河南农业大学学报

参考文献

[1]张银杰，苗玉红，盛开，等.配施有机肥调控农田土壤磷素有效性研究进展[J].河南农业大学学报，2025, 59(2):189-198.ZHANG Y J, MIAO Y H, SHENG K, et al. Research progress on organic fertilizers application regulates phosphorus availability in farmland soil[J]. Journal of Henan Agricultural University, 2025,59(2):189-198.

[2]LAMBERS H. Phosphorus acquisition and utilization in plants[J]. Annual Review of Plant Biology, 2022, 73:17-42.

[3]贾瑞，贾睿琪，杜浩，等.施磷对苗期小麦镉吸收和根际特性的影响[J].河南农业大学学报，2025, 59(3):474-486.JIA R, JIA R Q, DU H, et al. Effect of phosphorus application on cadmium uptake and inter-root characteristics of seedling wheat[J]. Journal of Henan Agricultural University, 2025, 59(3):474-486.

[4]邵云，王岚，王鹏飞，等.不同前茬作物和施肥水平下麦田土壤不同形态无机磷含量及其对冬小麦磷累积量的贡献[J].河南师范大学学报（自然科学版），2025, 53(1):23-31.SHAO Y, WANG L, WANG P F, et al. Content of different fractions of soil inorganic phosphorus and their contributions to phosphorus accumulation in winter wheat with different previous crops and at different fertilizer levels[J]. Journal of Henan Normal University(Natural Science Edition), 2025, 53(1):23-31.

[5]LUO X Z, ELRYS A S, ZHANG L L, et al. The global fate of inorganic phosphorus fertilizers added to terrestrial ecosystems[J]. One Earth, 2024,7(8):1402-1413.

[6]吴薪，毕嘉榆，戈应同，等.间作促进磷吸收利用的研究进展[J].河南农业科学，2024, 53(12):1-9.WU X, BI J Y, GE Y T, et al. Research progress of intercropping promoting phosphorus absorption and utilization[J]. Journal of Henan Agricultural Sciences,2024, 53(12):1-9.

[7]LI C J, HOFFLAND E, KUYPER T W, et al. Syndromes of production in intercropping impact yield gains[J]. Nature Plants, 2020, 6(6):653-660.

[8]SAHOO U, MAITRA S, DEY S, et al. Unveiling the potential of maize-legume intercropping system for agricultural sustainability:a review[J]. Farming&Management, 2023, 8(1):1-13..

[9]HOMULLE Z, GEORGE T S, KARLEY A J. Root traits with team benefits:understanding belowground interactions in intercropping systems[J]. Plant and Soil, 2022, 471(1):1-26.

[10]LI C J, HOFFLAND E, VAN DER WERF W, et al.Complementarity and facilitation with respect to P acquisition do not drive overyielding by intercropping[J].Field Crops Research, 2021, 265:108127.

[11]WEN Z H, LI H B, SHEN Q, et al. Tradeoffs among root morphology, exudation and mycorrhizal symbioses for phosphorus-acquisition strategies of 16 crop species[J]. New Phytologist, 2019, 223(2):882-895.

[12]WU A J, FANG Y, LIU S, et al. Root morphology and rhizosheath acid phosphatase activity in legume and graminoid species respond differently to low phosphorus supply[J]. Rhizosphere, 2021, 19:100391.

[13]王琳萍，赖易文，周一帆，等.接种芽孢杆菌及其复合菌群对低磷胁迫下大豆生长及氮磷吸收的影响[J].南方农业学报，2025, 56(1):169-179.WANG L P, LAI Y W, ZHOU Y F, et al. Effects of inoculation with Bacillus strains and their synthetic microbial communities on the growth and nitrogen and phosphorus uptake of soybean under low phosphorus stress[J]. Journal of Southern Agriculture, 2025, 56(1):169-179.

