何新华
发布时间2014-09-01 16:55:31    作者:    浏览次数: 次

                                                                                        

 

何新华,原藉中国, 现藉澳大利亚                                                   

 

西南农业大学农学学士(1982), 华南农业大学/加拿大Guelph联培植物生理生化硕士(1991), 澳大利亚昆士兰大学植物生理生态博士(2002)中科院原昆明实习研究员(1982–1984), 云南师大助教、副教授和教授(1985-1995), 昆士兰大学植物系研究助理(1997–2001), 加州大学戴维斯分校与东京大学博士后(2002–2007), 西澳大利亚大学植物生物学系和美国农业部研究助理教授(2008–2011), 西澳大学地球与环境系研究副教授(2012–2014)。现任西南大学特聘教授土壤生物学研究中心主任, 兼悉尼大学和西澳大学副教授

科研方向为植物氮/碳生理生态、土壤-真菌-植物相互作用、土壤有益微生物和碳氮磷钾积累对环境变化响应与耕地保育及地力提升等, 主持和参与过的科研项目得到国家重点研发计划、国家基金委、美国国家基金委与农业部、澳大利亚国家研委会和联邦教科部与谷物研发组织及日本学术振兴会等资助。在菌根真菌促进植物之间双向氮素传递、改善土壤团聚体结构、提高土壤碳积累与植物抗逆能力、C3C4作物氮素利用效率等方面获得重要结果, 提出若干标志性新见解。

目前在Agr Ecosyst Environ, Agr Sust Develop, Biol Fert Soils, Crit Rev Plant Sci, Glob Biogeochem Cy, Mycorrhiza, Nature Geosci, New Phytologist, Plant Soil, SBB, SSAJ, Trends Ecol & Evol, Trends Plant Sci, Tree Physiol等发表论文120余篇, 所发论文被Am Nat, Annu Rev Ecol Evol System, Appl Environ Microbiol, Biogeochem, BioScience, BMC Evol Biol, Cladistics, Ecology, Ecol Lett, Ecol Monogr, Environ Microbiol, Front Ecol Environ, Funct Ecol, J Ecol, J Exp Bot, J Theoret Biol, Mol Ecol, Mycorrhiza, Nature, Nat Clim Change, Nat Geosci, New J Physics, New Phytol, Plant Cell & Environ, Plant J, Plant Physiol, Plant Soil, Science, SBB, SSAJ, Stud Mycol, Trends Ecol & Evol, Trends Plant Sci等多学科120余种期刊引用2,500余次。研究结果已100多次在国际同位素生态应用、国际菌根学会、国际根际大会、国际固氮大会、国际氮素大会、世界生态高峰会、美英真菌联合会、美国生态学会、美国农学-土壤-作物学会联合会等和HarvardUC DavisU TokyoUSDAKings Park, 国内如北大、北师大、中国农大、中国农科院、中国林科院、中科院植物、土壤、微生物、地理、水保、生态环境等研究所/中心进行了学术报告。曾任3种国际期刊(1994-2015)编委, 定期/不定期为国家自然基金委(NSFC)、澳大利亚(ARCGRDC)、英国(BBSRC sLoLa)、美国(NSFUSDA)及荷兰(NWO)等审评基金与学位论文和80余种英文期刊审评稿件。

 

教学:

《英文文献精读与解析》、《科研论文与报告撰写》、Soil Fertility and Ecology

《稳定性同位素在土壤和植物生理生态研究中的应用》

 

主持和参与过的主要科研项目:

2016-20       梨养分推荐方法与限量标准, 国家重点研发计划(2016YFD0200104)

2015-18       丛枝菌根菌丝网络在番茄植株间传递干旱信号的机理, 国家自然科学基金 (31470477)

2015-17       柑橘菌根根外菌丝释放球囊霉素相关土壤蛋白特性及相关功能, 国家自然科学基金 (31372017)

2014-17       印度檀香-降香黄檀寄生体系氮素营养双向传递作用机制, 国家自然科学基金(31300527)

2013-17       作物生产系统中土壤有机碳组分与增产功能, 澳大利亚谷物研发组织(DAN00169)

2010-14       丛枝菌根在柑橘根系碳库中的作用, 中央级公益性科研院所基本科研业务(国库2012-26102-43)

2010-12       减缓气候变化与地下水抽取对生态系统的影响, 澳大利亚国家研究委员会(LP0669240)

2009-10       白桦林外生菌根多样性与氮/碳生理功能对氮素沉降之响应, 美国农业部(NRI 2006-02587)

