教育及工作经历

2015年至今，533333巴黎人官方网站首页教授

2012年-2016年，西澳大利亚大学/悉尼大学副教授

2008年-2011年，西澳大利亚大学/美国农业部研究员

2002年-2007年，美国加州大学戴维斯分校/日本东京大学博士后

2001年，澳大利亚昆士兰大学植物生理生态博士

1991年，华南农业大学/加拿大McMaster/Guelph大学联培植物生理生化硕士

1982年，西南农业大学农学(土壤农业化学)学士

2020年至今，美国加州大学戴维斯分校兼职教授

2015年至今，澳大利亚西澳大利亚大学兼职教授

2022年至今，Frontiers in Plant Science (Frontiers) 领域编委

2020年至今，Journal of Agriculture and Food Research (Elsevier) 副主编

2019年至今，Plants (MDPI) 领域编委

2019年至今，Soil Research (CSIRO) 副主编

2007年至今，Plant and Soil (Springer Nature) 领域编委

代表性学术成果

一、中文/Chinese

（1） 王志超, 何新华. 2021. 基于植被覆盖度和遥感生态指数的成都市锦江区生态质量评估.《生态与农村环境学报》37(4): 492-500 (该刊2022年度10篇优秀论文之一).

（2) 王志超, 何新华. 2021. 基于改进型遥感生态距离指数的秀山县生态环境质量评估.《长江科学院院报》38(8): 54-59.

（3) 许晨阳, 蒲全明, 邱玉玲, 张跃强, 张虹, 段顺远,何新华. 2021. 养分专家系统推荐施肥提高梨果产量及品质.《植物营养与肥料学报》27(5): 849–857.

（4) 张璐, 何新华. 2020. C₃和C₄植物的氮素利用机制. 《植物学报》55 (2): 228-239.

（5） 温 苗, 施松梅, 罗协, 何新华, 徐云飞, 胥 晓. 2020. 不同树龄桑园丛枝菌根侵染、球囊霉素土层分布及与土壤因子的关系.《应用与环境生物学报》26(5): 1138-46.

（6） 施松梅, 高启国, 左同鸿, 蒲全明, 刘豫东, 刘贵喜, 朱利泉, 何新华. 2019. 甘蓝BoMLPKn1的克隆及其拟南芥同源基因AtAPK1b的功能研究.《园艺学报》46(11): 2164-2175.

（7） 辜夕容, 倪亚兰, 江亚男, 贾豪, 何新华. 2018. 接种双色蜡蘑对马尾松根际土壤无机磷和活性铝含量的影响. 《土壤学报》55(5): 1179-89.

（8） 何新华、段英华、陈应龙、徐明岗. 2012. 中国菌根研究60年: 过去、现在和将来.《中国科学》生命科学 42(6): 431-454.

（9） 张会民、徐明岗、张文菊、何新华. 2009. 长期施肥条件下土壤钾素固定影响因素分析. 《科学通报》54(17): 2574-80.

（10） Lambers H, 邱国玉, 何新华. 2010. 如何写好英文科学论文: 以使你的研究论文获取最优机会而被快速接受, 1-81页. 科学出版社, ISBN 978-7-03-028900-1, 5万字.

二、英文/English (https://orcid.org/0000-0002-5570-3454)

─ Ten Representative Journal Publications

1. Lie ZY, Zhou GY, Huang WJ, Kadowaki K, Tissue DT, Yan JH, Peñuelas J, Sardans J, Li YL, Liu ZH, Chu GW, Meng Z, He XH, Liu JX*. 2022. Warming drives sustained plant phosphorus demand in a humid tropical forest. Global Change Biology (https://doi.org/10.1111/gcb.16194).

2. Shi SM, Wen M, Dong XS, Sharifi S, Xie DT, He XH*. 2021. Variations in glomalin-related soil protein in Vicia faba rhizosphere depending upon interactions among mycorrhization, daytime and/or nighttime elevated CO₂ levels. Geoderma 404: 115283 (doi.org/10.1016/j.geoderma.2021.115283).

3. Gao JW, Wang F, Ranathunge K, Arruda A, Cawthray G, Clode P, He XH, Leopold M, Roessner U, Rupasinghe, T, Zhong HT, Lambers H*. 2020. Edaphic niche characterization of four Proteaceae reveals unique calcicole physiology linked to hyper-endemism of Grevillea thelemanniana. New Phytologist 228: 869-883 (doi: 10.1111/nph.16833).

