating spikelet hull cell division. Journal of Integrative Plant Biology. June 2020, Volume 62, Issue 6, 847–864.(SC-E,IF4.885)

[417].Sun, K‐K, Yu, W‐S, Jiang, J‐J, et al. Mismatches between the resources for adult herbivores and their offspring suggest invasive Spartina alterniflora is an ecological trap. J Ecol. 2020; 108: 719– 732. https://doi.org/10.1111/1365-2745.13277.(LA-S,IF5.762)

[418].Tang Xinglin, Liu Guangzheng, Jiang Jiang, Lei Changju, Zhang Yunxing, Wang Liyan, Liu Xinliang (2020) Effects of growth irradiance on photosynthesis and photorespiration of Phoebe bournei leaves. Functional Plant Biology 47, 1053-1061.(LA-S)

[419].Wang a, Shu X, Jiang y, et al. Genome-wide Association Study-based Identification Genes Influencing Agronomic Traits in Rice (Oryza Sativa L.). Research Square; 2020. DOI: 10.21203/rs.3.rs-74749/v1.(SC-G)

[420].Wang, D., Yu, K., Jin, D., Sun, L., Chu, J., Wu, W., Xin, P., Gregová, E., Li, X., Sun, J., Yang, W., Zhan, K., Zhang, A. and Liu, D. (2020), Natural variations in the promoter of Awn Length Inhibitor 1 (ALI‐1) are associated with awn elongation and grain length in common wheat. Plant J, 101: 1075-1090. https://doi.org/10.1111/tpj.14575.(IF6.141)

[421].Wang, GJ., Wang, Y., Ying, JZ. et al. Identification of qLG2, qLG8, and qWG2 as novel quantitative trait loci for grain shape and the allelic analysis in cultivated rice. Planta 252, 18 (2020). https://doi.org/10.1007/s00425-020-03420-3.(SC-G,IF3.39)

[422].Wang, X., Zheng, M., Liu, H. et al. Fine-mapping and transcriptome analysis of a candidate gene controlling plant height in Brassica napus L.. Biotechnol Biofuels 13, 42 (2020). https://doi.org/10.1186/s13068-020-01687-y.(LA-S,IF4.815)

[423].Wei Zhang, Huifang Li, Liya Zhi, Qiannan Su, Jiajia Liu, Xiaoli Ren, Deyuan Meng, Na Zhang, Jun Ji, Xueyong Zhang, Junming Li, Functional markers developed from TaGS3, a negative regulator of grain weight and size, for marker-assisted selection in wheat, The Crop Journal, Volume 8, Issue 6, 2020, Pages 943-952, ISSN 2214-5141, https://doi.org/10.1016/j.cj.2020.03.003.(SC-G,IF3.395)

[424].Wei Zhang, Huifang Li, Liya Zhi, Qiannan Su, Jiajia Liu, Xiaoli Ren, Deyuan Meng, Na Zhang, Jun Ji, Xueyong Zhang, Junming Li, Functional markers developed from TaGS3, a negative regulator of grain weight and size, for marker-assisted selection in wheat, The Crop Journal, Volume 8, Issue 6, 2020, Pages 943-952, ISSN 2214-5141, https://doi.org/10.1016/j.cj.2020.03.003.(SC-G,IF3.395)

[425].Wenchao Yin, Yunhua Xiao, Mei Niu, Wenjing Meng, Lulu Li, Xiaoxing Zhang, Dapu Liu, Guoxia Zhang, Yangwen Qian, Zongtao Sun, Renyan Huang, Shiping Wang, Chun-Ming Liu, Chengcai Chu, Hongning Tong,ARGONAUTE2 Enhances Grain Length and Salt Tolerance by Activating BIG GRAIN3 to Modulate Cytokinin Distribution in Rice, The Plant Cell Jul 2020, 32 (7) 2292-2306; DOI: 10.1105/tpc.19.00542

[426].Xia Zhang, Caihong Cui, Yinguang Bao, Honggang Wang, Xingfeng Li, Molecular cytogenetic characterization of a novel wheat-Thinopyrum intermedium introgression line tolerant to phosphorus deficiency, The Crop Journal, 2020, ISSN 2214-5141, https://doi.org/10.1016/j.cj.2020.08.014.(LA-S,IF3.395)

[427].Xiao, Y., Liu, X., Zhang, L., Song, Z. and Zhou, S. (2021), The allometry of plant height explains species loss under nitrogen addition. Ecology Letters. https://doi.org/10.1111/ele.13673.(LA-S,IF8.665)

[428].Xiaohong Wang, Liming Yin, Feike A. Dijkstra, Jiayu Lu, Peng Wang, Weixin Cheng, Rhizosphere priming is tightly associated with root-driven aggregate turnover, Soil Biology and Biochemistry, Volume 149, 2020, 107964, ISSN 0038-0717, https://doi.org/10.1016/j.soilbio.2020.107964.(LA-S,IF5.795)

[429].Xiao-lan LI, Xiang LÜ, Xiao-hong WANG, Qin PENG, Ming-sheng ZHANG, Ming-jian REN, Biotic and abiotic stress-responsive genes are stimulated to resist drought stress in purple wheat, Journal of Integrative Agriculture, Volume 19, Issue 1, 2020, Pages 33-50, ISSN 2095-3119, https://doi.org/10.1016/S2095-3119(19)62659-6.(SC-G)

[430].Xin Guan, Qun Li, Tusunniyaze Maimaiti, Suke Lan, Peng Ouyang, Bowei Ouyang, Xian Wu, Sheng-Tao Yang, Toxicity and photosynthetic inhibition of metal-organic framework MOF-199 to pea seedlings, Journal of Hazardous Materials, 2020, 124521, ISSN 0304-3894, https://doi.org/10.1016/j.jhazmat.2020.124521.(IF9.038)

[431].Xu, H, Li, X, Zhang, H, et al. High temperature inhibits the accumulation of storage materials by inducing alternative splicing of OsbZIP58 during filling stage in rice. Plant Cell Environ. 2020; 43: 1879– 1896. https://doi.org/10.1111/pce.13779.(SC-E,IF6.362)

[432].Yang, L., Zhao, D., Meng, Z. et al. QTL mapping for grain yield-related traits in bread wheat via SNP-based selective genotyping. Theor Appl Genet 133, 857–872 (2020). https://doi.org/10.1007/s00122-019-03511-0.(IF4.439)

[433].Yan-huan Chen, Cheng Yan, Ya-fei Yang, Jia-xin Ma, Quantitative microbial risk assessment and sensitivity analysis for workers exposed to pathogenic bacterial bioaerosols under various aeration modes in two wastewater treatment plants, Science of The Total Environment, Volume 755, Part 2, 2021, 142615, ISSN 0048-9697, https://doi.org/10.1016/j.scitotenv.2020.142615.(HICC-B,IF6.551)

[434].Yujiao Gao, Kexin An, Weiwei Guo, Yongming Chen, Ruijie Zhang, Xue Zhang, Siyuan Chang, Vincenzo Rossi, Fangming Jin, Xinyou Cao, Mingming Xin, Huiru Peng, Zhaorong Hu, Weilong Guo, Jinkun Du, Zhongfu Ni, Qixin Sun, Yingyin Yao, The endosperm-specific transcription factor TaNAC019 regulates glutenin and starch accumulation and its elite allele improves wheat grain quality, The Plant Cell, 2021;, koaa040, https://doi.org/10.1093/plcell/koaa040.(IF9.618)

[435].Yu-Juan Lin, Yu-Xi Feng, Yan-Hong Li, Guo Yu, Xiao-Zhang Yu, Fuzzy synthetic evaluation of the impact of plant growth regulators on the root phenotype traits of rice seedlings under thiocyanate stress, Plant Physiology and Biochemistry, Volume 158, 2021, Pages 182-189, ISSN 0981-9428, https://doi.org/10.1016/j.plaphy.2020.10.029.(LA-S,IF3.72)

[436].Yunhua Chi, Kimani Wilson, Zhiquan Liu, Xiaoyuan Wu, Li Shang, Limin Zhang, Haichun Jing, Huaiqing Hao, Vacuolar invertase genes SbVIN1 and SbVIN2 are differently associated with stem and grain traits in sorghum (Sorghum bicolor), The Crop Journal, Volume 8, Issue 2, 2020, Pages 299-312, ISSN 2214-5141, https://doi.org/10.1016/j.cj.2019.06.012.(IF3.395)

[437].Yunhua Chi, Kimani Wilson, Zhiquan Liu, Xiaoyuan Wu, Li Shang, Limin Zhang, Haichun Jing, Huaiqing Hao, Vacuolar invertase genes SbVIN1 and SbVIN2 are differently associated with stem and grain traits in sorghum (Sorghum bicolor), The Crop Journal, Volume 8, Issue 2, 2020, Pages 299-312, ISSN 2214-5141, https://doi.org/10.1016/j.cj.2019.06.012.(SC-E,IF3.395)

[438].Yunlong Pang, Chunxia Liu, Danfeng Wang, Paul St. Amand, Amy Bernardo, Wenhui Li, Fang He, Linzhi Li, Liming Wang, Xiufang Yuan, Lei Dong, Yu Su, Huirui Zhang, Meng Zhao, Yunlong Liang, Hongze Jia, Xitong Shen, Yue Lu, Hongming Jiang, Yuye Wu, Anfei Li, Honggang Wang, Lingrang Kong, Guihua Bai, Shubing Liu, High-Resolution Genome-wide Association Study Identifies Genomic Regions and Candidate Genes for Important Agronomic Traits in Wheat, Molecular Plant, Volume 13, Issue 9, 2020, Pages 1311-1327, ISSN 1674-2052, https://doi.org/10.1016/j.molp.2020.07.008.(IF12.084)

[439].Zeng, X., Luo, Y., Vu, N.T.Q. et al. CRISPR/Cas9-mediated mutation of OsSWEET14 in rice cv. Zhonghua11 confers resistance to Xanthomonas oryzae pv. oryzae without yield penalty. BMC Plant Biol 20, 313 (2020). https://doi.org/10.1186/s12870-020-02524-y.(SC-G,IF3.497)

[440].Zhang L-L, Li Y, Zheng Y-P, Wang H, Yang X, Chen J-F, Zhou S-X, Wang L-F, Li X-P, Ma X-C, Zhao J-Q, Pu M, Feng H, Fan J, Zhang J-W, Huang Y-Y and Wang W-M (2020) Expressing a Target Mimic of miR156fhl-3p Enhances Rice Blast Disease Resistance Without Yield Penalty by Improving SPL14 Expression. Front. Genet. 11:327. doi: 10.3389/fgene.2020.00327.(SC-G,IF3.26)

[441].Zhang, J., Jiao, X., Du, Q. et al. Effects of Vapor Pressure Deficit and Potassium Supply on Root Morphology, Potassium Uptake, and Biomass Allocation of Tomato Seedlings. J Plant Growth Regul (2020). https://doi.org/10.1007/s00344-020-10115-2.(IF2.672)

