CRRICULUM VITAE_PENG WANG

汪 鹏 (Peng Wang)
教授，博士生导师，国家青年人才
通信地址：南京农业大学，资源与环境科学学院
Professor in Environmental Soil Science
College of Resources and Environmental Sciences Nanjing Agricultural University, Nanjing 210095,
China
( (+86) 25 8439 9562 (Tel) : 理科北楼 A-616
* p.wang3@njau.edu.cn

从事专业：
环境生物学、土壤重金属污染与修复、土壤污染与人体健康
研究方向：
? 污染元素生物地球化学与人体健康
? 人体离子组学与人体健康
? 元素原位高通量和高灵敏度分析技术
? 农田土壤重金属污染与修复
招生方向：
农业资源与环境、植物营养、微生物、环境科学与工程

欢迎对科学研究感兴趣的优秀学生报考本人硕士及博士研究生！欢迎在相关研究方向取得博士学位的加盟本团队进行博士后研究！
招聘师资博后、讲师、副教授，要求：
? 具有土壤学、植物学、环境生物学、环境科学、统计学、计算机学、或图像处理等相关领域获得博士学位
? 对科学研究有强烈兴趣，有创新思维，动手能力强，有独立开展科研能力
? 工作勤奋、富有团队合作精神
教育经历：
2006/09–2011/07，中国科学院，南京土壤研究所，博士
2002/09–2006/07，安徽大学，生命科学学院，学士

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CRRICULUM VITAE_PENG WANG

研究工作经历：
2016/03–至今，南京农业大学 资源与环境科学学院，教授、博导 2015/01–2016/12，澳大利亚 昆士兰大学，农业与食品科学学院，Research Fellow
/ Lecturer 2013/01–2015/12，澳大利亚 昆士兰大学，ARC DECRA Research Fellow
2011/08–2012/12，澳大利亚 昆士兰大学，农业与食品科学学院，博后
学术任职与服务:
? 国际 SCI 期刊《Plant and Soil》编委 (2015-)；《土壤学报》编委
? 《Frontiers in Plant Science》、《Journal of Chemistry》客座 Editor
? 澳大利亚同步辐射中心项目评审委员（2014- ）
? 江苏省土壤学会理事 （2016-）
? 江苏省土壤学会教育专业委员会主任（2020- ）
? 中国土壤学会土壤分析专业委员会副主任（2019-）
? 中国植物生理学会修复生物学专业委员会委员（2019- ）
? 中国土壤学会土壤环境专业委员会委员（2018- ）
? 10 余种国际期刊审稿人，《Environmental Pollution》 Outstanding Reviewer
获奖及荣誉:

2020
2018
中国土壤学会优秀青年学者奖江苏省杰出青年基金获得者
2013 ARC Discovery Early Career Researcher Award (Australian Research Council)
(澳大利亚政府“探索”青年研究学者奖)
2012 中国科学院 优秀博士学位论文
2011 中国科学院 院长特别奖

主持的科研项目：
1. 国家自然科学基金面上项目，我国典型镉污染地区人群健康风险定量化关系研究，62 万，
2020-2023. 主持
2. 江苏省自然科学基金杰出青年项目，农田镉、砷污染阻控，100 万，2019-2022. 主持
3. 国家重点研发计划重点专项子课题，典型场地土壤重金属的形态转化过程与调控机制，62 万，
2019-2022. 参与
4. 国家重点研发计划重点专项子课题，土壤砷、铬迁移转化和生物有效性研究，400 万，2016- 2020. 主持

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CRRICULUM VITAE_PENG WANG

5. 国家自然科学基金面上项目，水稻土 Cd 生物有效性的控制过程解析与调控，66 万，2017- 2020. 主持
6. 南京农业大学资源与环境学院人才引进项目，30 万，2016-2017. 主持
7. 国家青年人才项目，300 万，2016-2020. 主持
8. 南京农业大学高层次引进人才启动基金，300 万，2016-2020. 主持
9. CSIRO (澳大利亚联邦科学与工业研究组织). Fate and behaviour of nanomaterials in terrestrial ecosystems and
ecosystem health. Peter Kopittke, Neal Menzies, and Peng Wang. AU$ 100,000. 2015-2019.
10. ARC (澳大利亚政府研究委员会) Discovery of Early Career Researcher Award: Improving risk- based
assessments of trace metal bioavailability in soil-plant systems: A focus on cadmium (Cd). Peng
Wang (Fellowship). ARC DECRA AU$ 375,000. 2012-2015.
11. UQ (澳大利亚昆士兰大学) Early Career Research Scheme: Synchrotron-based XANES imaging for studying
uptake, speciation, and translocation of selenium in soil-crop systems. Peng Wang. The University
of Queensland. AU$39,400. 2014.


主要学术专著与论文（*:通讯作者）:
Updated on July 1, 2020
? 社会服务
1. 汪鹏，赵方杰. 《内参咨询报告》. 2019.（得到国家领导人重要批示，受到国务院多部委高度重视）

? 发明专利和软件著作权
2. 汪鹏，黄辉，赵方杰. 一种抑制稻田土壤有效态镉释放和稻米镉积累的方法. 2020. 专利申请号: 202010083416.X
3. 汪鹏，王静，赵方杰. 污染农田稻米镉阻控的锰负载生物炭的制备与应用. 2020. 专利申请号：202010651023.4
4. 汪鹏，赵方杰，陈宏坪，唐仲. 酸性土壤改良和镉污染农田安全利用石灰质物料用量计算软件. 2020. 软件著作权登记号：2020SR1004367

? 专著章节
5. Wang P*, Kopittke PM, McGrath S, Zhao FJ. 2017. Cadmium transfer from soil to plants and its
potential risk to human health. In: Singh BR, McLaughlin MJ, Brevik E (eds). The Nexus of Soils,
Plants, Animals and Human Health. Catena- Schweizerbart: Stuttgart, pp 138-147.