4. Zhu JX, Hu HF, Tao SL, Chi XL, Li P, Jiang L, Ji CJ, Zhu JL, Tang ZY, Pan YD, Birdsey W, He XH, Fang JY*. 2017. Carbon stocks and changes of dead organic matter in China's forests. Nature Communications 8: 151 (doi:10.1038/s41467-017-00207-1).

5. Ai C, Liang GQ, Sun JW, Wang XB, He P, Zhou W*, He XH*. 2015. Reduced dependence of rhizosphere microbiome on plant-derived carbon in 32-year long-term inorganic & organic fertilized soils. Soil Biology & Biochemistry 80: 70-78 (http://dx.doi.org/10.1016/j.soilbio.2014.09.028).

6. Chen YP*, Wang KB, Lin YS, Shi WY, Song Y, He XH*. 2015. Balancing green and grain trade. Nature Geoscience 8: 739-41.

7. He XH*, Nara K. 2007. Element biofortification: Can mycorrhizas potentially offer a more effective and sustainable way to curb human malnutrition? Trends in Plant Science 12: 331-33.

8. Selosse M*, Richard F, He XH, Simard S. 2006. Mycorrhizal networks: des liaisons dangereuses? Trends in Ecology & Evolution 21: 621-28.

9. He XH*, Bledsoe CS, Zasoski RJ, Southworth D, Horwath WR. 2006. Rapid nitrogen transfer from ectomycorrhizal pines to adjacent ectomycorrhizal and arbuscular mycorrhizal plants in a California oak woodland. New Phytologist 170: 143-51.

10. He XH*, Critchley C, Ng H, Bledsoe CS. 2005. Nodulated N₂-fixing Casuarina cunninghamiana is the sink for net N transfer from non-N₂-fixing Eucalyptus maculata via an ectomycorrhizal fungus Pisolithus sp. supplied as NH₄NO₃. New Phytologist 167: 897-912
    

1. Gu X, Jia H, Wang X, Jiang Y, Li J, He XH. 2023. Differential aluminum tolerance and absorption characteristics in Pinus massoniana seedlings colonized with ectomycorrhizal fungi of Lactarius deliciosus and Pisolithus tinctorius. Journal of Forestry Research (doi.org/10.1007/s11676-022-01583-1).

2. Li ZS, Meng S, Qin FC, Wang SK, Liang JF, He XH, Lu JK. 2023. Host root exudates initiate a foraging preference by the root parasite Santalum album. Tree Physiology 43: 304-314 (doi.org/10.1093/treephys/tpac116).

3. Mkonda M, He XH. 2023. The influence of soil organic carbon and climate variability on crop yields in Kongwa District, Tanzania. Environmental Management 71: 170-178(https://doi.org/10.1007/s00267-022-01592-0).

4. Qiu ZJ, He XH, Yu HY, Zhu CW, Shen WS. 2023. Differential responses of soil bacterial communities to elevated CO₂ between strongly CO₂-responsive and weakly CO₂-responsive rice cultivars. Science of the Total Environment 869: 161843 (http://dx.doi.org/10.1016/j.scitotenv.2023.161843).

5. Yu GC, Chen J, Yu MX, Li AD, Wang YP, He XH, Tang XL, Liu H, Jiang J, Mo JM, Zhang S, Yan JH, Zheng MH. 2023. Eighteen-year nitrogen addition does not increase plant phosphorus demand in a nitrogen-saturated tropical forest. Journal of Ecology (Accepted).

6. Yu ZJ, He XH, Li ZT, Zhou SA, Guo DL, Pu H, Luo HY. 2023. Anammox bacterial abundance and diversity in different temperatures of purple paddy soils by ¹³C-DNA stable-isotope probing combined with high-throughput sequencing. Frontiers in Microbiology (doi.org/10.3389/fmicb.2023.1098681).

7. Li SP, Li Y, Feng X, Zhang JJ, He XH. 2022. A Bjerkandera adusta new strain as a potential biocontrol agent against wheat scab. International Microbiology 25: 831-838.

8. Lie ZY, Zhou GY, Huang WJ, Kadowaki K, Tissue DT, Yan JH, Peñuelas J, Sardans J, Li YL, Liu ZH, Chu GW, Meng Z, He XH, Liu JX. 2022. Warming drives sustained plant phosphorus demand in a humid tropical forest. Global Change Biology 28: 4085-96 (doi.org/10.1111/gcb.16194).