[14]杨通黎，杨松花，王晶琴，等.不同大豆品种幼苗对低磷胁迫的生理响应及综合评价[J].南方农业学报，2024, 55(2):451-459.YANG T L, YANG S H, WANG J Q, et al. Physiological responses of different varieties of soybean to low phosphorus stress and comprehensive evaluation[J].Journal of Southern Agriculture, 2024,55(2):451-459.

[15]LI S M, LI L, ZHANG F S, et al. Acid phosphatase role in chickpea/maize intercropping[J]. Annals of Botany, 2004, 94(2):297-303.

[16]LIU X, RAHMAN T, SONG C, et al. Changes in light environment, morphology, growth and yield of soybean in maize-soybean intercropping systems[J]. Field Crops Research, 2017, 200:38-46.

[17]CHENG Y L, XU X, ZHANG Y, et al. Intercropping of Echinochloa frumentacea with leguminous forages improves hay yields, arbuscular mycorrhizal fungi diversity, and soil enzyme activities in saline-alkali soil[J].Agronomy, 2023, 13(9):2356.

[18]LIU B, XU W Y, NIU Y X, et al. TaTCP6 is required for efficient and balanced utilization of nitrate and phosphorus in wheat[J]. Nature Communications, 2025,16:1683.

[19]MESSAOUDI H, GÉRARD F, DOKUKIN P, et al.Effects of intercropping on field-scale phosphorus acquisition processes in a calcareous soil[J]. Plant and Soil,2020, 449(1):331-341.

[20]黄倩楠，王朝辉，黄婷苗，等.中国主要麦区农户小麦氮磷钾养分需求与产量的关系[J].中国农业科学，2018, 51(14):2719-2734.HUANG Q N, WANG C H, HUANG T M, et al. Relationships of N, P and K requirement to wheat grain yield of farmers in major wheat production regions of China[J].Scientia Agricultura Sinica, 2018,51(14):2719-2734.

[21]吴良泉.基于“大配方、小调整”的中国三大粮食作物区域配肥技术研究[D].北京：中国农业大学，2014.WU L Q. Study on regional fertilizer allocation technology of three major grain crops in China based on“big formula and small adjustment”[D]. Beijing:China Agricultural University, 2014.

[22]郜紫依，鲁剑巍，任涛，等.水稻百公斤籽粒养分吸收量及其影响因素整合分析[J].植物营养与肥料学报，2023, 29(9):1587-1596.GAO Z Y, LU J W, REN T, et al. Integrative analysis of nutrient uptakes for 100 kg-grain production of rice and the impact factors[J]. Journal of Plant Nutrition and Fertilizers, 2023, 29(9):1587-1596.

[23]刘景辉，朱建国，张永平，等.不同饲用高粱品种N、P、K吸收规律研究[J].耕作与栽培，2009,29(3):13-17.LIU J H, ZHU J G, ZHANG Y P, et al. Study on absorption law of N, P and K in different forage sorghum varieties[J]. Tillage and Cultivation, 2009, 29(3):13-17.

[24]宁强.高粱-油菜轮作养分需求规律与测土配方施肥技术研究[D].重庆：西南大学，2023.NING Q. Study on nutrient demand law of sorghum-rape rotation and soil testing and formula fertilization technology[D]. Chongqing:Southwest University, 2023.

[25]唐旭，陈义，吴春艳，等.大麦长期肥料效率和土壤养分平衡[J].作物学报，2013, 39(4):665-672.TANG X, CHEN Y, WU C Y, et al. Fertilizer efficiency and soil apparent nutrient balance for barley under long-term fertilization[J]. Acta Agronomica Sinica, 2013, 39(4):665-672.

[26]鲁泽刚，周龙，杨丽梅.不同施肥水平对大麦产量的影响及肥料效应[J].山东农业大学学报（自然科学版），2018, 49(5):744-749.LU Z G, ZHOU L, YANG L M. Effect of different fertilization levels on barley yield and fertilizer effect[J].Journal of Shandong Agricultural University(Natural Science Edition), 2018, 49(5):744-749.