[442].Zhang, J.; Tong, T.; Potcho, P.M.; Huang, S.; Ma, L.; Tang, X. Nitrogen Effects on Yield, Quality and Physiological Characteristics of Giant Rice. Agronomy 2020, 10, 1816. https://doi.org/10.3390/agronomy10111816.(SC-E)

[443].Zhang, L., Ma, B., Bian, Z. et al. Grain Size Selection Using Novel Functional Markers Targeting 14 Genes in Rice. Rice 13, 63 (2020). https://doi.org/10.1186/s12284-020-00427-y.(SC-G,IF3.912)

[444].Zhang, M., Zhou, Zp., Chen, Yy. et al. Finding new addictive QTL for yield traits based on a high-density genetic map in hybrid rice. Plant Growth Regul 93, 105–115 (2021). https://doi.org/10.1007/s10725-020-00669-2.(IF2.388)

[445].Zhang, N., Zhang, X., Song, L. et al. Identification and validation of the superior alleles for wheat kernel traits detected by genome-wide association study under different nitrogen environments. Euphytica 216, 52 (2020). https://doi.org/10.1007/s10681-020-2572-5.(SC-G)

[446].Zhanqiang Hu, Hua Yang, Mamoun Chaima, Changyun Fang, Lin Lu, Xianqiao Hu, Bai Du, Zhiwei Zhu, Jianying Huang, A visualization and quantification method to evaluate the water-absorbing characteristics of rice, Food Chemistry, Volume 331, 2020, 127050, ISSN 0308-8146, https://doi.org/10.1016/j.foodchem.2020.127050.(SC-E,IF6.306)

[447].Zhanqiang Hu, Yuexi Yang, Lin Lu, Ye Chen, Zhiwei Zhu, Jianying Huang, Kinetics of water absorption expansion of rice during soaking at different temperatures and correlation analysis upon the influential factors, Food Chemistry, Volume 346, 2021, 128912, ISSN 0308-8146, https://doi.org/10.1016/j.foodchem.2020.128912.(SC-E,IF6.306)

[448].Zhao H., Yan W., Yu K., Wang T., Khattak A.N., Tian E. (2021): QTL identification for nine seed-related traits in Brassica juncea using a multiparent advanced generation intercross (MAGIC) population. Czech J. Genet. Plant Breed., 57: 9−18.(SC-G)

[449].Zhao, B, Wang, L, Shang, J, et al. Application of pearling in modified roller milling of hull-less barley and effect on noodles quality. J Food Process Preserv. 2020; 44:e14838. https://doi.org/10.1111/jfpp.14838.(SC-A)

[450].Zhao, J.; Ajadi, A.A.; Wang, Y.; Tong, X.; Wang, H.; Tang, L.; Li, Z.; Shu, Y.; Liu, X.; Li, S.; Wang, S.; Liu, W.; Zhang, J. Genome-Wide Identification of lncRNAs During Rice Seed Development. Genes 2020, 11, 243. https://doi.org/10.3390/genes11030243.(SC-G,IF3.759)

[451].Zheng, L., Liu, P., Zhang, S. et al. Favorable allele mining and breeding utilization of ALK in rice. Mol Breeding 40, 107 (2020). https://doi.org/10.1007/s11032-020-01183-z.(SC-G)

[452].Zhou, S.‐R. and Xue, H.‐W. (2020), The rice PLATZ protein SHORT GRAIN6 determines grain size by regulating spikelet hull cell division. J. Integr. Plant Biol, 62: 847-864. https://doi.org/10.1111/jipb.12851.(SC-E)

[453].Zhou, S.‐X., Zhu, Y., Wang, L.‐F., Zheng, Y.‐P., Chen, J.‐F., Li, T.‐T., Yang, X.‐M., Wang, H., Li, X.‐P., Ma, X.‐C., Zhao, J.‐Q., Pu, M., Feng, H., Li, Y., Fan, J., Zhang, J.‐W., Huang, Y.‐Y. and Wang, W.‐M. (2020), Osa‐miR1873 fine‐tunes rice immunity against Magnaporthe oryzae and yield traits. J. Integr. Plant Biol, 62: 1213-1226. https://doi.org/10.1111/jipb.12900.(SC-A,IF4.885)

[454].Zhu, Z., Zhang, H., Leng, J. et al. Isolation and characterization of plant growth-promoting rhizobacteria and their effects on the growth of Medicago sativa L. under salinity conditions. Antonie van Leeuwenhoek 113, 1263–1278 (2020). https://doi.org/10.1007/s10482-020-01434-1.(LA-S)

[455].Workie Anley Zegeye. 水稻半矮稈基因OsFBK4的定位及功能分析[D].中國農(nóng)業(yè)科學院,2020.

[456].艾鵬睿,馬英杰,海英.邊行效應(yīng)對間作棉花生理性狀及產(chǎn)量的影響[J].水資源與水工程學報,2020,31(04):138-144.

[457].蔡俊. SlWRKY3通過TPK1b負調(diào)控番茄對灰霉病的抗性[D].華中農(nóng)業(yè)大學,2020.

[458].蔡夢穎,張平,宋煒涵,余江峰,郝棲賢,王平,劉世家,王益華,江玲,萬建民.通過CRISPR/Cas9技術(shù)靶向編輯SSSⅡb基因改良稻米品質(zhì)[J].南京農(nóng)業(yè)大學學報,2021,44(01):18-26.

[459].蔡欣月. 轉(zhuǎn)錄因子AtVIP1介導IAA與ABA信號途徑調(diào)控高粱側(cè)根發(fā)育的分子機制初探[D].黑龍江八一農(nóng)墾大學,2020.

[460].曹彩紅,曹玲玲,趙立群,田雅楠.不同基質(zhì)配比對草莓脫毒苗馴化移栽的影響[J].蔬菜,2020(06):57-62.

[461].曹珊. 生態(tài)條件和后期干旱對小麥種子活力形成的影響及生理差異分析[D].山東農(nóng)業(yè)大學,2020.

[462].陳博寧,章潔瓊,崔婭松,霍冬敖,陳慶富.苦蕎遺傳群體農(nóng)藝性狀分析[J].耕作與栽培,2020,40(03):13-16.

[463].陳吉寶.綠豆產(chǎn)量性狀的QTL定位[J].中國農(nóng)業(yè)科技導報,2020,22(10):38-48.

[464].陳黎,朱超,朱慶祥,王翠鳴,鮑佳書,莫辰,施婷婷,萬志兵.NaN_3處理對烏桕種子萌發(fā)及幼苗生長的影響[J].南京林業(yè)大學學報(自然科學版),2020,44(04):47-54.

[465].陳庭木,方兆偉,王寶祥,劉艷,邢運高,徐大勇.高黃酮水稻品種資源的鑒定與篩選[J].中國稻米,2020,26(02):41-43.

[466].陳庭木,邢運高,孫志廣,方兆偉,王寶祥,劉艷,徐大勇.水稻高脂肪含量資源篩選[J].江蘇農(nóng)業(yè)科學,2020,48(08):74-77.

[467].陳曦. 多群體定位水稻粒形數(shù)量性狀位點[D].廣西大學,2020.

[468].褚云霞,任麗,鄧姍,李壽國,張靖立,陳海榮.基于DUS測試的上海地區(qū)小麥新品種評價[J].分子植物育種,2020,18(07):2399-2408.

[469].單飛彪,閆文芝,杜瑞霞,王永行,楊欽方,劉春暉,白立華,苗雨,賴運平.救荒野豌豆品種DUS測試主要數(shù)量性狀篩選與評價[J].中國種業(yè),2020(08):60-65.

[470].丁一然,李英文.長溪河浮游生物群落特征及水質(zhì)評價[J].西華師范大學學報(自然科學版),2020,41(03):242-248.

[471].董晨星. 草莓種質(zhì)資源生物學鑒定及對激素的反應(yīng)[D].山東農(nóng)業(yè)大學,2020.

[472].杜冬冬. 鹽堿條件下植物根際菌促生作用的研究[D].山東農(nóng)業(yè)大學,2020.

[473].范可欣. 小麥NGli-D2、Sec-1~s和1Dx5+1Dy10高代聚合體的品質(zhì)和農(nóng)藝性狀分析[D].山東農(nóng)業(yè)大學,2020.

[474].付路平. 小麥莖稈水溶性碳水化合物含量遺傳解析與標記發(fā)掘[D].中國農(nóng)業(yè)科學院,2020.

[475].付路平. 小麥莖稈水溶性碳水化合物含量遺傳解析與標記發(fā)掘[D].中國農(nóng)業(yè)科學院,2020.

[476].龔睿,畢玉科,張杰,奉樹成,張春英.Cu、Zn制劑處理對貼梗海棠容器苗生長的影響[J].東北林業(yè)大學學報,2020,48(05):16-20.

[477].龔睿,夏溪,張春英.Cu、Zn制劑的化學控根對平邑甜茶容器苗根構(gòu)型影響[J].西部林業(yè)科學,2020,49(02):154-159.

[478].谷瑞,徐森,陳雙林,郭子武,章超.鞭長和鞭徑對地被竹鞭段繁育容器苗生長和葉片養(yǎng)分的影響[J].東北林業(yè)大學學報,2020,48(09):34-40.

[479].關(guān)志林. 甘藍型油菜生態(tài)型分化的遺傳基礎(chǔ)解析[D].華中農(nóng)業(yè)大學,2020.

[480].管柳蓉,劉祖培,徐冉,段朋根,張國政,于海躍,李靜,羅越華,李云海.一個新的OsBRI1弱等位突變體的鑒定及其調(diào)控種子大小的功能研究[J].植物學報,2020,55(03):279-286.

[481].管祥洋,孔明,張毅敏,韓巍,楊飛,張志偉,顧詩云,錢文瀚.滆湖水華初期浮游植物群落特征及與水環(huán)境因子相關(guān)性分析[J].環(huán)境科學學報,2020,40(03):901-914.

[482].郭燕,張樹航,李穎,張馨方,王廣鵬.中國板栗238份品種(系)葉片形態(tài)、解剖結(jié)構(gòu)及其抗旱性評價[J].園藝學報,2020,47(06):1033-1046.

[483].韓志順,鄭敏娜,梁秀芝,康佳惠,陳燕妮.干旱脅迫對不同紫花苜蓿品種形態(tài)特征和生理特性的影響[J].中國草地學報,2020,42(03):37-43.

[484].郝好鑫. 侵蝕環(huán)境下根系功能性狀對土壤保持的影響及機制[D].華中農(nóng)業(yè)大學,2020.

[485].何瑞,馬靖福,劉媛,張沛沛,栗孟飛,王彩香,宿俊吉,程宏波,楊德龍.小麥粒形QTL定位及其與水分環(huán)境互作遺傳分析[J].麥類作物學報,2020,40(08):906-914.