9. Qin C, Wright AL, Ma LH, He XH, Xie DT, Jian XJ. 2022. Improving nitrogen-use efficiency by using ridge tillage in rice paddy soils. Soil Use & Management 38: 528-536 (doi.org/10.1111/sum.12675).

10. Sharifi S, He XH, Dong XS, Shi SM, Obaid H, Baray SM, Nasrat NA, Khalili A. 2022. Splitting nitrogen fertilization improves growth, yield and profit of soybean (Glycine max) production in the semi-arid Afghanistan. Eurasian Journal of Soil Science 11: 33-42 (doi.org/10.18393/ejss.984060 OR CABI:20220408017).

11. Shi WY, Xu MG, He XH. 2022. Plant-microbe-soil interactions in a vulnerable ecosystem: promising re-vegetation approaches to slow down rocky karst desertification. Plant Soil 475: 1-4 (Editoral, doi.org/10.1007/s11104-022-05478-2).

12. Wang YH, Long Q, Li YY, Kang FR, Fan ZH, Xiong HY, Zhao HY, Luo YL, Guo R, He XH, Lakshmanan P, Shi XJ, Zhang FS, Zhang YQ. 2022. Mitigating magnesium deficiency for sustainable citrus production: A case study in Southwest China. Scientia Horticulturae 295: 110832 (doi.org/10.1016/j.scienta.2021.110832).

13. Xie J, Shi XJ, Zhang Y, Wan Y, Hu QJ, Zhang YQ, Wang J, He XH, Evgenia B. 2022. Carbon sequestration and reduced environmental contamination under a gradient of manure application. Soil & Tillage Research 220: 105386 (doi.org/10.1016/j.still.2022.105386).

14. Wang YL, Wang R, Liu B, Guerin‑Laguette A, He XH, Yu FQ. 2022. Non-host plants: are they mycorrhizal networks players? Plant Diversity 44: 127-134 (https://doi.org/10.1016/j.pld.2021.06.005) (2021年7月被中国科学院、科技日报‘前沿版’网站及中国主要新闻媒体择选简介,见http://www.cas.cn/syky/202107/t20210716_4798877.shtml.

15. Zhu XC, Ma MG, Tateno R,·He XH, Shi WY. 2022. Effects of vegetation restoration on soil carbon dynamics in Karst and non‑Karst regions in Southwest China: A synthesis of multi‑source data. Plant Soil 475: 45-60 (doi.org/10.1007/s11104-021-05220-4).

16. Fang LF, He XH, Zhang XL, Yang YH, Liu R, Shi SM, Shi XJ, Zhang YT. 2021. A small amount of nitrogen transfer from legume cover crop to citrus seedling via common arbuscular mycorrhizal networks. Agronomy 11: 32 (doi.org/10.3390/agronomy11010032).

17. Feng X, Li SP, Lu YF, Zhang JJ, Zhu YY, Yang HJ, He XH, Li Y. 2021. Bjerkandera adusta M1 inhibits the growth of Fusarium oxysporum f. sp. conglutinans and fusarium wilt incidence in Brassica napus L.. Journal of Plant Pathology 103: 483-491 (doi.org/10.1007/s42161-021-00753-0).

18. Gu XR, Jiang YN, Wang XH, Jia H, Li J, Cui Y, Hu J, Mao QZ, He XH. 2021. Differences in aluminum tolerance and immobilization between two indigenous ectomycorrhizal fungi Lactarius deliciosus and Pisolithus tinctorius from Southwest China’s forest stands. Ecotoxicology and Environmental Safety 213: 112042 (doi.org/10.1016/j.ecoenv.2021.112042).

19. Jeewani PH, Luo Y, Yu GH, Fu YY, He XH, Zwieten L, Liang C, Kumar A, He Y, Kuzyakov Y, Qin H, Guggenberger G, Xu JM. 2021. Arbuscular mycorrhizal fungi and goethite promote carbon sequestration via hyphal-aggregate mineral interactions. Soil Biology & Biochemistry 162: 108417 (https://doi.org/10.1016/j.soilbio.2021.108417).

20. Luo X, Shi SM, Liu YN, Yang HJ, Li NN, Dong ZX, Zhu B, He XH. 2021. Arbuscular mycorrhizal fungal communities differentiate in subsoil and topsoil during an annual intensively managed maize-wheat rotation after 15-year long-term NPK based fertilization. Agriculture, Ecosystems & Environment 315: 107442 (doi.org/10.1016/j.agee.2021.107442).