[27]王仙，聂石辉，张金汕，等.氮磷钾肥配施对旱田大麦农艺性状和产量的影响[J].新疆农业科学，2017,54(11):2028-2035.WANG X, NIE S H, ZHANG J S, et al. Effects of combined application of nitrogen, phosphorus and potassium fertilizer on agronomic traits and yield of barley in dryland[J]. Xinjiang Agricultural Sciences, 2017, 54(11):2028-2035.

[28]刘晓杰.不同磷效率谷子在氮磷钾统筹施肥下农艺性状、产量及品质表现[D].太谷：山西农业大学，2022.LIU X J. Agronomic characters, yield and quality performance of millet with different phosphorus efficiency under integrated fertilization of nitrogen, phosphorus and potassium[D]. Taigu:Shanxi Agricultural University, 2022.

[29]王湛，李凯，王勇，等.基于“3414”试验的谷子氮磷钾施肥量研究[J].中国土壤与肥料，2025(3):76-83.WANG Z, LI K, WANG Y, et al. Studies on application rates of nitrogen, phosphorus and potassium fertilizer in foxtail millet cultivation based on“3414” fertilizer experiment[J]. Soil and Fertilizer Sciences in China, 2025(3):76-83.

[30]刘克礼，高聚林，王立刚.大豆对氮、磷、钾的平衡吸收动态的研究[J].中国油料作物学报，2004,26(1):51-54.LIU K L, GAO J L, WANG L G. Study on dynamic balance assimilation of N, P and K in soybean[J]. Chinese Journal of Oil Crop Sciences, 2004, 26(1):51-54.

[31]吕继龙，何萍，徐新朋，等.我国大豆最佳施肥量和种植密度评价[J].中国土壤与肥料，2020(6):174-180.LÜJ L, HE P, XU X P, et al. Assessment of the optimum fertilization rates and planting density for soybean production in China[J]. Soil and Fertilizer Sciences in China, 2020(6):174-180.

[32]索炎炎，张翔，司贤宗，等.增效磷肥对花生生长、产量和磷利用率的影响[J].中国油料作物学报，2020, 42(5):888-895.SUO Y Y, ZHANG X, SI X Z, et al. Effect of different synergistic phosphate fertilizer on growth, yield and phosphorus use efficiency of peanut[J]. Chinese Journal of Oil Crop Sciences, 2020, 42(5):888-895.

[33]武庆慧，汪洋，赵亚南，等.氮磷钾配比对潮土区高产夏播花生产量、养分吸收和经济效益的影响[J].中国土壤与肥料，2019(2):98-104.WU Q H, WANG Y, ZHAO Y N, et al. Effects of NPK ratio on yield, nutrient absorption and economic benefit of high-yielding summer peanut in a fluvo-aquic soil[J]. Soil and Fertilizer Sciences in China, 2019(2):98-104.

[34]王桂梅，邢宝龙，张旭丽，等.氮、磷、钾不同配比对绿豆产量的影响[J].作物杂志，2015(3):130-132.WANG G M, XING B L, ZHANG X L, et al. Effects of different ratios of nitrogen, phosphorus and potassium on mung bean production[J]. Crops, 2015(3):130-132.

[35]韩梅.不同肥料配比对蚕豆养分吸收分配规律和肥料利用率的影响[J].干旱地区农业研究，2017, 35(3):232-237.HAN M. Effect of different fertilizer application on the yield and fertilizer uptake and utilization of broad bean[J]. Agricultural Research in the Arid Areas, 2017, 35(3):232-237.

[36]高运青，李姝彤，尚启兵，等.施肥对蚕豆根瘤及产量的影响[J].作物杂志，2019(2):164-167.GAO Y Q, LI S T, SHANG Q B, et al. Nodules and yield of faba bean under different fertilizer treatments[J]. Crops, 2019(2):164-167.

[37]韩彦龙，晋凡生，郑普山，等.红芸豆养分限制因子及养分吸收、积累和分配特征研究[J].中国生态农业学报，2016, 24(7):902-909.HAN Y L, JIN F S, ZHENG P S, et al. Nutrient restrictive factors, nutrient absorption and accumulation of red kidney bean[J]. Chinese Journal of Eco-Agriculture,2016, 24(7):902-909.