2008-09       给予或摄取:田间条件下木麻黄与桉树之间的氮素双向传递, 西澳大学发展基金

2007-08       根系穿透犁底耕层能力与大田作物水分摄取利用, 澳大利亚谷物研发组织(UWA00090)

2006-07       富有或稀有菌根在松林碳氮循环中具有相似功能吗? 日本学术振兴会和澳大利亚科学院

2002-06       生物复杂性:共有菌根网络主动抑或被动资源转移路径

                      美国国家基金委环境中的生物复杂性专项 (DEB-9981711)

1999.01       氮素在固氮和非固氮菌根植物之间的转移, 澳大利亚昆士兰大学博士论文海外研究基金

1997-01       受控温室条件下菌根调节桉树/木麻黄之间的氮素双向传递, 澳大利亚教育科学与培训部

1994-96       氮钾对水稻 Rubisco 动力学特性及产量和品质关系, 国家自然科学基金

1994-96       抗病毒转基因烟草中抗病毒基因的扩散和病毒区系变化

                      现教育部新世纪优秀人才支持计划和云南烟草公司

1994-96       云南松茸居群地理分布特征, 国家自然科学基金

1986-94       C3C4作物氮素利用效率

                      云南省教育厅, 加拿大科学与工程研究理事会(A2818)和国家研究委员会(DSS0156:31964)

 

研究生/博士后招生

招收的研究生/博士后可到美国加州大学戴维斯分校、西澳大利亚大学、悉尼大学、东京大学等相关研究室做交流培养。博士后待遇为每年15万人民币/年。此外,西南大学将为博士后提供21厅住房一套(月租600元)、优质中小学及幼儿园教育资源、国家规定的社会福利及医疗保险。

 

主要中文论著论文

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

何新华 编著 1994. 铁的生物无机化学, 云南科技出版社(首届云南省学术著作出版基金资助, ISBN 7-5416-0357-O/D.7, 1-240,  20万字).

白宝璋, 张宪政主编, 何新华, 李攸福, 陈凤玉, 金光春副主编 1994. 植物生理学 (第二版), 中国科学技术出版社 (ISBN7-5046-0837-8/S.116, 50万字).

白宝璋, 汤学军主编, 何新华, 田文勋, 王三根, 田永清副主编 1993. 植物生理学测试技术, 中国科学技术出版社 (ISBN7-5046-0837-8/S.116, 50万字).

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

何新华, 徐维山 1995. 滇南少数民族农林生态结构多样性与持续发展 以西双版纳傣族自治州傣族为例. 《科学对社会的影响》6(4): 39-45.

何新华 1993. 壁山县农田生态中氮肥利用与平衡的研究.《生态学杂志》12(5): 29-35.

何新华, Ann Oaks 和李明启1995. C3C4禾本科植物的氮素利用效率. 《植物学报》 12(3): 20-27.

何新华, Ann Oaks李明启 1995. C3 C4 禾本科作物的氮素利用效率: 外源 NO3- NRP 形成和NR 活性影响的比较,《中国科学技术协会第二届青年学术年会论文集》, 中国科技出版社,P. 173-179.

何新华 1993. 从植物基因工程的潜在危险看植物基因工程植物生态学的建立, 见《首届全国新学说新观点学术讨论会论文集》, 中国科学技术出版社, P. 306-311.

何新华 1995. C3C4植物的比较营养学及其展望, 见张福锁主编《土壤与植物营养研究新动态》(第三卷), 中国农业出版社, P. 270-283.

 

Background/Introduction

Dr. He has focused on nitrogen use efficiency in C3 and C4 cereals, carbon and nitrogen movement in agricultural and natural ecosystems, roles of nitrogen fixing microbes and plant beneficial mycorrhizal fungi in plant ecophysiology/nutrition and soil health. Dr. He is currently exploring emerging technologies such as 454 Pyrosequencing, High Resolution Optical and/or Electron Microscopy, Nano-scale Secondary Ion Mass Spectrometry (nanoSIMS), RNA/DNA Stable Isotope Probing (DNA/RNA-SIP) and Synchrotron Radiation Facility, etc., to address above-mentioned topics in a variety of plant-microbial-soil systems under global environmental change scenarios.