21. Schnepf A, He XH. 2021. Rhizosphere 5 - shining light on the world beneath our feet. Plant & Soil 461: 1-4 (Editoral, doi.org/10.1007/s11104-021-04942-9).

22. Shi SM, Luo X, Dong XS, Qiu YL, Xu CY, He XH. 2021. Arbuscular mycorrhizatione enhances nitrogen, phosphorus and potassium accumulation in Vicia faba by modulating soil nutrient balance under elevated CO₂. Journal of Fungi 7: 361 (doi.org/10.3390/jof7050361, Editor’s Choice Article in its July issue, 被选为该期刊2021年第7期编辑部介绍文章(每期1~2篇)；该期刊每年12期，每期 ~80篇文章).

23. Shi SM, Luo X, Wen M, Dong XS, Sharifi S, Xie DT, He XH. 2021. Funneliformis mosseae improves growth and nutrient accumulation in wheat by facilitating soil nutrient uptake under elevated CO₂ at daytime, not nighttime. Journal of Fungi 7: 458 (doi.org/10.3390/jof7060458).

24. Shi SM, Qiu YL, Wen M, Xu X, Dong XS, Xu CY, He XH. 2021. Daytime, not nighttime, elevated atmospheric CO₂ exposure improves plant growth and leaf quality of mulberry (Morus alba L.) seedlings. Frontiers in Plant Science 11: 609031 (doi: 10.3389/fpls.2020.609031, 2021年5月被美国Science and Environmental Policy Project (SEPP) 评价为: Valuable to nursery owners for time-of-day elevation of CO₂,见https://climate-science.press/2021/05/17/weekly-climate-and-energy-news-roundup-455/ 和被美国CO₂科学组织网站选登, 见http://www.co2science.org/articles/V24/may/a3.php. 同时，被英国著名科普期刊“Research Outreach”2021年第9期以“Nutrient management strategies for sustainable mulberry plantations”为题择选为亮点研究成果介绍；该期刊每年12期，全球每年介绍~300篇文章.).

25. Shi SM, Wen M, Dong XS, Sharifi S, Xie DT, He XH. 2021. Variations in glomalin-related soil protein in Vicia faba rhizosphere depending upon interactions among mycorrhization, daytime and/or nighttime elevated CO₂ levels. Geoderma 404: 115283 (doi.org/10.1016/j.geoderma.2021.115283).

26. Shi SM, Xu X, Dong XS, Xu CY, Qiu YL, He XH. 2021. Photosynthetic acclimation and growth responses to elevated CO₂ associate with leaf nitrogen and phosphorus concentrations in mulberry (Morus multicaulis Perr.). Forests 12: 660 (doi.org/10.3390/f12060660, 被英国著名科普期刊“Research Outreach”2021年第9期以“Nutrient management strategies for sustainable mulberry plantations”为题择选为亮点研究成果介绍；该期刊每年12期，全球每年介绍~300篇文章).

27. Wang YL, He XH, Yu FQ. 2021. Mycorrhization of Quercus mongolica seedlings by Tuber melanosporum alters root carbon exudation and rhizosphere bacterial communities. Plant Soil 467: 391-403 (https://doi.org/10.1007/s11104-021-05112-7) (2021年9月被中国科学院、科学网网站等媒体择选简介,见http://www.cas.cn/cm/202109/t20210901_4804112.shtml, http://news.sciencenet.cn/htmlnews/2021/8/463653.shtm等).

28. Gao JW, Wang F, Ranathunge K, Arruda A, Cawthray G, Clode P, He XH, Leopold M, Roessner U, Rupasinghe, T, Zhong HT, Lambers H. 2020. Edaphic niche characterization of four Proteaceae reveals unique calcicole physiology linked to hyper-endemism of Grevillea thelemanniana. New Phytologist 228: 869-883 (Cover photo, doi: 10.1111/nph.16833, currently referenced in a Facebook page).

29. Gu XR, Wang XH, Jie Li J, He XH. 2020. Laccaria bicolor mobilizes both labile aluminum and inorganic phosphate in rhizosphere soil of pinus massoniana seedlings field grown in a yellow acidic soil. Applied & Environmental Microbiology 86: e03015-19 (doi:10.1128/AEM.03015-19).

30. Lu JK, Li ZS, Yang FC, Wang SK, Liang JF, He XH. 2020. Concurrent carbon and nitrogen transfer between hemiparasite Santalum album and two N₂-fixing hosts in a sandalwood plantation. Forest Ecology & Management 464: 118060 (doi:10.1016/j.foreco.2020.118060).