[486].何瑞. 小麥粒形相關(guān)性狀QTL定位及其元分析[D].甘肅農(nóng)業(yè)大學,2020.

[487].洪佳樂. 水稻細胞分裂素氧化酶OsCKX3的生物學功能研究[D].浙江師范大學,2020.

[488].胡群. 中期氮肥調(diào)控對優(yōu)良食味粳稻產(chǎn)量和品質(zhì)的效應(yīng)及其機理[D].揚州大學,2020.

[489].黃婧芬,康敏,殷勤,王艷艷,楊子怡,鄭曉明,喬衛(wèi)華,楊慶文,孫希平.茶陵野生稻導入系遺傳分析及重要性狀相關(guān)QTL鑒定[J].植物遺傳資源學報,2020,21(03):674-686.

[490].黃夢迪,吳會琴,王娜,楊璞,高金鋒,高小麗.不同品種綠豆理化特性和抗氧化性研究[J].食品研究與開發(fā),2020,41(06):32-37.

[491].黃夢迪. 不同品種綠豆及其豆芽品質(zhì)研究與評價[D].西北農(nóng)林科技大學,2020.

[492].黃鵬. 山葵植物水培技術(shù)研究[D].成都大學,2020.

[493].黃世杰. 不同番茄品種對弱光生理響應(yīng)差異的研究[D].山東農(nóng)業(yè)大學,2020.

[494].黃文功. 亞麻和水曲柳對低鉀或磷耐受性及基因表達調(diào)控研究[D].東北林業(yè)大學,2020.

[495].計宏蕊,張夢瑜,王曉娜.重金屬鎘影響下油松外生菌根的形態(tài)特征[J].林業(yè)與生態(tài)科學,2020,35(04):377-386.

[496].姜朋. 小麥核心種質(zhì)寧麥9號與揚麥158重要農(nóng)藝性狀及赤霉病抗性的遺傳解析[D].山東農(nóng)業(yè)大學,2020.

[497].姜順邦,韋小麗.水分供應(yīng)量與灌溉方式對花櫚木容器苗生長及節(jié)水節(jié)肥的影響[J].西北農(nóng)林科技大學學報(自然科學版),2020,48(08):69-77.

[498].黎雨薇. 施氮量對水稻籽粒灌漿特性、產(chǎn)量和品質(zhì)的影響[D].華中農(nóng)業(yè)大學,2020.

[499].李丹竹,曾寧波,張志飛,劉寧芳,徐倩,胡龍興.漬水脅迫對不同磷水平下紫花苜蓿根系生長的影響[J].草地學報,2020,28(06):1563-1571.

[500].李丹竹,張強,徐倩,張志飛,劉寧芳,曾寧波,胡龍興.漬水脅迫對不同秋眠級紫花苜蓿苗期根系形態(tài)的影響[J].草地學報,2020,28(02):420-428.

[501].李發(fā)奎,李金霞,孫小妹,陳年來.黑果枸杞莖葉生長及其生態(tài)化學計量特征對灌水施肥的響應(yīng)[J].干旱區(qū)研究,2020,37(02):452-461.

[502].李發(fā)奎. 黑果枸杞器官間生態(tài)化學計量特征比較研究[D].甘肅農(nóng)業(yè)大學,2019.

[503].李虎,陳傳華,劉廣林,吳子帥,羅群昌,朱其南,李秋雯.銅、鋅肥對優(yōu)質(zhì)稻桂育9號的影響效應(yīng)研究[J].江西農(nóng)業(yè)大學學報,2020,42(03):448-457.

[504].李虎,黃秋要,陳傳華,劉廣林,吳子帥,羅群昌,朱其南,李秋雯.種植密度和施氮量對桂育8號產(chǎn)量及稻米外觀和加工品質(zhì)的影響[J].西南農(nóng)業(yè)學報,2020,33(04):718-724.

[505].李歡,陳惠查,阮仁超,黎小冰,康秀晗,譚金玉.貴州特色蠶豆種質(zhì)資源主要農(nóng)藝性狀分析與綜合評價[J].農(nóng)技服務(wù),2020,37(08):74-76+78.

[506].李嘉琦. 基于GWAS解析水稻粒型變異的遺傳基礎(chǔ)[D].沈陽師范大學,2020.

[507].李進. 水稻穗長QTL qPL-3的精細定位[D].揚州大學,2020.

[508].李軍軍. 不同N、P供給水平對駱駝刺和芨芨草組織養(yǎng)分特征及根系構(gòu)型的影響[D].蘭州大學,2020.

[509].李樂晨. 野生二粒小麥居群進化及其產(chǎn)量性狀全基因組關(guān)聯(lián)分析[D].河南大學,2020.

[510].李敏. 玉米自交系種子萌發(fā)期間物質(zhì)利用率差異及全基因組關(guān)聯(lián)分析[D].山東農(nóng)業(yè)大學,2020.

[511].李明,李朝蘇,劉淼,吳曉麗,魏會廷,湯永祿,熊濤.耕作播種方式對稻茬小麥根系發(fā)育、土壤水分和硝態(tài)氮含量的影響[J].應(yīng)用生態(tài)學報,2020,31(05):1425-1434.

[512].李盼盼,朱玉君,郭梁,莊杰云,樊葉楊.利用剩余雜合體衍生的近等基因系精細定位水稻粒長微效QTL qGL1.1[J].中國水稻科學,2020,34(02):125-134.

[513].李盼盼. 水稻粒長QTL qGL1.1的精細定位[D].中國農(nóng)業(yè)科學院,2020.

[514].李倩,董春娟,田雅楠,曹玲玲,尚慶茂.潮汐灌溉供液高度對黃瓜穴盤苗生長發(fā)育與水肥利用的影響[J].中國蔬菜,2020(01):56-62.

[515].李如雪. 小麥種子活力狀況分析與種子活力評價技術(shù)研究[D].山東農(nóng)業(yè)大學,2020.

[516].李珊珊. 調(diào)環(huán)酸鈣和CPPU對蘋果營養(yǎng)生長和花芽形成的影響[D].山東農(nóng)業(yè)大學,2020.

[517].李月娟,馬錦林,王東雪,魏育,葉航.不同基質(zhì)理化性質(zhì)對香花油茶扦插生根的影響[J].熱帶農(nóng)業(yè)科學,2020,40(03):25-30.

[518].李月娟,王東雪,魏育,朱慧,馬錦林.不同外源激素處理下香花油茶扦插生根效果的綜合評價[J].廣西林業(yè)科學,2020,49(01):49-53.

[519].林升麗. 全基因組和全轉(zhuǎn)錄組關(guān)聯(lián)分析解析油菜千粒重自然變異的遺傳機制[D].華中農(nóng)業(yè)大學,2020.

[520].劉春花. 供磷水平對核桃實生苗生長、生理特性及土壤養(yǎng)分的影響[D].塔里木大學,2020.

[521].劉寒. 營養(yǎng)平衡對刺五加生長代謝的生物調(diào)控機制[D].黑龍江中醫(yī)藥大學,2020.

[522].劉凱強,劉文輝,賈志鋒,馬祥,梁國玲.干旱脅迫對‘青燕1號’燕麥器官生長及水分利用效率的影響[J].草地學報,2020,28(06):1552-1562.

[523].劉凱強. 水分脅迫對燕麥生長發(fā)育及產(chǎn)量構(gòu)成的影響[D].青海大學,2020.

[524].劉娜. 過表達ZmDWF4提高玉米產(chǎn)量的研究[D].山東農(nóng)業(yè)大學,2020.

[525].劉守旭. 玉米Mu/MuDr突變體庫的構(gòu)建和LSC1基因的精細定位[D].山東農(nóng)業(yè)大學,2020.

[526].劉同金. 基于機器視覺的蘋果體尺參數(shù)測量方法研究[D].塔里木大學,2020.

[527].劉曉偉. 土壤缺鉀對不同品種冬小麥鉀素吸收、品質(zhì)及碳氮代謝的影響[D].河北農(nóng)業(yè)大學,2020.

[528].劉迎超. 光照強度對煙草漂浮育苗基質(zhì)理化生物性狀影響研究[D].山東農(nóng)業(yè)大學,2020.

[529].劉盈盈,韋小麗,周紫晶,邵暢暢.硝態(tài)氮供應(yīng)水平對棕櫚幼苗根系形態(tài)及苗木生長的影響[J].東北林業(yè)大學學報,2020,48(11):1-7.

[530].羅進. 鈦表面鈷摻入羥基磷灰石復合涂層的制備及表征和生物活性研究[D].遵義醫(yī)科大學,2020.

[531].呂丹. 苦蕎種質(zhì)資源產(chǎn)量性狀和籽粒黃酮含量與SSR標記的關(guān)聯(lián)分析[D].貴州師范大學,2020.

[532].呂立軍,石奡坤,袁瑞江,李衍素,閆妍,于賢昌,賀超興.大蔥品種苗期耐低氮性的綜合評價及鑒定指標篩選[J].中國蔬菜,2020(12):49-55.

[533].馬本賀,陶志英,吳早保,吳斌,王海華,徐先棟,陳翠云.大鱗副泥鰍新品系的人工繁殖及胚胎發(fā)育[J].水產(chǎn)科學,2020,39(06):863-870.

[534].馬鴻潤. 面向人工智能育種的大豆種子表型特征數(shù)據(jù)采集與分析[D].山東大學,2020.

[535].馬瑞,黃成亮,孟英,劉猷紅.播期對三江平原主栽水稻品種品質(zhì)的影響[J].中國稻米,2020,26(02):80-83.

[536].馬旭輝. 褪黑素對玉米根系構(gòu)型及其抗旱性影響的初步研究[D].中國農(nóng)業(yè)科學院,2020.

[537].馬艷明,馮智宇,王威,張勝軍,郭營,倪中福,劉杰.新疆冬小麥品種農(nóng)藝及產(chǎn)量性狀遺傳多樣性分析[J].作物學報,2020,46(12):1997-2007.

[538].毛恒,熊躍東,李馨,周放姣,胡銚,尹忠良,周萌,鄧化冰.4個秈稻光溫敏核不育系及其所配組合的稻米品質(zhì)評價[J].雜交水稻,2020,35(05):88-93.

[539].牟立同,荀咪,曹輝,楊洪強,王利,范偉國,陳金旭,馮豐,李萍.果木屑腐熟物對平邑甜茶幼苗生長和土壤養(yǎng)分及酶活性的影響[J].山東農(nóng)業(yè)大學學報(自然科學版),2020,51(06):1027-1031.

[540].饒澤來,朱桂才,姚振.融合表達乙醇酸氧化酶和過氧化氫酶轉(zhuǎn)基因馬鈴薯的表型分析[J].種子,2020,39(03):39-42+51.

[541].饒澤來. 在馬鈴薯中融合表達GLO-CAT構(gòu)建光呼吸支路的研究[D].長江大學,2020.

[542].任達.斷根處理對遼東櫟1年生裸根苗成活率及生長指標的影響[J].山西林業(yè)科技,2020,49(03):13-14+56.