 

Qualifications

PhD       Plant Ecophysiology, University of Queensland, Australia

MS Plant Physiology & Biochemistry, South China Agricultural University, China

BS  Soil Science & Agrochemistry, Southwest Agricultural University, China

 

Work Experience

2015           Professor & Director, Centre of Excellence of Soil Biology, Southwest University, China

2014           Adjunct Associate Professor, Univ. Sydney & Univ. Western Australia, Australia

2008-2014  Research Fellow/Associate Professor, University of Western Australia, Australia

2006-2007  Postdoctoral Fellow, University of Tokyo, Japan

2002-2006  Postdoctoral Fellow, University of California at Davis, USA

1997-2001  Research Assistant, University of Queensland, Australia

 

Research Interests

·           Availability of soil nutrients and their use efficiency in C3 and C4 plants

·           Integrations of aboveground performance and belowground process

·           Nano-minerals in soil organic carbon sequestration and functionality of organic matter

·           Network theory to address resource facilitation via mycorrhizal fungi and/or bacteria

·           Tracking 2H, 13C, 15N and/or 18O movement in plant-microbial-soil systems

·           Wax-layer simulation to enhance root hardpan penetration and micronutrient biofortification

 

Key Words

C3 and C4 plants

Carbon, hydrogen, nitrogen and oxygen stable isotopes

Mycorrhizal symbiosis

Nitrogen movement between plants

Nutrient use efficiency

Soil carbon and fertility

 

Professional Memberships/Activities

Australian Society of Plant Biologists (1997–); Plant & Soil (Editorial Board, 2007–2015); Three Scientific Societies in China

American Association for the Advancement of Science (2003–); International Mycorrhizal Society (Life time)

Peer Review for >80 peer-review international journals (AEE, Appl Soil Ecol, Biogeochem, Biogeosci, Biol & Fert Soils, Fungal Ecol, J Appl Ecol, J Ecol, Mycorrhiza, New Phytol, Plant Cell & Environ, Plant Physiol, Plant Soil, SBB, SSAJ, Tree Physiol, etc.) & major funding bodies (Australia, ARC, GRDC; China, NSFC; UK, BBSRC sLoLa; USA, NSF, USDA; and Netherlands, Netherlands Organisation for Sci Res, NWO); PhD and Masters theses around the world.

 

Publications (For a full list of publications see https://www.researchgate.net/profile/Xinhua_He3 OR http://www.researcherid.com/rid/B-8047-2015)

 

Selected Refereed Journal Publications

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.

Hao QJ, Jiang CS, Chai XS, Huang Z, Fan ZW, Xie DT, He XH. 2016. Drainage, no-tillage and crop rotation decreases annual cumulative emissions of methane and nitrous oxide from a rice field in Southwest China. Agriculture, Ecosystems & Environment 233: 270-281.

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.

He F, Yang BS, Wang H, Yan QL, Cao Y, He XH. 2016. Changes in composition and diversity of fungal communities along Quercus mongolica forests developments in Northeast China. Applied Soil Ecology 100: 162-171.

Liu SL, Guo XL, Feng G, Maimaitiaili B, Fan JL, He XH. 2016. Indigenous arbuscular mycorrhizal fungi can alleviate salt stress and promote growth of cotton and maize in saline fields. Plant & Soil 398: 195-206.

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.

Shen P, Wu ZF, Wang CX, Luo S, Zheng YM, Yu TY, Sun XW, Sun XS, Wang CB, He XH. 2016. Contributions of rational soil tillage to compaction stress in main peanut producing areas of China. Scientific Reports 6: 38629 DOI: 10.1038/srep38629.

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.

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.

Wu QS, Liu CY, Zhang DJ, Zou YN, He XH, Wu QH. 2016. Mycorrhizas alter the profile of root hairs in trifoliate orange. Mycorrhiza 26: 237-247.

Xiao J, He XH, Zhou Y, Zheng L, Hao J, Ran W, Shen Q, Yu G. 2016. In situ interactive characteristics of reactive minerals in soil colloids and soil carbon preservation differentially revealed by nanoscale secondary ion mass spectrometry and X-ray absorption fine structure spectroscopy. Biogeosciences 13: 3607-18.

Zhang YT, He XH, Liang H, Zhao J, Zhang YQ, Xu C, Shi XJ. 2016. Long-term tobacco plantation induces soil acidification and soil base cation loss. Environmental Science and Pollution Research 23: 5442-50.

Zhao YN, Zhang YQ, Liu XQ, He XH, Shi XJ. 2016. Carbon sequestration dynamic and trend as affected by 22-year fertilization under rice-wheat cropping system. Journal of Plant Nutrition and Soil Science 179: 605-684.

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.