31. Shen H, Yan WH, Yang XY, He XH, Wang X, Zhang YT, Wang B, Xia QY. 2020. Co-occurrence network analyses of rhizosphere soil microbic PFLAs and soil metabolites over continuous cropping seasons in tobacco. Plant & Soil 452: 119-135 (doi.org/10.1007/s11104-020-04560-x).

32. Wang F, Gao JW, Yong JWH, Liu YF, Cao D, He XH. 2020. Glutamate over-accumulation may serve as an endogenous indicator of tricarboxylic acid (TCA) cycle suppression under NH₄⁺ nutrition in wheat (Triticum aestivum L.) seedlings. Environmental & Experimental Botany 177: 104130 (doi.org/10.1016/j.envexpbot.2020.104130).

33. Wang F, Gao JW, Yong JWH, Wang Q, Ma JW, He XH. 2020. Higher atmospheric CO₂ levels favour C₃ plants over C₄ plants in utilizing ammonium. Frontiers in Plant Science 11: 537443 (doi: 10.3389/fpls.2020.537443).

34. Wang J, Zhang LH, He XH, Zhang YQ, Wang Y, Duan SY, Xu CY, Mao XY, Chen XP, Shi XJ. 2020. Environmental mitigation potential by improved nutrient managements in pear (Pyrus pyrifolia L.) orchards based on life cycle assessment: A case study in the North China Plain. Journal of Cleaner Production 262: 121273 (doi.org/10.1016/j.jclepro.2020.121273).

35. Zhao ML, Jiang CS, Zhao ZJ, Shi XJ, He XH, Hao QJ. 2020. Variations in nitrous oxide emissions as manipulated by plastic film mulching and fertilization over three successive years in a hot pepper-radish rotated vegetable production system. Agriculture, Ecosystems & Environment 304: 107127 (doi.org/10.1016/j.agee.2020.107127).

36. Yu GH, Sun FS, Liu Y, He XH, Polizzotto ML. 2020. Influence of biodiversity and iron availability on soil peroxide: Implications for soil carbon stabilization and storage. Land Degradation & Development 31: 463–472 (doi: 10.1002/ldr.3463, currently referenced in 1 Wikipedia page).

37. Ge TD, Luo Y, He XH. 2019. Quantitative and mechanistic insights into the key process in the rhizodeposited carbon stabilization, transformation and utilization of carbon, nitrogen and phosphorus in paddy soil. Plant & Soil 445: 1-5 (Editoral, https://doi.org/10.1007/s11104-019-04347-9).

38. Gu XR, Wang XH, Li J, He XH. 2019. Accumulation and translocation of phosphorus, calcium, magnesium, and aluminum in Pinus massoniana lamb. seedlings inoculated with three Laccaria bicolor isolates growing in an acidic yellow soil. Forests 10: 1153 (doi:10.3390/f10121153).

39. Luo X, He XH, Luo XM, Liu YN, Wang JQ, Dong JY. 2019. Soil organic carbon shapes AMF communities in soils and roots of Cynodon dactylon under anti-seasonal drying-wetting cycles. Diversity 11: 197, doi:10.3390/d11100197.

40. Wang F, Gao JW, Shi SM, He XH, Dai TB. 2019. Impaired electron transfer accounts for the photosynthesis inhibition in wheat seedlings (Triticum aestivum L.) subjected to ammonium stress. Physiologia Plantarum 167: 159-172 (2019年10月被该刊编辑部择选漫画配图向社会媒体推介, Journal’s Choice Paper with Cartoon Introductions to the Social Network Media in its October issue).

41. Wang KB, Shi WY, Chen YP, He XH. 2019. Effects of grassland afforestation on structure and function of soil bacterial and fungal communities. Science of the Total Environment 676: 396-406 (2019年4月被美国Microbiome Digest网站选录, 见https://microbiomedigest.com/2019/04/29/april-29-2019/, and referred in a 2020 Food and Agriculture Organization of the United Nations’ Policy Document: State of Knowledge of Soil Biodiversity - Status, Challenges and Potentialities).

42. Mkonda MY, He XH. 2018. Climate variability and crop yields synergies in Tanzania’s semiarid agroecological zone. Ecosystem Health and Sustainability 4: 59-72.

43. Mkonda MY, He XH, Festin ES. 2018. Comparing smallholder farmers’ perception of climate change with meteorological data: Experience from seven agroecological zones of Tanzania. Weather, Climate, and Society 10: 435-452 (2018年3-4月被美国Skeptical Science网站选录, 见https://skepticalscience.com/news.php?n=4079 and currently also referenced in 1 Facebook page).