[38]曾玲玲，崔秀辉，李清泉，等.氮磷钾配施对芸豆产量的效应研究[J].黑龙江农业科学，2013(2):39-43.ZENG L L, CUI X H, LI Q Q, et al. Study on the effects of application ratios of nitrogen, phosphorus and potassium on yield of kidney bean[J]. Heilongjiang Agricultural Sciences, 2013(2):39-43.

[39]范虹，殷文，柴强.间作优势的光合生理机制及其冠层微环境特征[J].中国生态农业学报（中英文），2022, 30(11):1750-1761.FAN H, YIN W, CHAI Q. Research progress on photophysiological mechanisms and characteristics of canopy microenvironment in the formation of intercropping advantages[J]. Chinese Journal of Eco-Agriculture,2022, 30(11):1750-1761.

[40]ZHANG W P, LI Z X, GAO S N, et al. Resistance vs.surrender:different responses of functional traits of soybean and peanut to intercropping with maize[J]. Field Crops Research, 2023, 291:108779.

[41]武晶，陈梦，汪直华，等.带状间作不同带间距对玉米光能利用的影响[J].中国农业科学，2023,56(23):4648-4659.WU J, CHEN M, WANG Z H, et al. Effect of different strip distances on light energy utilization in strip intercropping maize[J]. Scientia Agricultura Sinica, 2023,56(23):4648-4659.

[42]FENG L, SHI K, LIU X, et al. Optimizing trade-offs between light transmittance and intraspecific competition under varying crop layouts in a maize-soybean strip relay cropping system[J]. The Crop Journal, 2024,12(6):1780-1790.

[43]WANG L, ZHOU T, CHENG B, et al. Variable light condition improves root distribution shallowness and P uptake of soybean in maize/soybean relay strip intercropping system[J]. Plants, 2020, 9(9):1204.

[44]ZHOU T, WANG L, SUN X, et al. Improved postsilking light interception increases yield and P-use efficiency of maize in maize/soybean relay strip intercropping[J]. Field Crops Research, 2021, 262:108054.

[45]ROGERS E D, BENFEY P N. Regulation of plant root system architecture:implications for crop advancement[J]. Current Opinion in Biotechnology, 2015,32:93-98.

[46]LI L, SUN J H, ZHANG F S, et al. Root distribution and interactions between intercropped species[J].Oecologia, 2006, 147(2):280-290.

[47]YANG H, XU H S, ZHANG W P, et al. Overyielding is accounted for partly by plasticity and dissimilarity of crop root traits in maize/legume intercropping systems[J]. Functional Ecology, 2022, 36(9):2163-2175.

[48]MA H M, YU X Q, YU Q, et al. Maize/alfalfa intercropping enhances yield and phosphorus acquisition[J]. Field Crops Research, 2023, 303:109136.

[49]FANG S Q, GAO X, DENG Y, et al. Crop root behavior coordinates phosphorus status and neighbors:from field studies to three-dimensional in situ reconstruction of root system architecture[J]. Plant Physiology, 2011,155(3):1277-1285.

[50]柏文恋，张梦瑶，刘振洋，等.小麦与蚕豆间作体系根系形态与磷吸收的定量解析[J].应用生态学报，2021, 32(4):1317-1326.BAI W L, ZHANG M Y, LIU Z Y, et al. Quantitative analysis of root morphology and phosphorus absorption in wheat and faba bean intercropping system[J]. Chinese Journal of Applied Ecology, 2021, 32(4):1317-1326.

[51]WANG T Q, TIAN J H, LU X, et al. Soybean variety influences the advantages of nutrient uptake and yield in soybean/maize intercropping via regulating root-root interaction and rhizobacterial composition[J]. Journal of Integrative Agriculture, 2025, 24(10):4048-4062.