Chen YP, Wang KB, Lin YS, Shi WY, Song Y, He XH. 2015. Balancing green and grain trade. Nature Geoscience 8: 739-741.

He YT, Zhang WJ, *Xu MG, Tong XG, Sun FX, Wang JZ, Huang SM, Zhu P, He XH. 2015. Long-term combined chemical and manure fertilizations increase soil organic carbon and total nitrogen in aggregate fractions at three typical cropland soils in China. Science of the Total Environment 532: 635–644.

Li JF, He XH, Li H, Zheng WJ, Liu JF, Wang MY. 2015. Arbuscular mycorrhizal fungi increase growth and phenolics synthesis in Poncirus trifoliata under iron deficiency. Scientia Horticulturae 183: 87-92.

Wu HT, Lu MZ, Guan Q, Lu XG, He XH. 2015. Negative effects of interactions between earthworm and mesofauna on soil CO2 and N2O emissions. Soil Biology & Biochemistry 88: 294-97.

Wu QS, Li Y, Zou YN, He XH. 2015. Arbuscular mycorrhiza mediates glomalin-related soil protein production and relevant soil enzyme activity in the rhizosphere of trifoliate orange grown under different P levels. Mycorrhiza 25: 121-30.

Zhang J, Tang XL, He XH, Liu JX. 2015. Glomalin-related soil protein responses to elevated CO2 and nitrogen addition in subtropical forest: potential consequences for soil carbon accumulation. Soil Biology & Biochemistry 83: 142-49.

Zou YN, Huang YM, Wu QS, He XH. 2015. Mycorrhizal-induced lower oxidative burst is related with higher antioxidant enzyme activities, net H2O2 effluxes and Ca2+ influxes in trifoliate orange roots under drought stress. Mycorrhiza 56: 143-50.

Acuna TLB, Rebetzke GJ, He XH, Maynol E, Wade LJ. 2014. Mapping quantitative trait loci associated with root penetration ability of wheat in contrasting environments. Molecular Breeding 34: 631-642.  

Chen YP, Liu Q, Liu YJ, Jia FA, He XH. 2014. Responses of soil microbial activity to cadmium pollution and elevated CO2. Scientific Reports 4: 4287 DOI: 10.1038/srep04287.

Jiang GY, Xu MG, He XH, Zhang WJ, Huang SM, Yang XY, Liu H, Peng C, Shirato Y, Iizumi T, Wang JZ, Murphy DV. 2014. Soil organic carbon sequestration in upland soils of northern China under variable fertilizer management and climate change scenarios. Global Biogeochemical Cycles 28: 319-33.

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.

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 DOI: 10.1038/srep03915.

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 http://www.sciencewa.net.au/topics/agriculture/item/3052-manure-offsets-fertiliser-s-nano-scale-changes & www.ecosmagazine.com/?paper=EC14220).

Wu QS, Cao MQ, Zou YN, He XH. 2014. Direct and indirect effects of glomalin, mycorrhizal hyphae, and roots on aggregate stability in rhizosphere of trifoliate orange. Scientific Reports 4: 4287 DOI: 10.1038/srep05823

Liang B, Yang XY, Murphy DV, He XH, Zhou JB. 2013. Fate of 15N-labeled fertilizer in the soils after 19-year different fertilization in wheat-fallow cropping system. Biology and Fertility of Soils 49: 977-986.

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.

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.

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.

Liang B, Yang XY, He XH, Murphy DV, Zhou JB. 2012. Long-term combined application of manure and NPK fertilizers influenced N retention and stabilization of organic C in Loess soil. Plant & Soil 353: 249-260.

Wu QS, He XH, Zou YN, He KP, Sun YH, Cao MQ. 2012. Spatial distribution of glomalin-related soil protein and its relationships with root mycorrhization, soil aggregates, carbohydrates, activity of protease and β-glucosidase in rhizosphere of Citrus unshiu. Soil Biology & Biochemistry 45: 181-183.

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.

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 (Briefly introduced by VerticalNews China in the USA, see http://www.verticalnews.com/newsletters/China-Weekly-News/2011-01-25/1454TI.html).

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.

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.

Qiu GY, Wang LM, He XH, Zhang XY, Chen SY, Chen J, Yang YH. 2008. Water use efficiency and evapotranspiration of winter wheat and its response to irrigation regime in the north China Plain. Agricultural & Forest Meteorology 148: 1848-59.

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 (Recommended as a “Must Read”, see http://f1000.com/prime/1090832. IF: 14.673, Rank in Plant Sci: 2/200).