44. Zhang H, Mkonda MY, He XH. 2018. Conservation agriculture for environmental sustainability in a semiarid agroecological zone under climate change scenarios. Sustainability 10: 1430.

45. He JD, Dong TF, Huang KC, Yang YX, Li DD, Xu X, He XH. 2017. Sex-specific floral morphology, biomass, and phytohormones associated with altitude in dioecious Populus cathayana populations. Ecology and Evolution 7: 1-11. DOI: 10.1002/ece3.2808.

46. Mkonda MY, He XH. 2017. Yields of the major food crops: Implications to food security and policy in tanzania’s semi-arid agro-ecological zone. Sustainability 9: 1490.

47. Zhang YT, Shen H, He XH, Thomas BW, Lupwayi NZ, Hao X, Thomas MC, Shi XJ. 2017. Fertilization shapes bacterial community structure by alteration of soil pH. Frontier in Microbiology 8: 1325.

48. Zhu JX, Hu HF, Tao SL, Chi XL, Li P, Jiang L, Ji CJ, Zhu JL, Tang ZY, Pan YD, Birdsey W, He XH, Fang JY. 2017. Carbon stocks and changes of dead organic matter in China's forests. Nature Communications 8: 151. DOI: 10.1038/s41467-017-00207-1.

49. Fang YY, Singh P, Badgery W, He XH. 2016. In situ assessment of new carbon and nitrogen assimilation and allocation in contrastingly managed dryland wheat crop–soil systems. Agriculture, Ecosystems and Environment 235: 80-90.

50. He XH, Du ZL, Wang YD, Lu N, Zhang QZ. 2016. Sensitivity of soil respiration to soil temperature decreased under deep biochar amended soils in temperate croplands. Applied Soil Ecology 108: 204-210.

51. Shen H, He XH, Liu Y, Chen Y, Tang J, Guo T. 2016. A complex inoculant of N₂-fixing, P- and K-solubilizing bacteria from a purple soil improves the growth of kiwifruit (Actinidia chinensis) plantlets. Frontier in Microbiology 7: 841.

52. Shi SM, Chen K, Gao Y, Liu B, Yang X-H, Huang XZ, Liu GX, Zhu LQ, He XH. 2016. Arbuscular mycorrhizal fungus species dependency governs better plant physiological characteristics and leaf quality of mulberry (Morus alba L.) seedlings. Frontier in Microbiology 7: 1030 (2018年6月荣获第七届“梁希青年论文奖”三等奖).

53. Wang YH, Zou CQ, Mirza Z, Li H, Zhang ZZ, Li DP, Xu CL, Shi XJ, Xie DT, He XH, Zhang YQ. 2016. Cost of agronomic biofortification of wheat with zinc in China. Agronomy for Sustainable Development 36: 44 (2016年9月被法国国家农业研究院博客网站择选配图简介, 见https://ist.blogs.inrae.fr/agronomy/2016/09/26/zinc-spraying-on-wheat-is-cheaper-with-pesticides/).

54. Zhu ZK, Ge TD, Hu YJ, Tong CL, Shibistova, He XH, Wang J, Guggenberger G, Wu JS. 2016. Fate of rice shoot and root residues, rhizodeposits, and microbe-assimilated carbon in paddy soil – Part 1: Decomposition and priming effect. Biogeosciences 13: 1-9 (2016年8月被中国科学院网站择选简介,见http://www.cas.cn/syky/201608/t20160812_4571042.shtml).

55. Ai C, Liang GQ, Sun JW, Wang XB, He P, Zhou W. He XH, 2015. Reduced dependence of rhizosphere microbiome on plant-derived carbon in 32-year long-term inorganic and organic fertilized soils. Soil Biology & Biochemistry 80: 70-78.

56. Cai ZJ, Wang BR, Xu MG, Zhang HM, He XH, Zhang L, Gao SD. 2015. Intensified soil acidification from chemical N fertilization and prevention by manure in an 18-year field experiment in the red soil of southern China. Journal of Soils & Sediments 15: 260-70 (Referred in a 2021 Food and Agriculture Organization of the United Nations’ Policy Document: Recarbonizing Global Soils: A Technical Manual of Recommended Sustainable Soil Management).