[543].邵暢暢,韋小麗,周紫晶,劉盈盈.供磷水平對棕櫚幼苗生長及根系形態(tài)的影響[J].東北林業(yè)大學學報,2021,49(01):12-15.

[544].佘遠國,張瑩,曹克麗,李秀梅,章璐,汪洋.基質(zhì)配方對油茶容器苗根系生物量及形態(tài)的影響[J].經(jīng)濟林研究,2020,38(04):11-16.

[545].時曉磊,嚴勇亮,石書兵,張金波,王繼慶,謝磊,耿洪偉.NaCl脅迫下小麥根部耐鹽性狀QTL分析[J].新疆農(nóng)業(yè)大學學報,2020,43(01):1-9.

[546].宋巖,張銳,魚尚奇,劉春花,高山,王雨,羅立新,張建良.不同施氮水平對核桃砧木苗形態(tài)特征及生理特性的影響[J].福建農(nóng)業(yè)學報,2020,35(03):309-316.

[547].孫艷楠. 燕麥不同品種鋅效率的評價及對低鋅脅迫的響應(yīng)[D].內(nèi)蒙古農(nóng)業(yè)大學,2020.

[548].陶菊紅,季向東,王小虎,蘭國防,陸燕,柯璦,潘斌清,唐樂堯,馬剛,端木銀熙,張濤.三個江南地區(qū)適用粳稻選育品系的常規(guī)農(nóng)藝性狀[J].常熟理工學院學報,2020,34(05):86-90.

[549].陶若芙. 水稻轉(zhuǎn)錄因子OsBBX4的功能研究[D].浙江大學,2020.

[550].田貴生,王志賓,李小坤,朱丹丹,張江林,劉秋霞.“稻-再-油/肥”輪作和施氮對水稻產(chǎn)量及籽粒灌漿特性的影響[J].中國農(nóng)業(yè)科技導報,2021,23(01):146-153.

[551].萬海霞,蔡進軍,郭永忠,馬璠,許浩,韓新生,王月玲,董立國.寧夏南部黃土丘陵區(qū)典型草本根系分布特征[J].水土保持研究,2020,27(04):149-156+163.

[552].汪文佳. （普通小麥×長穗偃麥草）F_1鑒定及生理特性的比較研究[D].淮北師范大學,2020.

[553].王亮. 防治三七黑斑病的多抗霉素發(fā)酵生產(chǎn)技術(shù)研究[D].陜西科技大學,2020.

[554].王順斌. 適應(yīng)亞熱帶環(huán)境的亞麻薺突變體的篩選與研究[D].浙江農(nóng)林大學,2020.

[555].王文靜. 脫水劑和收獲方式對小麥種子活力的調(diào)控作用[D].山東農(nóng)業(yè)大學,2020.

[556].王文團. 耐鹽堿細菌篩選與生物菌肥對鹽堿地作物的影響[D].山東農(nóng)業(yè)大學,2020.

[557].王小雷,李煒星,曾博虹,孫曉棠,歐陽林娟,陳小榮,賀浩華,朱昌蘭.基于染色體片段置換系對水稻粒形及千粒重QTL檢測與穩(wěn)定性分析[J].作物學報,2020,46(10):1517-1525.

[558].王宇智. 氮肥運籌對旱直播水稻產(chǎn)量、品質(zhì)及氮素利用率的影響[D].沈陽農(nóng)業(yè)大學,2020.

[559].王園園. 叢枝菌根真菌和鉀調(diào)控寧夏枸杞耐鹽及鉀吸收機制[D].西北農(nóng)林科技大學,2020.

[560].王澤鵬,岳松青,荀咪,石鈞元,張瑋瑋,楊洪強.H_2S預處理對NaCl脅迫下平邑甜茶根系氧化損傷和細胞死亡的影響[J].植物生理學報,2020,56(10):2241-2247.

[561].王澤鵬. NaHS對NaCl脅迫下平邑甜茶根系離子流及相關(guān)基因表達的影響[D].山東農(nóng)業(yè)大學,2020.

[562].衛(wèi)平洋,裘實,唐健,肖丹丹,朱盈,劉國棟,邢志鵬,胡雅杰,郭保衛(wèi),高尚勤,魏海燕,張洪程.安徽沿淮地區(qū)優(yōu)質(zhì)高產(chǎn)常規(guī)粳稻品種篩選及特征特性[J].作物學報,2020,46(04):571-585.

[563].魏琦. 硫酸鉀/銨片劑肥料對蘋果根區(qū)土壤環(huán)境及幼樹生長的影響[D].山東農(nóng)業(yè)大學,2020.

[564].烏國俊,龔梨霞,李丹竹,張志飛.原花青素對酸銅脅迫下紫花苜蓿種子萌發(fā)的影響[J].草學,2020(02):40-45+53.

[565].吳江,龐瀾,阿里木江·阿不都熱合曼,朱勇荷,馬秀英,陳鵬,張荔霜,岳躍明,吳濤.聚維酮碘胃部灌洗對內(nèi)鏡下黏膜剝離術(shù)患者胃部細菌菌落及感染率的影響[J].中華醫(yī)院感染學雜志,2020,30(06):903-907.

[566].肖月華,高建芹,王潔,鄒玉國,陳松,周曉嬰,龍衛(wèi)華,彭琦.種子處理劑對甘藍型油菜生長發(fā)育及菌核病的效應(yīng)[J].江蘇農(nóng)業(yè)科學,2020,48(23):111-114.

[567].熊潔,丁戈,李書宇,陳倫林,宋來強.鋁脅迫對不同耐鋁油菜品種苗期生長發(fā)育和養(yǎng)分吸收的影響[J].華北農(nóng)學報,2020,35(06):165-171.

[568].徐飛,王紓馨,程甲,張毓梅,焦彬彬.可視化自動識別技術(shù)與傳統(tǒng)人眼識別在大米外觀品質(zhì)檢驗中的比較分析[J].食品安全質(zhì)量檢測學報,2020,11(20):7280-7286.

[569].徐易如. 小麥苗期生物量、成熟期農(nóng)藝性狀對氮、磷、鉀脅迫的響應(yīng)及其遺傳解析[D].山東農(nóng)業(yè)大學,2020.

[570].許趙蒙. 水稻紋枯病抗性相關(guān)基因OsSBR1的功能鑒定和組學分析[D].浙江師范大學,2020.

[571].薛其勤,別茹,常宇涵,邢明,楊會,張昆,劉風珍,萬勇善.花生種皮顏色及花青素含量的遺傳分析[J].花生學報,2020,49(01):19-24.

[572].晏權(quán). GZ95-6分枝麥穗分枝性狀的遺傳分析及改良[D].貴州大學,2020.

[573].楊莉. 普通小麥籽粒相關(guān)性狀QTL定位與驗證[D].中國農(nóng)業(yè)科學院,2020.

[574].楊娜,楊鑫,李英文,劉智皓,陳啟亮,沈彥君.重慶市涪陵區(qū)梨香溪流域和麻溪河流域浮游生物及魚類資源現(xiàn)狀[J].重慶師范大學學報(自然科學版),2020,37(06):63-77.

[575].殷敏,劉少文,褚光,徐春梅,王丹英,章秀福,陳松.長江下游稻區(qū)不同類型雙季晚粳稻產(chǎn)量與生育特性差異[J].中國農(nóng)業(yè)科學,2020,53(05):890-903.

[576].于瀟. 煙臺扇貝養(yǎng)殖區(qū)水質(zhì)變化及其對扇貝生長的影響[D].煙臺大學,2020.

[577].俞寧寧. 水楊酸羥化酶在調(diào)節(jié)水稻抗病和生長中的功能研究[D].浙江師范大學,2020.

[578].張芳,任毅,嚴勇亮,付婧璇,耿洪偉.小麥TaGS-D1與TaFlo2-A1等位變異對粒重的影響[J].麥類作物學報,2020,40(05):533-546.

[579].張國慶. 西藏“一江兩河”流域典型區(qū)段藻類群落時空分布特征及其與環(huán)境因子間的關(guān)系[D].西藏大學,2020.

[580].張洪超. 三唑酮在不同作物、不同土壤類型中的吸收、轉(zhuǎn)運規(guī)律及特性[D].浙江大學,2020.

[581].張紀. 引進大麥種質(zhì)資源籽粒性狀間關(guān)系研究與評價利用[D].西北農(nóng)林科技大學,2020.

[582].張嘉宇. 水汽壓差（VPD）與鉀素對不同溫度下番前營養(yǎng)吸收與光合生理的影響[D].西北農(nóng)林科技大學,2020.

[583].張金波,王小波,嚴勇亮,肖菁,彭惠茹,叢花.新疆春小麥育成品種耐熱性評價[J].麥類作物學報,2020,40(09):1055-1063.

[584].張金波,嚴勇亮,王小波,路子峰,肖菁,彭惠茹,叢花.新疆春小麥育成品種遺傳演變分析[J].新疆農(nóng)業(yè)科學,2020,57(03):418-426.

[585].張俊,郝西,朱亞娟,臧秀旺,劉娟,張佳蕾,張曼,崔亞男,湯豐收,董文召.不同保水劑用量對花生發(fā)育及氮素積累的影響[J].花生學報,2020,49(02):43-48.

[586].張淼. 超級稻內(nèi)2優(yōu)6號產(chǎn)量性狀QTL的定位[D].中國農(nóng)業(yè)科學院,2020.

[587].張曉蕊,謝露露,董春娟,尚慶茂.葉片切除對番茄扦插苗莖基部糖含量及不定根發(fā)生的影響[J].中國蔬菜,2020(11):60-65.

[588].張曉蕊. 茄果類蔬菜扦插苗莖基部碳水化合物積累與不定根發(fā)生[D].中國農(nóng)業(yè)科學院,2020.

[589].張鄭偉. 中國多年生野生大豆Glycine tomentella和Glycine tabacina的遺傳多樣性研究[D].中國農(nóng)業(yè)科學院,2020.

[590].趙晨浩. 新型保水劑和保水型控釋肥的研制及對土壤持水性狀改良的機制[D].山東農(nóng)業(yè)大學,2020.

[591].趙靚,戰(zhàn)勇,張恒斌,曾凱,劉濤.灌水量和種植密度互作對籽瓜產(chǎn)量及籽粒性狀的影響[J].北方園藝,2020(22):1-9.

[592].趙坤. 固氮藍藻和葉面肥對水稻生育及產(chǎn)量品質(zhì)的影響[D].黑龍江八一農(nóng)墾大學,2020.

[593].鄭冉,黎瑞源,呂丹,鄭俊青,黃娟,石桃雄,陳慶富.苦蕎重組自交系群體籽粒性狀遺傳變異分析[J].安徽農(nóng)業(yè)大學學報,2020,47(05):818-825.

[594].鄭冉. 苦蕎重組自交系群體籽粒黃酮含量與農(nóng)藝性狀的QTL定位[D].貴州師范大學,2020.