[52]SUN B R, GAO Y Z, WU X, et al. The relative contributions of pH, organic anions, and phosphatase to rhizosphere soil phosphorus mobilization and crop phosphorus uptake in maize/alfalfa polyculture[J]. Plant and Soil, 2020, 447(1):117-133.

[53]LO PRESTI E, BADAGLIACCA G, ROMEO M, et al.Does legume root exudation facilitate itself P uptake in intercropped wheat?[J]. Journal of Soil Science and Plant Nutrition, 2021, 21(4):3269-3283.

[54]ZHANG S, LI S M, MENG L B, et al. Root exudation under maize/soybean intercropping system mediates the arbuscular mycorrhizal fungi diversity and improves the plant growth[J]. Frontiers in Plant Science, 2024, 15:1375194.

[55]AN R, YU R P, XING Y, et al. Intercropping efficiently utilizes phosphorus resource in soil via different strategies mediated by crop traits and species combination[J]. Plant and Soil, 2024, 497(1):705-725.

[56]ZHOU Y, ZHU H H, FU S L, et al. Metagenomic evidence of stronger effect of stylo(legume)than bahiagrass(grass)on taxonomic and functional profiles of the soil microbial community[J]. Scientific Reports, 2017,7:10195.

[57]JIANG P, WANG Y Z, ZHANG Y P, et al. Intercropping enhances maize growth and nutrient uptake by driving the link between rhizosphere metabolites and microbiomes[J]. New Phytologist, 2024,243(4):1506-1521.

[58]ZHOU X G, ZHANG J Y, SHI J B, et al. Volatilemediated interspecific plant interaction promotes root colonization by beneficial bacteria via induced shifts in root exudation[J]. Microbiome, 2024, 12(1):207.

[59]LI Y F, RAN W, ZHANG R P, et al. Facilitated legume nodulation, phosphate uptake and nitrogen transfer by arbuscular inoculation in an upland rice and mung bean intercropping system[J]. Plant and Soil, 2009,315(1):285-296.

[60]马慧敏.施磷和玉米/紫花苜蓿间作提高盐碱化低磷土地产量和磷素吸收利用的根-土互作机理[D].长春：东北师范大学，2022.MA H M. The root-soil interaction mechanism of improved yield and phosphorus uptake and utilization under phosphorus application and maize/alfalfa intercropping in low P and saline-alkali soil[D]. Changchun:Northeast Normal University, 2022.

[61]ZHU S G, DUAN H X, TAO H Y, et al. Arbuscular mycorrhiza changes plant facilitation patterns and increases resource use efficiency in intercropped annual plants[J]. Applied Soil Ecology, 2023, 191:105030.

[62]WANG Y Z, JIANG P, LIAO C L, et al. Understanding the increased maize productivity of intercropping systems from interactive scenarios of plant roots and arbuscular mycorrhizal fungi[J]. Agriculture, Ecosystems&Environment, 2025, 381:109450.

[63]LIU Y L, MA C Y, LAKSHMANAN P, et al. Phosphorus solubilizing bacteria rather than arbuscular mycorrhizal fungi drive maize/faba bean intercropping advantages[J]. Plant and Soil, 2025, 511(1):753-766.

[64]ANDRINO A, GUGGENBERGER G, KERNCHEN S,et al. Production of organic acids by arbuscular mycorrhizal fungi and their contribution in the mobilization of phosphorus bound to iron oxides[J]. Frontiers in Plant Science, 2021, 12:661842.

[65]SONG C, SARPONG C K, ZHANG X F, et al. Mycorrhizosphere bacteria and plant-plant interactions facilitate maize P acquisition in an intercropping system[J].Journal of Cleaner Production, 2021, 314:127993.

[66]SINGH P K, SINGH M, TRIPATHI B N. Glomalin:an arbuscular mycorrhizal fungal soil protein[J]. Protoplasma, 2013, 250(3):663-669.

[67]LU M, ZHAO J X, LU Z R, et al. Maize-soybean intercropping increases soil nutrient availability and aggregate stability[J]. Plant and Soil, 2025,506(1):441-456.