57. Chen YP, Wang KB, Lin YS, Shi WY, Song Y, He XH. 2015. Balancing green and grain trade. Nature Geoscience 8: 739-741 (2015年9月被中国科学院网站、科学网网站及中国主要新闻媒体择选简介,见http://www.cas.cn/cm/201509/t20150909_4422098.shtml, http://news.sciencenet.cn/htmlnews/2015/9/326564.shtm等).

58. Hu FN, Xu CY, Li H, Li S, Yu ZH, Li Y, He XH. 2015. Particles interaction forces and their effects on soil aggregates breakdown. Soil & Tillage Research 147: 1-9 (被欧洲地球科学联合会博客网站择选为2015年“Soil & Tillage Research”期刊引用最多的30篇文章之一, 见https://blogs.egu.eu/divisions/sss/2016/08/06/top-30-papers-in-the-top-10-journals-of-the-soil-sciences-category-vii-soil-tillage-research/).

59. Wu HT, Lu MZ, Lu XG, Guan Q, He XH. 2015. Interactions between earthworm and mesofauna has no significant effect on emissions of CO₂ and N₂O from soil. Soil Biology & Biochemistry 88: 294-97.

60. Duan YH, Shi XJ, Li SL, Sun XF, He XH. 2014. Long-term phosphorus addition on top of nitrogen improves nitrogen use efficiency of both wheat and rice but further potassium addition only improves wheat nitrogen use efficiency in rice-wheat rotations. Journal of Integrative Agriculture 13: 588-596 (Currently referenced in a Facebook page).

61. Song YY, Ye M, Li CY, He XH, Zhu-Salzman KY, Wang RL, Su YJ, Luo SM, Zeng RS. 2014. Hijacking common mycorrhizal networks for herbivore-induced defence signal transfer between tomato plants. Scientific Reports 4: 3915 (2017年10月被美国“科学美国人”网站择选配图配视频简介, 见https://blogs.scientificamerican.com/artful-amoeba/parasite-can-pass-warnings-between-co-joined-hosts/).

62. Lu JK, Xu DP, Kang LH, He XH. 2014. Host-species dependent physiological characteristics of hemiparasite Santalum album L. in association with N₂-fixing and non-N₂-fixing hosts native to southern China. Tree Physiology 34: 1006-17.

63. Wen YL, Li H, Xiao JA, Wang C, Shen QR, Ran W, He XH, Zhou GS, Yu GH. 2014. Insights into complexation of dissolved organic matter and Al(III) and nanominerals formation in soils under contrasting fertilizations using two-dimensional correlation spectroscopy and high resolution-transmission electron microscopy techniques. Chemosphere 111: 441-449 (Introduced by www.ecosmagazine.com/?paper=EC14220, etc.).

64. Lu JK, Kang LH, Sprent JI, Xu DP, He XH. 2013. Two-way transfer of nitrogen between Dalbergia odorifera and its hemiparasite Santalum album is enhanced when the host is effectively nodulated and fixing nitrogen. Tree Physiology 33: 464-474 (Currently referenced in a Facebook page).

65. Zhang HJ, Ding WX, Yu HY, He XH. 2013. Carbon uptake by a microbial community during 30-day treatment with ¹³C-glucose of a sandy loam soil fertilized for 20 years with NPK or compost as determined by a GC-C-IRMS analysis of phospholipid fatty acids. Soil Biology & Biochemistry 57: 228-236.

66. Acuna TLB, He XH, Wade LJ. 2012. Temporal variation in root penetration ability of wheat genotypes through thin wax layers in contrasting water regimes and in the field. Field Crops Research 138: 1-10.

67. Duan YH, Xu MG, He XH, Li SL, Sun XF. 2011. Long-term pig manure application reduces the requirement for chemical phosphorus and potassium in two rice-wheat sites in subtropical China. Soil Use & Management 27: 427-436 (One of the selected 20 out of ~100 papers authored by Chinese soil scientists (1998-2012) in European Journal of Soil Science and Soil Use & Management [Chinese Soil Science: An Important Growing Contribution of International Relevance, see http://onlinelibrary.wiley.com/journal/10.1111/(ISSN)1365-2389/homepage/custom_copy.htm).

68. Shen WS, Lin XG, Gao N, Shi WM, Min J, He XH. 2011. Nitrogen fertilization changes abundance and community composition of ammonia-oxidizing bacteria. Soil Science Society of America Journal 75: 2198-205.

69. He XH, Duan YH, Chen YL, Xu MG. 2010. A 60-year journey of mycorrhizal research in China: Past, present and future. Science China-Life Sciences 53: 1374-98 (被美国VerticalNews China专栏选介, see http://www.verticalnews.com/newsletters/China-Weekly-News/2011-01-25/1454TI.html).