[595].朱紅菊,趙勝杰,路緒強,何楠,劉文革.二倍體和四倍體西瓜幼苗根系形態(tài)差異比較[J].中國瓜菜,2020,33(11):18-21.

[596].朱麗霞,韓琰,陸鑾眉,張瓊,蔡月琴,陳清森.四種花灌木對鎘的耐性和富集特性研究[J].閩南師范大學學報(自然科學版),2020,33(01):74-80.

[597].朱麗霞,林逸涵,陸鑾眉,張瓊,蔡月琴,魯俊,韓欣剛.茉莉花對四種重金屬污染土壤的抗性和富集特性研究[J].福建熱作科技,2020,45(02):17-22.

[598].朱琳. 花生種子大小相關(guān)基因及其定位研究[D].山東師范大學,2020.

[599].朱秀茹,王永舟,蕭楚健,方瀟,周文滔,趙李,楊建偉,蘆芮冰,高聰.農(nóng)家旱稻品種特性的鑒定[J].金陵科技學院學報,2020,36(01):65-70.

[600].朱亞瓊,于輝,鄭偉,黎松松,娜爾克孜,劉岳含,郝帥,艾麗菲熱.燕麥+箭筈豌豆混播草地混播優(yōu)勢的測度與影響因素分析[J].草業(yè)學報,2020,29(01):74-85.

[601].鄒其珍. 四個水稻油菜素內(nèi)酯降解相關(guān)基因的功能研究[D].中國農(nóng)業(yè)科學院,2020.

[602].Ahong Wang, Qingqing Hou, Lizhen Si. et al. The PLATZ Transcription Factor GL6 Affects Grain Length and Number in Rice[J]Plant Physiology,2019.(SC-E,IF6.305)

[603].Cao, P., Liang, X., Zhao, H. et al. Identification of the quantitative trait loci controlling spike-related traits in hexaploid wheat (Triticum aestivum L.). Planta 250, 1967–1981 (2019). https://xs.scihub.ltd/https://doi.org/10.1007/s00425-019-03278-0.(SC-G,IF3.06)

[604].Chen, Z., Cheng, X., Chai, L. et al. Dissection of genetic factors underlying grain size and fine mapping of QTgw.cau-7D in common wheat (Triticum aestivum L.). Theor Appl Genet 133, 149–162 (2020). https://xs.scihub.ltd/https://doi.org/10.1007/s00122-019-03447-5. (SC-G,IF3.926)

[605].Christine J.Bergman. 9 - Rice end-use quality analysis[J]. Rice, 2019, Pages 273-337.(SC-E,IF3.513)

[606].CongqiZhang, RuiZhong, ZhongsuoWang. et al. Intra-annual variation of zooplankton community structure and dynamics in response to the changing strength of bio-manipulation with two planktivorous fishes[J].Ecological Indicators, Volume 101, June 2019, Pages 670-678.(AlgaeC,IF4.49)

[607].Dongzhi Wang, Kang Yu, Di Jin. et al. ALI-1, candidate gene of B1 locus, is associated with awn length and grain weight in common wheat[J]. 2019

[608].Dongzhi Wang, Kang Yu, Di Jin. et al. Natural variations in the promoter of Awn Length Inhibitor 1 (ALI‐1) are associated with awn elongation and grain length in common wheat[J].The Plant Journal,19 October 2019.(SC-G,IF5.726)

[609].Du, B., Wang, Q., Sun, G. et al. Mapping dynamic QTL dissects the genetic architecture of grain size and grain filling rate at different grain-filling stages in barley. Sci Rep 9, 18823 (2019). https://xs.scihub.ltd/https://doi.org/10.1038/s41598-019-53620-5.

[610].Fan Xu, Jiuyou Tang, Shaopei Gao. et al. Control of rice pre‐harvest sprouting by glutaredoxin‐mediated abscisic acid signaling[J].The Plant Journal, 22 August 2019.(SC-E,IF5.726)

[611].Fang, C., Li, L., He, R. et al. Identification of S23 causing both interspecific hybrid male sterility and environment-conditioned male sterility in rice. Rice 12, 10 (2019). https://xs.scihub.ltd/https://doi.org/10.1186/s12284-019-0271-4.(SC-E,IF3.513)

[612].Fengxian Zhen, Wei Wang, Haoyu Wang. et al. Effects of short-term heat stress at booting stage on rice-grain quality[J].Crop and Pasture Science 70(6) 486-498 https://doi.org/10.1071/CP18260.(SC-E,IF1.33)

[613].Gongduan Fan, Zhong Chen, Bo Wang. et al. Photocatalytic Removal of Harmful Algae in Natural Waters by AgAgCl@ZIF-8 Coating under Sunlight[J].Catalysts 2019, 9(8), 698; https://doi.org/10.3390/catal9080698.(AlgeaC,IF3.444)

[614].Guan, P., Di, N., Mu, Q. et al. Use of near-isogenic lines to precisely map and validate a major QTL for grain weight on chromosome 4AL in bread wheat (Triticum aestivum L.). Theor Appl Genet 132, 2367–2379 (2019). https://xs.scihub.ltd/https://doi.org/10.1007/s00122-019-03359-4.(SC-G, IF3.926)

[615].Hanyang Zhang, Jianhang Jiao & Hui Jin (2019) Degradable poly-L-lysinemodified PLGA cell microcarriers with excellent antibacterial and osteogenic activity, Artificial Cells, Nanomedicine, and Biotechnology, 47:1, 2391-2404, DOI: 10.1080/21691401.2019.1623230.(HiCC,IF4.462)

[616].Hao, H., Di, H., Jiao, X. et al. Fine roots benefit soil physical properties key to mitigate soil detachment capacity following the restoration of eroded land. Plant Soil 446, 487–501 (2020). https://xs.scihub.ltd/https://doi.org/10.1007/s11104-019-04353-x.(LA-S,IF3.259)

[617].He C, Ding Z, Mubeen S, Guo X, Fu H, Xin G. 2020. Evaluation of three wheat (Triticum aestivum L.) cultivars as sensitive Cd biomarkers during the seedling stage. PeerJ 8:e8478 https://doi.org/10.7717/peerj.8478.

[618].Jiajia Lia, Jinghui Zhaoa, Yinghui Li. et al. Identification of a novel seed size associated locus SW9-1 in soybean[J]. The Crop Journal, Volume 7, Issue 4, August 2019, Pages 548-559.(SC-G,IF3.179)

[619].Jiangzhe Zhao, Ningning Yu, Min Ju. et al. ABC transporter OsABCG18 controls the shootward transport of cytokinins and grain yield in rice[J]. Journal of Experimental Botany, Volume 70, Issue 21, 1 November 2019, Pages 6277–6291(SC-G,IF5.36)

[620].Jinshan Zhang, Zhenyu Zhou, Jinjuan Bai. et al. Disruption of MIR396e and MIR396f improves rice yield under nitrogen-deficient conditions[J]. National Science Review, nwz142, https://doi.org/10.1093/nsr/nwz142.(SC-A,IF13.222)

[621].Kang Chen, Yongtai Yin, Si Liu. et al. Genome-wide identification and functional analysis of oleosin genes in Brassica napus L.[J]. BMC Plant Biology (2019) 19:294.(SC-G,IF3.67)

[622].Kang Yu, Dongcheng Liu, Yong Chen. et al. Unraveling the genetic architecture of grain size in einkorn wheat through linkage and homology mapping and transcriptomic profiling[J]. Journal of Experimental Botany, Vol. 70, No. 18 pp. 4671–4687, 2019.(SC-G,IF5.36)

[623].Kashif HUSSAIN, ZHANG Yingxing, Workie ANLEY. et al. Association Mapping of Quantitative Trait Loci Increase Grain Size in An Introgression Line Derived by Oryza Ruffipogon Griff[J]. Rice Science, 2020.

[624].Ke‐Ke Sun, Wen‐Sheng, Yu Jia‐Jia Jiang. et al. Mismatches between the resources for adult herbivores and their offspring suggest invasive Spartina alterniflora is an ecological trap[J].Journal Of Ecology,04 September 2019 https://doi.org/10.1111/1365-2745.13277(LA-S,IF5.687)

[625].Lei Liu, Yubo Wang, Zhijia Gai. et al. Responses of Soil Microorganisms and Enzymatic Activities to Alkaline Stress in Sugar Beet Rhizosphere[J].Pol. J. Environ. Stud. Vol. 29, No. 1 (2020), 739-748(LA-S,IF1.186)

[626].LI Xiao-lan, LÜ Xiang, WANG Xiao-hong. et al. Biotic and abiotic stress-responsive genes are stimulated to resist drought stress in purple wheat[J]. Journal of Integrative Agriculture 2019, 18(0): 2–19.(SC-G,IF1.337)

[627].Meijuan Li, Jiaen Zhang, Shiwei Liu. et al. Mixed‐cropping systems of different rice cultivars have grain yield and quality advantages over mono‐cropping systems[J].Journal Of The Science Of Food And Agriculture, Volume99, Issue7 May 2019 Pages 3326-3334.(IF2.422)

[628].Meijuan Lia, Ronghua Lia, Shiwei Liu. et al. Rice-duck co-culture benefits grain 2-acetyl-1-pyrroline accumulation and quality and yield enhancement of fragrant rice[J].The Crop Journal,Volume 7, Issue 4, August 2019, Pages 419-430.(SC-E,IF3.179)

[629].Mengsi Kong, Qiao Qiao, Xiaolin Ma. et al. Isolation and functional analysis of the zmARM4 locus in a novel maize (Zea mays) grain‐filling mutant[J]. Plant Breeding,01 December 2019(SC-G,IF1.251)

[630].Mohammad AbubakarSiddika, JunZhanga, JinChen. et al. Responses of indica rice yield and quality to extreme high and low temperatures during the reproductive period[J].European Journal of Agronomy,Volume 106, May 2019, Pages 30-38.(SC-E,IF3.384)

[631].Pan, L., Lie, G., Xue, L. et al. Changes of Cinnamomum camphora root characteristics and soil properties under ozone stress in South China. Environ Sci Pollut Res 26, 30684–30692 (2019).(LA-S,IF2.914)

[632].Paul R. Armstrong, Anna M. McClung, Elizabeth B. Maghirang. et al. Detection of chalk in single kernels of long‐grain milled rice using imaging and visiblenear‐infrared instruments[J]. Cereal Chemistry,14 September 2019.(SC-G,IF1.289)

[633].Qiao-YunLi, Qiao-QiaoXu, Yu-MeiJiang. et al. The correlation between wheat black point and agronomic traits in the North China Plain[J].Crop Protection,Volume 119, May 2019, Pages 17-23(SC-G,IF2.172)

[634].Qifei Wang, Genlou Sun, Xifeng Ren. et al.Dissecting the Genetic Basis of Grain Size and Weight in Barley (Hordeum vulgare L.) by QTL and Comparative Genetic Analyses[J].Front. Plant Sci., 24 April 2019 | https://doi.org/10.3389/fpls.2019.00469.(SC-G,IF4.106)

[635].Ren, H., Wen, L., Guo, Y. et al. Expressional and Functional Verification of the Involvement of CmEXPA4 in Chrysanthemum Root Development. J Plant Growth Regul 38, 1375–1386 (2019). https://xs.scihub.ltd/https://doi.org/10.1007/s00344-019-09940-x.(LA-S,IF2.179)

[636].Ruixin Xu, Wei Hu, Yanchen Zhou. et al. Use of near-infrared spectroscopy for the rapid evaluation of soybean [Glycine max (L.) Merri.] water soluble protein content[J].Spectrochimica Acta Part A-Molecular And Biomolecular Spectroscopy,224(2020)(SC-G,IF2.931)

[637].Shi‐Xin Zhou, Yong Zhu, Liang‐Fang Wang. et al. Osa‐miR1873 fine‐tunes rice immunity against Magnaporthe oryzae and yield traits[J]. JIPB,21 December 2019.