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 (Briefly introduced by two 2007 New Phytologist Editorials, 173: 661-663 and 176: 499-501; and a 2008 book entitled “Mycorrhizal Symbiosis”, p597).

Selosse M, Richard F, He XH, Simard S. 2006. Mycorrhizal networks: des liaisons dangereuses? Trends in Ecology & Evolution 21: 621-28 (Briefly introduced by a 2007 New Phytologist Editorial, 174: 225-7. 211 citations).

Southworth D, He XH, Swenson WS, Bledsoe CS, Horwath WR. 2005. Application of network theory to potential mycorrhizal networks. Mycorrhiza 15: 589-.

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 (Major results adopted by a 2008 book entitled “Plant Physiological Ecology”, p420-21).

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 (Major results adopted by a 2008 book entitled “Plant Physiological Ecology”, p420-21).

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 (Briefly introduced by a 2005 New Phytologist Letter, 167: 326-330) and a 2009 book entitled “Legume Nodulation”, p43).

 

─ Selected Scholarly Book Chapters

Msafiri Yusuph Mkonda MY, He XH. 2017. Conservation Agriculture in Tanzania. In: Sustainable Agriculture Reviews, 309-324. Lichtfouse ed., Springer International Publishing, Switzerland.

Simard S, Beiler K, Bingham M, Deslippe J, He XH, Philip L, Song YY, Teste F. 2015. Resource transfer between plants through ectomycorrhizal network. In: Mycorrhizal Networks, 133-176. Horton TR, ed. Springer, Germany.

Saker JR, Singh BP, He XH, Fang YY, Li GD, Cowie AL. 2014. In situ dynamics of ‘recent’ carbon and nitrogen in a Red Kandosol under contrasting crop management. 2014 National Soil Conference (4 pages, see http://soilscienceaustralia.com.au/soil2014/proceedings/Sarker.pdf), Australian Society of Soil Science, Melbourne, Australia.

He XH, Lilleskov E. 2014. Arsenic uptake and phytoremediation potential by arbuscular mycorrhizal fungi. In: Mycorrhizal Fungi: Use in Sustainable Agriculture & Land Restoration, 259-75. Solaiman Z, Abbott L & Varma A, eds. Springer, Germany.

He XH, Critchley C, Nara K, Southworth D, Bledsoe CS. 2009. Quantification of nitrogen transfer between plants linked by mycorrhizal networks. In: Symbiotic Fungi, 285-91. Varma A & Kharkwal A, eds. Springer

He XH, Manyol E, Nio SA, Malik I, Botwright-Acuna T, *Wade L. 2008. Hardpan penetration ability of drought-stressed wheat. 2008 Agribusiness Crop Updates, 88-91. Dept Agri. & Food, ed., Perth, Australia (Introduced by Farming Weekly (12/06/2008), Merredin-Wheatbelt Mercury (02/07/2008), Australian Grain (01/08/2008), http://www.getfarming.com.au and http://www.seedquest.com (USA), & adopted by a Kings Park Restoration Program, Australia).

He XH, Critchley C. 2008. Frankia nodulation, mycorrhization and interactions between Frankia and mycorrhizal fungi in Casuarina plants. In: Mycorrhiza (3rd edn), 767-81. Varma A, ed. Springer, Germany.

He XH, Liu M, Lu JY, Xue H, Pan Y. 2006. Space mutation breeding: A brief introduction of screening new floricultural, vegetable & medicinal varieties from earth-grown plants returned from China’s satellites/spaceships. In: Floriculture, Ornamental and Plant Biotechnology. IV: 266-71. da Silva JT, ed. Global Science Books, London, UK.

He XH, Oaks A, Li M. 1994. Nitrogen use efficiency in C3 and C4 plants. Agro’s Annu Rev Plant Physiol 1: 147-88.

Oaks A, He XH, Zoumadakis M. 1990. Nitrogen use efficiency in C3 and C4 cereals. In: Proceedings of International Congress of Plant Physiology 2: 1038-45. SK Sinha et al., eds. Neo Art Press, India.

 

地址/Address:重庆市北碚区天生桥路2号西南大学资源环境学院

                          College of Resources and Environment

                          Southwest University

                          2 Tiansheng Road

                          Beibei, Chongqing 400716

                          China

电邮/E-mailxinhua.he@uwa.edu.au

电话/Tel 86-18723289058 (mobile)

Academic profile: https://www.researchgate.net/profile/Xinhua_He3

Recruitment: Candidates for Master, PhD and postdoctoral fellow are warmly welcome.