70. Shen WS, Lin XG, Shi WM, Min J, Gao N, He XH. 2010. High rates of nitrogen fertilization decrease soil enzyme activities, microbial functional diversity and nitrification capacity in a Chinese polytunnel greenhouse vegetable land. Plant & Soil 337: 137-50 (Referred in a 2018 Food and Agriculture Organization of the United Nations’ Policy Document: Soil Pollution: A Hidden Reality).

71. He XH, Xu MG, Qiu GY, Zhou JB. 2009. Use of ¹⁵N stable isotope to quantify nitrogen transfer between mycorrhizal plants. J Plant Ecology 2: 107-18 (Currently referenced in 1 Wikipedia page and a dozen of locations with details in “Mycorrhizal Networks” [2015 Springer, Thomas Horton, ed.).

72. He XH, Nara K. 2007. Element biofortification: Can mycorrhizas potentially offer a more effective and sustainable way to curb human malnutrition? Trends in Plant Science 12: 331-33 (被奥地利科学院 Marjori Matzke院士推荐为‘必读文献’, 见http://facultyopinions.com/prime/1090832).

73. He XH, Bledsoe CS, Zasoski RJ, Southworth D, Horwath WR. 2006. Rapid nitrogen transfer from ectomycorrhizal pines to adjacent ectomycorrhizal and arbuscular mycorrhizal plants in a California oak woodland. New Phytologist 170: 143-51 (被“New Phytologist”编辑部1次视为当年该刊15篇优秀树木研究前沿创新论文之一(173: 661-663/2007)和另1次视为未来重点论争及期待发表方向(176: 499-501/2007), 其主要结果被写入学术名著“Mycorrhizal Symbiosis” [2008年Academic Press (3版), Sally Smith (澳大利亚科学院院士)和David Read爵士(英国皇家学会副主席)编著]. Currently also referenced in 1 Wikipedia page, and in a dozen of locations with details in “Mycorrhizal Networks” [2015 Springer, Thomas Horton 编著).

74. Selosse M, Richard F, He XH, Simard S. 2006. Mycorrhizal networks: des liaisons dangereuses? Trends in Ecology & Evolution 21: 621-28 (Currently referenced in 7 Wikipedia pages, 1 Faceboob page, a 2007 New Phytologist Editorial 174: 225-227 and a dozen of locations with details in “Mycorrhizal Networks” [2015 Springer, Thomas Horton, ed.).

75. He XH, Critchley C, Ng H, Bledsoe CS. 2005. Nodulated N₂-fixing Casuarina cunninghamiana is the sink for net N transfer from non-N₂-fixing Eucalyptus maculata via an ectomycorrhizal fungus Pisolithus sp. supplied as NH₄NO₃. New Phytologist 167: 897-91295 (主要结果及一幅图表被写入学术名著“Plant Physiological Ecology” [2008 Springer (第2版, p420-21), Hans Lambers (澳大利亚科学院院士)、Francis Chapin (美国科学院院士)和Thijs Pons编著], currently also referenced in 1 Wikipedia page and a dozen of locations with details in “Mycorrhizal Networks” [2015 Springer, Thomas Horton 编著).

76. He XH, Critchley C, Ng H, Bledsoe CS. 2004. Reciprocal N (¹⁵NH₄⁺ or ¹⁵NO₃^) transfer between non-N2-fixing Eucalyptus maculata and N₂-fixing Casuarina cunninghamiana linked by the ectomycorrhizal fungus Pisolithus sp.. New Phytologist 163: 629-40 (主要结果及一幅图表被写入学术名著“Plant Physiological Ecology” [2008 Springer (第2版, p420-21), Hans Lambers (澳大利亚科学院院士)、Francis Chapin (美国科学院院士)和Thijs Pons编著], currently also referenced in 1 Wikipedia page and a dozen of locations with details in “Mycorrhizal Networks” [2015 Springer, Thomas Horton 编著).

77. He XH, Critchley C, Bledsoe CS. 2003. Nitrogen transfer within and between plants through common mycorrhizal networks. Critical Reviews in Plant Sciences 22: 531-67 (得到Janet Sprent (时任英国生态学会主席)在2005年“New Phytologist”(167: 326-330)和2009年“Legume nodulation, p43”专著上简评, and also referenced in a dozen of locations with details in “Mycorrhizal Networks” [2015 Springer, Thomas Horton 编著).