[638].ShuhaoLia, YimanLia, XinruiHe. et al. Response of water balance and nitrogen assimilation in cucumber seedlings to CO2 enrichment and salt stress[J].Plant Physiology and Biochemistry, Volume 139, June 2019, Pages 256-263.(LA-S,IF3.404)

[639].Tiecheng Bai, Nannan Zhang, Benoit Mercatoris. et al. Improving Jujube Fruit Tree Yield Estimation at the Field Scale by Assimilating a Single Landsat Remotely-Sensed LAI into the WOFOST Model[J].Remote Sens. 2019, 11(9), 1119; https://doi.org/10.3390/rs11091119.(LA-S,IF4.118)

[640].Wang, W., Shen, J., Wang, C. et al. Safety and Feasibility of Helical I-125 Seed Implants Combined with Transcatheter Arterial Chemoembolization in Hepatocellular Carcinomas with Main Portal Vein Tumor Thrombus. Cardiovasc Intervent Radiol 42, 1420–1428 (2019). https://xs.scihub.ltd/https://doi.org/10.1007/s00270-019-02256-z.(IF1.928)

[641].Wencai, D., Fangfei, C., Qiang, F. et al. Effect of soybean roots and a plough pan on the movement of soil water along a profile during rain. Appl Water Sci 9, 138 (2019). https://xs.scihub.ltd/https://doi.org/10.1007/s13201-019-1025-6.

[642].Wu, J., Wang, L., Fu, J. et al. Resequencing of 683 common bean genotypes identifies yield component trait associations across a north–south cline. Nat Genet 52, 118–125 (2020). https://xs.scihub.ltd/https://doi.org/10.1038/s41588-019-0546-0.(SC-G,IF31.077)

[643].Xi, Y., Liu, H., Johnson, D. et al. Selenium enhances Conyza canadensis phytoremediation of polycyclic aromatic hydrocarbons in soil. J Soils Sediments 19, 2823–2835 (2019). https://xs.scihub.ltd/https://doi.org/10.1007/s11368-019-02274-x.(IF2.669)

[644].Xia Zhang, Junling Pang, Xuhui Ma. et al. Multivariate analyses of root phenotype and dynamic transcriptome underscore valuable root traits and water‐deficit responsive gene networks in maize[J]. Plant Direct,Volume3, Issue3 March 2019 e00130

[645].Xiaolan Li, Xiang Lv, Xiaohong Wang. et al. Effects of abiotic stress on anthocyanin accumulation and grain weight in purple wheat[J].Crop and Pasture Science 69(12) 1208-1214 https://doi.org/10.1071/CP18341(SC-G,IF1.33)

[646].XiaolongYang, BenfuWang, LiangChen. et al. The different influences of drought stress at the flowering stage on rice physiological traits, grain yield, and quality[J].Scientific reports,2019.(SC-E,IF4.011)

[647].Xiaoqian Wang, Luhao Dong, Junmei Hu. et al. Dissecting genetic loci affecting grain morphological traits to improve grain weight via nested association mapping[J].Theoretical and Applied Genetics (2019) 132:3115–3128.(SC-E,IF3.926)

[648].Xin, F., Zhu, T., Wei, S. et al. QTL Mapping of Kernel Traits and Validation of a Major QTL for Kernel Length-Width Ratio Using SNP and Bulked Segregant Analysis in Wheat. Sci Rep 10, 25 (2020). https://xs.scihub.ltd/https://doi.org/10.1038/s41598-019-56979-7.(SC-G,IF4.011)

[649].Xinyu Chen, Zepeng Yin, Yang Yin. et al. E?ects of Elevated Root-Zone CO2 on Root Morphology and Nitrogen Metabolism Revealed by Physiological and Transcriptome Analysis in Oriental Melon Seedling Roots[J].Int. J. Mol. Sci. 2020, 21(3), 803; https://doi.org/10.3390/ijms21030803

[650].Xiuying Gao, Jia-Qi Zhang, Xiaojun Zhang. et al. Rice qGL3OsPPKL1 Functions with the GSK3SHAGGY-Like Kinase OsGSK3 to Modulate Brassinosteroid Signaling[J]. The Plant Cell, May 2019. DOI: https://doi.org/10.1105/tpc.18.00836.(SC-E,IF8.631)

[651].XUE Pao, ZHANG Ying-xin, LOU Xiang-yang. et al. Mapping and genetic validation of a grain size QTL qGS7.1 in rice (Oryza sativa L.)[J].Journal of Integrative Agriculture 2019, 18(8): 1838–1850.(SC-G,IF1.337)

[652].Ya‐Fan Zhao, Ting Peng, Hong‐Zheng Sun. et al. miR1432‐OsACOT (Acyl‐CoA thioesterase) module determines grain yield via enhancing grain filling rate in rice[J].Plant Biotechnology Journal, 05 September 2018.(SC-G,IF6.84)

[653].Yang, L., Zhao, D., Meng, Z. et al. QTL mapping for grain yield-related traits in bread wheat via SNP-based selective genotyping. Theor Appl Genet (2019). https://xs.scihub.ltd/https://doi.org/10.1007/s00122-019-03511-0.(SC-G,IF3.996)

[654].Yanhong Song, Guangbin Luo, Lisha Shen. et al. TubZIP28, a novel bZIP family transcription factor from Triticum urartu, and TabZIP28, its homologue from Triticum aestivum, enhance starch synthesis in wheat[J]. The New Phytologist Trust,18 January 2020.

[655].Ying Xuan, Yang Yi, He Liang. et al. Effects of Meteorological Factors on the Yield and Quality of Special Rice in Different Periods after Anthesis[J].Agricultural Sciences, 2019, 10, 451-475.

[656].Yingying Liu, Xiaoli Wei , Zijing Zhou. et al. In?uence of Heterogeneous Karst Microhabitats on the Root Foraging Ability of Chinese Windmill Palm (Trachycarpus fortunei) Seedlings[J].Int. J. Environ. Res. Public Health 2020, 17(2), 434; https://doi.org/10.3390/ijerph17020434.

[657].YingyingYang, ShiwuGaoYa, chunSuZhaoliLin. et al. Transcripts and low nitrogen tolerance Regulatory and metabolic pathways in sugarcane under low nitrogen stress[J].Environmental and Experimental Botany,Volume 163, July 2019, Pages 97-111(LA-S,IF3.712)

[658].Yiwang Zhu, Yarong Lin, Songbiao Chen. et al. CRISPR/Cas9‐mediated functional recovery of the recessive rc allele to develop red rice[J].Plant Biotechnology Journal (2019) 17, pp. 2096–2105.(SC-E,IF6.84)

[659].Yongbo Hong, Qunen Liu, Yongrun Cao. et al. The OsMPK15 Negatively Regulates Magnaporthe oryza and Xoo Disease Resistance via SA and JA Signaling Pathway in Rice[J].Front. Plant Sci., 21 June 2019 | https://doi.org/10.3389/fpls.2019.00752. (SC-G,IF4.106)

[660].Yunhua Chia, Kimani Wilson, Zhiquan Liu. et al. Vacuolar invertase genes SbVIN1 and SbVIN2 are differently associated with stem and kernel traits in sorghum (Sorghum bicolor)[J].The Crop Journal, Available online 29 October 2019(SC-E,IF3.179)

[661].YuzhouHuang, XiXiao, CaicaiXu. et al. Seagrass beds acting as a trap of microplastics - Emerging hotspot in the coastal region[J].Environmental Pollution, Volume 257, February 2020, 113450(AlgaeC,IF5.714)

[662].Zhang, H., Zhou, L., Xu, H. et al. The qSAC3 locus from indica rice effectively increases amylose content under a variety of conditions. BMC Plant Biol 19, 275 (2019). https://xs.scihub.ltd/https://doi.org/10.1186/s12870-019-1860-5.(SC-G,IF3.67)

[663].Zhang, K., Nie, L., Cheng, Q. et al. Effective editing for lysophosphatidic acid acyltransferase 2/5 in allotetraploid rapeseed (Brassica napus L.) using CRISPR-Cas9 system. Biotechnol Biofuels 12, 225 (2019). https://doi.org/10.1186/s13068-019-1567-8.(SC-G,IF5.452)

[664].ZhiqiangGao, QunenLiu, YingxinZhang. et al. A proteomic approach identifies novel proteins and metabolites for lesion mimic formation and disease resistance enhancement in rice[J]. Plant Science, Volume 287, October 2019, 110182.(SC-G,IF3.785)

[665].Zhiyu Fenga, Zhongqi Qia, Dejie Du. et al. Characterization of a new hexaploid triticale 6D(6A) substitution line with increased grain weight and decreased spikelet number[J].The Crop Journal, Volume 7, Issue 5, October 2019, Pages 598-607.(SC-G,IF3.179)

[666].JIN Jian-chu, LI Xiao-xiang, LI Yong-chao, et al. Genetic Similarity Analysis of Hunan Rice Landraces with Same or Similar Name in Household and Genebank Conservations[J]. Agricultural Science ＆ Technology, 2018, 19(3): 9-20.