[68]QIN L, JIANG H, TIAN J, et al. Rhizobia enhance acquisition of phosphorus from different sources by soybean plants[J]. Plant and Soil, 2011, 349(1):25-36.

[69]李姣姣，徐舟，梁翠月，等.不同磷浓度下结瘤对大豆生长及苹果酸合成和分泌的影响[J].大豆科学，2015, 34(4):643-647.LI J J, XU Z, LIANG C Y, et al. Effects of nodulation on soybean growth, malate synthesis and exudation in different phosphorus concentrations[J]. Soybean Science, 2015, 34(4):643-647.

[70]QIN X M, PAN H N, XIAO J X, et al. Increased nodular P level induced by intercropping stimulated nodulation in soybean under phosphorus deficiency[J]. Scientific Reports, 2022, 12:1991.

[71]ZHOU M, ZHU S N, MO X H, et al. Proteomic analysis dissects molecular mechanisms underlying plant responses to phosphorus deficiency[J]. Cells, 2022,11(4):651.

[72]路成成，蔡柏岩. AM真菌改善植物磷营养吸收和转运机制的研究进展[J].中国农学通报，2020,36(26):50-54.LU C C, CAI B Y. AM fungi improving the mechanism of phosphorus uptake and transport in plants:a review[J]. Chinese Agricultural Science Bulletin, 2020,36(26):50-54.

[73]刘云龙，钱浩宇，张鑫，等.丛枝菌根真菌对豆科作物生长和生物固氮及磷素吸收的影响[J].应用生态学报，2021, 32(5):1761-1767.LIU Y L, QIAN H Y, ZHANG X, et al. Impacts of arbuscular mycorrhizal fungi(AMF)on growth, N biofixation, and phosphorus uptake of legume crop[J].Chinese Journal of Applied Ecology, 2021, 32(5):1761-1767.

[74]YUAN K, ZHANG H, YU C J, et al. Low phosphorus promotes NSP1-NSP2 heterodimerization to enhance strigolactone biosynthesis and regulate shoot and root architecture in rice[J]. Molecular Plant, 2023,16(11):1811-1831.

[75]TAN X H, WANG D P, ZHANG X W, et al. A pair of LysM receptors mediates symbiosis and immunity discrimination in Marchantia[J]. Cell, 2025, 188(5):1330-1348.

[76]PARIES M, GUTJAHR C. The good, the bad, and the phosphate:regulation of beneficial and detrimental plant-microbe interactions by the plant phosphate status[J]. New Phytologist, 2023, 239(1):29-46.

[77]TIAN B L, PEI Y C, HUANG W, et al. Increasing flavonoid concentrations in root exudates enhance associations between arbuscular mycorrhizal fungi and an invasive plant[J]. The ISME Journal, 2021, 15(7):1919-1930.

[78]BENMRID B, GHOULAM C, ZEROUAL Y, et al. Bioinoculants as a means of increasing crop tolerance to drought and phosphorus deficiency in legume-cereal intercropping systems[J]. Communications Biology,2023, 6:1016.

[79]HAMDI W, L’TAIEF B, SOUID A, et al. Durum wheat-chickpea intercropping improves soil phosphorus status and biomass production under small soil inputs[J]. Journal of Soil Science and Plant Nutrition, 2024,24(1):1349-1361.

[80]顾嘉诚，王文敏，王振，等.玉米/大豆间作对根际土壤磷素生物有效性和微生物群落结构的影响[J].应用生态学报，2023, 34(11):3030-3038.GU J C, WANG W M, WANG Z, et al. Effects of maize and soybean intercropping on soil phosphorus bioavailability and microbial community structure in rhizosphere[J]. Chinese Journal of Applied Ecology, 2023,34(11):3030-3038.

[81]ZHANG B B, JIANG H D, ZHENG G T, et al. Genistein exudation drives spatial root allocation and heterogeneous microbial communities to enhance phosphorus acquisition in soybean-maize intercropping[J]. Plant,Cell&Environment, 2025, 48(10):7297-7312.