[667].Kashif Hussain.普通野生稻主效粒型QTL的遺傳剖析[D].北京:中國農(nóng)業(yè)科學院,2019

[668].Mohammad Abubakar Siddik.抽穗前后極端溫度對秈稻產(chǎn)量和品質(zhì)的影響及其機理[D].北京:中國農(nóng)業(yè)科學院,2019

[669].Sadaruddin Chachar.C3植物秈、粳水稻光合作用相關(guān)基因及其與DNA甲基化關(guān)系的研究[D].北京:中國農(nóng)業(yè)科學院,2019

[670].白磊.施氮量與密度對高油大豆光合生產(chǎn)及產(chǎn)質(zhì)量的影響[D].東北農(nóng)業(yè)大學,2019

[671].白云星,周運超.馬尾松人工林根系對近自然經(jīng)營措施的響應(yīng)[J].中南林業(yè)科技大學學報,第39卷第11期2019年11月

[672].曹立勇,程式華,洪永波等.OsMPK15基因、編碼蛋白和重組載體在水稻中的應(yīng)用:CN 110184286 A,2019.08.30

[673].曾新穎,郭建斌,趙姣姣等.花生籽仁大小相關(guān)性狀QTL定位[J].作物學報 ACTA AGRONOMICA SINICA 2019, 45(8): 1200?1207

[674].陳敬.長江上游雜交水稻親本遺傳多樣性及其品質(zhì)分析[D].西南科技大學,2019

[675].陳思,韓麗君.皂莢物候期初步研究[J].山西林業(yè)科技,第 48卷第3期,2019年9月

[676].陳總會,趙長臣,江小燕等.復合微生物菌劑對鯽魚生長及消化功能的影響[J].水產(chǎn)養(yǎng)殖,第40卷 第7期,2019年7月

[677].陳祖靜,高曉翠,周瑋等.不同施肥量對辣木幼苗生長、光合和養(yǎng)分特征的影響[J].林業(yè)與環(huán)境科學.2019 年 4 月第 35 卷第 2 期

[678].戴妙飛.ICARDA小麥種質(zhì)抗條銹資源篩選和抗病基因分析[D].西北農(nóng)林科技大學,2019

[679].單云鵬,陳新慧,萬平等.小豆種質(zhì)資源苗期抗旱性評價及抗旱資源篩選[J].植物遺傳資源學報,2019,20(5):1151-1159

[680].單云鵬.小豆種質(zhì)資源抗旱性篩選鑒定及相關(guān)基因關(guān)聯(lián)分析[D].北京農(nóng)學院,2019

[681].鄧嬌燕.1-甲基環(huán)丙烯(1-MCP)緩解黃瓜和辣椒高溫傷害的研究[D].北京:中國農(nóng)業(yè)科學院,2019

[682].段朋根,徐勁松,李云海.用于增加籽粒產(chǎn)量的方法:CN 110603264 A,2019.12.20

[683].段偉,王保平,喬杰等.水肥控制對楸葉泡桐苗期生長和生物量及其分配的影響[J].中南林業(yè)科技大學學報,第39卷第10期2019年10月

[684].范萍.一種減輕赤潮的可降解塑料袋及其制作方法:CN 110003593 A,2019.07.12

[685].范昱.中國苦蕎種質(zhì)資源性狀評價和蕎麥屬植物親緣關(guān)系分析[D].成都大學,2019

[686].奉寶兵,魏祥進,焦桂愛等.CRISPR/Cas9技術(shù)編輯淀粉合成基因PUL[J].中國稻米 2019,25(5):99-104

[687].符超.小麥籽粒缺陷型QTL定位和候選基因分析[D].北京:中國農(nóng)業(yè)科學院,2019

[688].付士朋,沈宏偉,王謙博等.刺五加種苗質(zhì)量分級標準及其方法的優(yōu)選[J].中國實驗方劑學雜志,第 25 卷第 17 期,2019 年 9 月

[689].高文碩.插秧密度對水稻生長發(fā)育及產(chǎn)量形成的影響[D].東北農(nóng)業(yè)大學,2019

[690].龔守賀,鄭應(yīng)龍,陶志英等.洪門水庫浮游生物的群落結(jié)構(gòu)特征[J].江西水產(chǎn)科技 2019 年第 4 期

[691].郭軍,李家前,李豪圣等.高大山羊草Pm13染色體片段對小麥農(nóng)藝和產(chǎn)量性狀的影響[J].麥類作物學報,2019,39(4):387-392

[692].郭軍,劉建軍,李豪圣等.一種快速檢測長穗偃麥草高產(chǎn)基因的分子:CN 109266779 A,2019.01.25

[693].郭軍盧明嬌,武智民等.1Ee染色體對小麥農(nóng)藝和品質(zhì)性狀的影響研究[J].植物遺傳資源學報 2019，20（4）：854-860

[694].賀翔翔.兩個甘藍型油菜遺傳作圖群體的重測序及QTL定位分析[D].華中農(nóng)業(yè)大學,2019

[695].賀鑫.不同磷水平下燕麥磷素營養(yǎng)及根系差異蛋白質(zhì)組學研究[D].內(nèi)蒙古農(nóng)業(yè)大學,2019

[696].胡丹丹.新型甘藍型油菜的群體改良和雜種優(yōu)勢分析[D].華中農(nóng)業(yè)大學,2019

[697].胡曉飛,趙建國,高利巖等.石墨烯對樹莓組培苗生長發(fā)育影響[J].新型碳材料,第34卷第5期2019年10月

[698].胡曉飛.石墨烯對樹莓生長的影響及其在防治植物枯萎病中的應(yīng)用[D].太原理工大學,2019

[699].扈戰(zhàn)強,黃建穎,方長云等.基于計算機視覺技術(shù)測定大米吸水膨脹及飽和時間的方法:CN 110596329 A,2019.12.20

[700].黃冰艷,齊飛艷 ,孫子淇等.以分子標記輔助連續(xù)回交快速提高花生品種油酸含量及對其后代農(nóng)藝性狀的評價[J].作物學報,2019, 45(4): 546−555,DOI: 10.3724/SP.J.1006.2019.84096

[701].黃思思.基于SNP的150份硬粒小麥43個性狀的關(guān)聯(lián)分析[D].華中農(nóng)業(yè)大學,2019

[702].焦灰敏,黨艷青,周小魏.蘋果砧木實生后代與親本之間相關(guān)性狀的研究[J].江蘇農(nóng)業(yè)科學 2019 年第 47 卷第 17 期

[703].荊瑞勇,王麗艷,鄭桂萍等.水稻萌發(fā)期和幼苗期耐鹽性鑒定指標篩選及綜合評價[J].黑龍江八一農(nóng)墾大學學報,第31卷第6期,2019年12月

[704].李發(fā)奎.黑果枸杞器官間生態(tài)化學計量特征比較研究[D].甘肅農(nóng)業(yè)大學,2019

[705].李洪果,陳達鎮(zhèn),勞慶祥等.基于表型性狀初步構(gòu)建格木核心種質(zhì)[J].分子植物育種，2019 年，第 17 卷，第 20 期，第 6881-6890頁

[706].李洪果,陳達鎮(zhèn),許靖詩等.瀕危植物格木天然種群的表型多樣性及變異[J].林業(yè)科學,第55卷第4期2019年4月,doi: 10．11707 / j．1001－7488．20190408

[707].李錦明.基于機器視覺的玉米考種技術(shù)研究[D].杭州:杭州電子科技大學,2019

[708].李倩,田雅楠,尚慶茂等.潮汐灌溉供液高度對番茄穴盤苗水分和氮素利用效率的影響[J].華北農(nóng)學報 ·2019 ，34 ( 6 ) : 126 -132

[709].李倩.番茄潮汐式育苗營養(yǎng)液細菌和真菌群落結(jié)構(gòu)動態(tài)分析[D].北京:中國農(nóng)業(yè)科學院,2019

[710].李盛婷,楊城,王冉等.草珊瑚植株表型對光照和氮素營養(yǎng)的響應(yīng)[J].植物營養(yǎng)與肥料學報 2019, 25(8): 1441–1450

[711].李濤,陸炳,李俊等.2個小麥株高QTL位點驗證及其對產(chǎn)量相關(guān)性狀的效應(yīng)分析[J].西南農(nóng)業(yè)學報,2019年32卷3期

[712].劉臣艷,王德爐.藍莓根系形態(tài)對不同肥種的響應(yīng)特征及模糊綜合評價[J].經(jīng)濟林研究,第37卷第3期2019年9月

[713].劉臣艷.藍莓根系對不同肥種的生態(tài)響應(yīng)研究[D].貴州大學,2019

[714].劉士玲,陳琳,楊保國等.氮磷肥對西南樺無性系生物量分配和根系形態(tài)的影響[J].南京 林 業(yè) 大 學 學 報 ( 自 然 科 學 版 )第 43 卷 第 5 期,2019 年 9 月

[715].劉士玲,賈宏炎,陳琳等.容器規(guī)格和添加生物炭的基質(zhì)配方對西南樺幼苗生長的影響[J].生態(tài)學雜志 Chinese Journal of Ecology 2019，38( 9) : 2875－2882

[716].劉小玲,張亨,陳文等.種植物生長調(diào)節(jié)劑對楝葉吳萸葉綠素熒光和根系生長的影響[J].林業(yè)與環(huán)境科學,第35卷第4期2019年8月

[717].劉鑫銘,陳婷,劉錫銘等.含氨基酸水溶性肥料對巨峰葡萄的影響[J].福建農(nóng)業(yè)學報 2019，３４（７）：７８２－７８９

[718].龍海,李濤,鄧光兵等.一種用于輔助檢測小麥高單穗小穗數(shù)性狀[J].CN 109811074 A,2019.05.28

[719].龍起樟,黃永蘭,唐秀英等.利用CRISPR_Cas9敲除OsNramp5基因創(chuàng)制低鎘秈稻[J].中國水稻科學(Chin J Rice Sci), 2019, 33(5): 407－420

[720].羅艷,屈洋,楊清華等.播期對糜子農(nóng)藝性狀及淀粉理化性質(zhì)的影響[J].中國農(nóng)業(yè)科學 2019,52(22):4154-4165

[721].牟立同,土壤鉆孔和果木屑腐熟物對蘋果樹生長及根區(qū)環(huán)境的影響[D].山東農(nóng)業(yè)大學,2019

[722].倪明理,任勃,陳燦等.稻魚(鰍)耦合對稻米品質(zhì)的影響[J].作物研究,2019,33(5):398-401

[723].彭緒冰,邱法展,龔佃明等.玉米百粒重及粒長性狀緊密連鎖的分子標記及應(yīng)用:CN 110106278 A,2019.08.09

[724].祁金玉,鄧繼峰,尹大川等.外生菌根菌對油松幼苗抗氧化酶活性及根系構(gòu)型的影響.生態(tài)學報,2019,39( 8) :2826-2832．

[725].卿冬進,劉開強,鄧國富等.基于PARMS技術(shù)的水稻粒形基因GW8分子標記的開發(fā)[J].西南農(nóng)業(yè)學報,2019年32卷3期

[726].任紅劍,柳斌,張沖等.山東地區(qū)茶用元寶楓品系的比較與篩選[J].山東林業(yè)科技 2019 年第 2 期

[727].石妮.長江重慶段四大家魚國家級水產(chǎn)種質(zhì)資源保護區(qū)魚類時空分布特征的研究[D].重慶師范大學,2019

[728].史鵬.NaCl脅迫對3種沙棘幼苗生長發(fā)育的影響[J].山 西 林 業(yè) 科 技,2019 年 3 月,第 48 卷 第 1 期

[729].蘇美玲.四種砧木對沃柑嫁接親和性和生長結(jié)果比較研究[D].廣西大學,2019

[730].唐鑫華,郭佳卓,張麗等.NaCl脅迫處理對馬鈴薯組培苗生理性狀和熒光參數(shù)的影響[J].馬鈴薯產(chǎn)業(yè)與健康消費,2019

[731].萬海霞,馬璠,許浩等.寧夏南部黃土丘陵區(qū)典型草本群落根系垂直分布特征與土壤團聚體的關(guān)系[J].水土保持研究,第26卷第6期,2019年12月

[732].王漢中,師家勤,李娜等.油菜BnbHLH60基因在提高油菜產(chǎn)量中的應(yīng)用:CN 106434740 B,2019.06.21

[733].王進賓.水稻異分支酸合成酶OsICS1在水楊酸合成途徑中的功能研究[D].浙江師范大學,2019

[734].王磊,申皓月,駱靈喜等.再論硅藻生長促進復合物對藍藻水華的控制作用[J].廣東化工,第46卷總第405期，2019年第19期

[735].王麗艷,唐金敏,鄭桂萍等.水稻萌發(fā)期和幼苗期耐低溫指標體系構(gòu)建及綜合評價[J].中國農(nóng)業(yè)科技導報，2019，21( 10) : 58－65

[736].王勝凡,王波,王磊等.益生藻生長促進劑及其制備方法和應(yīng)用:CN 109810903 A,2019.05.28

[737].王文慧.水稻千粒重QTLqTGW1.2a的解析與精細定位[D].北京:中國農(nóng)業(yè)科學院,2019

[738].王小波,關(guān)攀鋒,辛明明等.小麥種質(zhì)資源耐熱性評價[J].中國農(nóng)業(yè)科學,2019,52(23):4191-4200

[739].王曉琪,姚媛媛,劉之廣等.宛氏擬青霉提取物對鹽脅迫下水稻幼苗的生理適應(yīng)性[J].農(nóng)業(yè)資源與環(huán)境學報,2020,37（1）: 98-105

[740].韋如萍,胡德活,晏姝等.植物生長調(diào)節(jié)劑和基質(zhì)種類對杉木無性系瓶外生根組培苗質(zhì)量的影響[J].西南林業(yè)大學學報,第39卷第6期,2019 年11月

[741].魏珂.調(diào)控水稻淀粉代謝及糖轉(zhuǎn)運關(guān)鍵基因表達的效應(yīng)研究[D].揚州大學,2019

[742].魏其超,張海洋,劉文萍等.干旱脅迫下芝麻籽粒品質(zhì)及抗氧化能力變化分析[J].河南農(nóng)業(yè)科學，2019，48( 9) : 30-39

[743].魏其超.干旱處理對芝麻品質(zhì)和營養(yǎng)特性的影響研究[D].河南工業(yè)大學,2019

[744].吳敏,鄧平,趙英等.不同林齡紅錐人工林細根垂直分布和衰老生理特征[J].生態(tài)學雜志 Chinese Journal of Ecology 2019，38( 9) : 2622－2629

[745].吳少俊.基于計算機視覺的水稻葉綠素含量測定[J].農(nóng)機化研究,2020 年 4 月第 4 期

[746].伍曉明,閆貴欣,曾長立等.一種蛋白及其基因在控制植物種子性狀中的應(yīng)用:CN 110606878 A,2019.12.24

[747].伍曉明,閆貴欣,張美麗等.一種蛋白及其基因在控制粒重和/或含油量中的應(yīng)用:CN 110606879 A,2019.12.24

[748].伍曉明,閆貴欣,張美麗等.一種蛋白及其基因在控制植物性狀中的應(yīng)用:CN 110564735 A,2019.12.13

[749].謝嬌.普通小麥RIL群體籽粒性狀與穗部性狀相 關(guān)性分析及人工合成小麥RIL群體創(chuàng)建與初步分析[D].西北農(nóng)林科技大學,2019

[750].謝立紅,黃慶陽,曹宏杰等.五大連池火山色木槭葉功能性狀特征[J].生物多樣性,2019, 27 (3): 286–296

[751].辛芳.小麥籽粒形狀主效QTL定位分析[D].西北農(nóng)林科技大學,2019

[752].徐高偉.大壟膜上交錯雙行丹參移栽機關(guān)鍵部件研究及整機設(shè)計[D].東北農(nóng)業(yè)大學,2019

[753].徐志華,許 浩,李生寶.百里香群落根系特征研究[J].南方論壇,2019年6月上

[754].徐志華.黃土丘陵區(qū)主要草地群落根系特征研究[D].寧夏大學,2019

[755].薛亞榮,巴特爾·巴克.沙塵和遮陰復合脅迫對西梅葉片光合作用的影響[J].中國農(nóng)業(yè)氣象,2019,40(3):170-179

[756].鄢鵬,李國雷,冉紅達等.蘸根處理方式對彰武松造林成效的影響-以北京山區(qū)為例[J].水土保持通報,第39卷第5期2019年10月

[757].嚴青青,張巨松,徐海江等.鹽堿脅迫對海島棉幼苗生物量分配和根系形態(tài)的影響[J].生態(tài)學報,第39卷第20期2019年10月

[758].顏丹丹.小麥抗倒伏相關(guān)性狀的全基因組關(guān)聯(lián)分析[D].山東農(nóng)業(yè)大學,2019

[759].楊崇毅.大麥籽粒大小的全基因組關(guān)聯(lián)分析[D].浙江大學,2019

[760].楊光,梁坤南,黃桂華等.柚木無性系扦插育苗研究[J].中南林業(yè)科技大學學報,第39卷第10期2019年10月

[761].楊瀾,黃腐酸對平邑甜茶和八棱海棠耐鹽生理特性的影響[D].山東農(nóng)業(yè)大學,2019

[762].楊勇,陸彥,郭淑青等.秈稻背景下導入Wxin等位基因改良稻米食味和理化品質(zhì)[J].作物學報 ACTA AGRONOMICA SINICA 2019, 45(11): 1628?1637

[763].楊哲.棗實生與雜交后代群體主要性狀的遺傳變異分析[D].塔里木大學,2019

[764].葉李波,江麗偉,江春華等.日本花柏人工林生長過程及其模型研究[J].綠色科技,2019

[765].殷月輝,小麥-長穗偃麥草異染色體系篩選與鑒定[J].山 東 農(nóng) 業(yè) 科 學 2019，51( 4) : 1 ～ 6

[766].殷月輝.普通小麥中國春背景異染色體系的篩選與鑒定[D].山東農(nóng)業(yè)大學,2019

[767].游慧,向珣朝,楊博文等.重穗型變異材料爪哇稻22的生理性狀和遺傳特性[J].農(nóng) 業(yè) 生 物 技 術(shù) 學 報,2019, 27(6): 961~971

[768].游佳,谷晗,朱澤等.水稻粒質(zhì)量和粒形QTL定位及粒長位點qGL3.2的鑒定[J].南京農(nóng)業(yè)大學學報 2019，42( 4) : 612－621

[769].于瀟,盧鈺博,李希磊等.萊州灣浮游植物時空變化及其與環(huán)境因子的關(guān)系[J].煙臺大學學報( 自然科學與工程版),第33卷第1期,2020年1月

[770].余 明,蔡金桓,薛立等.樟樹(Cinnamomum)幼苗細根形態(tài)對氮磷添加和幼苗密度的響應(yīng)[J].生態(tài)學報,第39卷第20期2019年10月

[771].余佳雯.過表達OsDWF4和OsBZR1基因?qū)λ井a(chǎn)量和品質(zhì)的影響[D].揚州大學,2019

[772].張愛敏,周國順,付麗軍等.低溫脅迫下油菜素內(nèi)酯對黃瓜種子萌發(fā)及幼苗生長的影響[J].中國瓜菜,2019,32（12）：31-36

[773].張國慶,董麗麗,楊雨玲等.新安江流域水西河(黃山學院段)浮游植物群落結(jié)構(gòu)周年調(diào)查[J].黃山學院學報,第21卷第5期,2019年10月

[774].張宏娟,李玉瑩,苗麗麗等.小麥轉(zhuǎn)錄因子基因TaNAC67參與調(diào)控穗長和每穗小穗數(shù)[J].作物學報 ACTA AGRONOMICA SINICA 2019, 45(11): 1615?1627

[775].張宏娟.小麥TaNAC67基因抗逆分子機理及優(yōu)異單倍型發(fā)掘[D].甘肅農(nóng)業(yè)大學,2019

[776].張金汕.勻播和密度對小麥萌發(fā)及幼苗性狀的影響[J].中國農(nóng)學通報 2019.35(25):8-15

[777].張俊,劉 娟,臧秀旺等.麥秸覆蓋對土壤理化性質(zhì)及夏花生生長發(fā)育的影響[J].土壤通報,Vol . 50 , No . 3.Jun . , 2019

[778].張林,卞中,劉巧泉等.水稻粒長基因功能標記及其應(yīng)用:CN 110616277 A,2019.12.27

[779].張鵬,楊穎,奚如春等.油茶大規(guī)格容器苗質(zhì)量及其造林效果評價[J].經(jīng)濟林研究,Vol.37 No.1 Mar.2019

[780].張平,伍洪銘,張福鱗等.通過RNAi技術(shù)下調(diào)OsLOX提高水稻種子耐儲性[J].南京農(nóng)業(yè)大學學報 2019，42( 6) : 996－1005

[781].張勝忠,苗華榮,趙立波等.花生種子長寬比性狀遺傳分析和相關(guān)SSR標記篩選[J].花生學報2019,18(3):1-8

[782].張偉珍,段廷玉.AM真菌對箭筈豌豆響應(yīng)豌豆蚜取食的影響[J].草地學報,第27卷第6期,2019年11月

[783].張曉霞,楊會,張秀榮等.花生子仁長寬及單仁重的遺傳分析[J].山東農(nóng)業(yè)科學 2019，51( 9) : 73 ～ 78，86

[784].張新友,鄭崢,齊飛艷等.一種采用分生孢子接種鑒定花生網(wǎng)斑病抗病性的方法:CN 110100685 A,2019.08.09

[785].張玉娟.硬粒小麥灌漿特性及粒重與SNP標記的關(guān)聯(lián)分析[D].華中農(nóng)業(yè)大學,2019

[786].張鋆.綠豆開花結(jié)莢習性及籽粒形成過程中物質(zhì)積累研究[D].西北農(nóng)林科技大學,2019

[787].趙春華,崔法,張萌娜等.與小麥旗葉寬度主效QTL緊密連鎖的分子標記及應(yīng)用:CN 109913574 A,2019.06.21

[788].趙達.稻米品質(zhì)性狀的全基因組關(guān)聯(lián)分析及品質(zhì)相關(guān)基因的遺傳解析[D].華中農(nóng)業(yè)大學,2019

[789].趙思怡,陳菲,張鶴山等.51份紅三葉種質(zhì)資源萌發(fā)期耐銅性評價[J].種子,第３８卷　第４期?。玻埃保鼓辏丛?/div>