[82]JIANG P, WANG Y Z, ZHANG Y P, et al. Enhanced productivity of maize through intercropping is associated with community composition, core species, and network complexity of abundant microbiota in rhizosphere soil[J]. Geoderma, 2024, 442:116786.

[83]LO PRESTI E, KAVAMURA V N, ABADIE M, et al.Phosphorus availability drives the effect of legume-wheat intercropping on prokaryotic community interactions[J]. Applied Soil Ecology, 2024, 199:105414.

[84]ZHOU L, SU L Z, ZHAO H M, et al. Maize/soybean intercropping promoted activation of soil organic phosphorus fractions by enhancing more phosphatase activity in red soil under different phosphorus application rates[J]. Plant and Soil, 2025, 506(1):421-440.

[85]WANG W M, YIN F T, GU J C, et al. Effects of maize/soybean intercropping on rhizosphere soil phosphorus availability and functional genes involved in phosphorus cycling in Northwest China[J]. Plant and Soil, 2025,506(1):407-420.

[86]SONG C, WANG W J, GAN Y F, et al. Growth promotion ability of phosphate-solubilizing bacteria from the soybean rhizosphere under maize-soybean intercropping systems[J]. Journal of the Science of Food and Agriculture, 2022, 102(4):1430-1442.

[87]CAO D Y, LAN Y, SUN Q, et al. Maize straw and its biochar affect phosphorus distribution in soil aggregates and are beneficial for improving phosphorus availability along the soil profile[J]. European Journal of Soil Science, 2021, 72(5):2165-2179.

[88]LI X F, WANG Z G, BAO X G, et al. Long-term increased grain yield and soil fertility from intercropping[J]. Nature Sustainability, 2021, 4(11):943-950.

[89]GARLAND G, BÜNEMANN E K, OBERSON A, et al.Plant-mediated rhizospheric interactions in maizepigeon pea intercropping enhance soil aggregation and organic phosphorus storage[J]. Plant and Soil, 2017,415(1):37-55.

[90]TIAN X L, WANG C B, BAO X G, et al. Crop diversity facilitates soil aggregation in relation to soil microbial community composition driven by intercropping[J].Plant and Soil, 2019, 436(1):173-192.

[91]SU H, LAI H L, GAO F Y, et al. The proliferation of beneficial bacteria influences the soil C, N, and P cycling in the soybean-maize intercropping system[J].Environmental Science and Pollution Research, 2024,31(17):25688-25705.

[92]HAN Y, DONG Q Q, ZHANG K Z, et al. Maizepeanut rotational strip intercropping improves peanut growth and soil properties by optimizing microbial community diversity[J]. PeerJ, 2022, 10:e13777.

[93]ZOU X X, LIU Y, HUANG M M, et al. Rotational strip intercropping of maize and peanut enhances productivity by improving crop photosynthetic production and optimizing soil nutrients and bacterial communities[J]. Field Crops Research, 2023, 291:108770.

[94]BARGAZ A, NOYCE G L, FULTHORPE R, et al.Species interactions enhance root allocation, microbial diversity and P acquisition in intercropped wheat and soybean under P deficiency[J]. Applied Soil Ecology,2017, 120:179-188.

[95]TANG X M, ZHANG Y X, JIANG J, et al. Sugarcane/peanut intercropping system improves physicochemical properties by changing N and P cycling and organic matter turnover in root zone soil[J]. PeerJ, 2021, 9:e10880.

[96]SHI X L, ZHOU Y F, GUO P, et al. Peanut/sorghum intercropping drives specific variation in peanut rhizosphere soil properties and microbiomes under salt stress[J]. Land Degradation&Development, 2023, 34(3):736-750.

[97]MA H Y, ZHOU J, GE J Y, et al. Oat/soybean intercropping reshape the soil bacterial community for enhanced nutrient cycling[J]. Land Degradation&Development, 2024, 35(17):5200-5209.