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CRRICULUM VITAE_PENG WANG

? 学术论文 (* 通讯作者)
2020

6. Gu Y, Wang P*, Zhang S, Dai J, Chen H, Lombi E, Zhao F-J. Chemical speciation and distribution
of cadmium in rice grain and implications for bioavailability to humans. Environmental Science &
Technology 2020. In Press. https://doi.org/10.1021/acs.est.0c03001
7. Wu J, Bai Y, Lu B, Zhao W, Forstner C, Menzies NW, Wang P*, Kopittke PM. Silver sulfide
nanoparticles reduce nitrous oxide emissions by inhibiting denitrification in the earthworm gut.
Environmental Science & Technology 2020, 54(18): 11146-11154.
8. Zhao F-J, Wang P. 2020. Arsenic and cadmium accumulation in rice and mitigation strategies.
Plant Soil 446 (1): 1-21.

9. Chang J-D, Huang S, Konishi N, Wang P, Chen J, Huang X-Y, Zhao F-J. 2020. Overexpression of
the manganese/cadmium transporter OsNRAMP5 reduces cadmium accumulation in rice grain. Journal of
Experimental Botany In press. https://doi.org/10.1093/jxb/eraa287
10. Tang Z, Wang Y, Gao A, Ji Y, Yang B, Wang P, Tang Z, Zhao F-J. 2020. Dimethylarsinic acid is
the causal agent inducing rice straighthead disease. Journal of Experimental Botany. In press.
https://doi.org/10.1093/jxb/eraa253.
11. Kopittke PM, Lombi E, van der Ent A, Wang P*, Laird J, Moore K, Persson DP, Husted S. 2020.
Methods to visualize elements in plants. Plant Physiology, 182: 1869-1882.
12. Chen H, Wang P*, Gu Y, Kretzschmar R, Kopittke PM, Zhao F-J. 2020 The within-field spatial
variation in rice grain Cd concentration is determined by soil redox status and pH during grain
filling. Environmental Pollution, 261: 114151.
13. Dai J, Tang Z, Jiang N, Kopittke PM, Zhao F-J, Wang P* 2020. Increased arsenic mobilization in
the rice rhizosphere is mediated by iron-reducing bacteria. Environmental Pollution, 263: 114561.
14. Wu J, Li C, Zhang J, Menzies NW, Bertsch PM, Wang P*, Kopittke PM. 2020. Release of silver from
nanoparticle-based filter paper and the impacts to mouse gut microbiota. Environmental Science:
Nano. 2020,7, 1554-1565.
15. Wu J, Bai Y, Lu B, Li C, Menzies NW, Bertsch PM, Wang Z, Wang P*, Kopittke PM. 2020.
Application of sewage sludge containing environmentally-relevant silver sulfide nanoparticles
increases emissions of nitrous oxide in saline soils. Environmental Pollution 265: 114807.
16. 赵方杰，谢婉滢，汪 鹏. 2020. 土壤与人体健康. 土壤学报, 57(1): 1-11.


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CRRICULUM VITAE_PENG WANG

17. Lu J, Zhang S, Gao S, Wang P, Bond PL, Guo J 2020. New insights of the bacterial response to
exposure of differently sized silver nanomaterials. Water Research 169:115205.


2019

18. Yang YP, Wang P, Yan HJ, Zhang HM, Cheng WD, Duan GL, Zhu YG 2019. NH4H2PO4- extractable
arsenic provides a reliable predictor for arsenic accumulation and speciation in pepper fruits
(Capsicum annum L.). Environ Pollution 251:651-658.
19. Kopittke PM, Menzies NW, Wang P*, McKenna BA, Lombi E 2019. Soil and the intensification of
agriculture for global food security. Environment International 132:105078.
20. Wang J, Wang P-M, Gu Y, Kopittke PM, Zhao F-J, Wang P* 2019. Iron-manganese (oxyhydro)oxides,
rather than oxidation of sulfides, determine the mobilization of Cd during soil drainage in paddy
soil systems. Environmental Science & Technology 53, 2500-2508.
21. Wang P*, Zhao F-J, Kopittke PM 2019. Engineering Crops without Genome Integration Using
Nanotechnology. Trends in Plant Science 24 (7), 574-577.
22. Wang P*, Chen H, Kopittke PM, Zhao F-J 2019. Cadmium contamination in agricultural soils of
China and the impact on food safety. Environment Pollution 249, 1038-1048. (ESI 高被引论文)
23. Xu X, Wang P*, Zhang J, Chen C, Wang Z, Kopittke PM, Kretzschmar R, Zhao F-J 2019. Microbial
sulfate reduction decreases arsenic mobilization in flooded paddy soils with high potential for
microbial Fe reduction. Environmental Pollution 251, 952-960.
24. Wang P*, McKenna BA, Menzies NW, Li C, Glover C, Zhao F-J, Kopittke PM 2019. Minimizing
experimental artefacts in synchrotron-based X-ray analyses of Fe speciation in tissues of rice
plants. Journal of Synchrotron Radiation 26, 1272-1279.
25. Zhang YQ, Bhattacharyya R, Dalal RC, Wang P, Menzies NW, Kopittke PM Impact of land use change
and soil type on total phosphorus and its fractions in soil aggregates. Land Degradation &
Development:14. doi:10.1002/ldr.3501
26. Blarney FPC, Li C, Howard DL, Cheng MM, Tang CX, Scheckel KG, Noerpel MR, Wang P, Menzies NW,
Kopittke PM (2019) Evaluating effects of iron on manganese toxicity in soybean and sunflower using
synchrotron-based X-ray fluorescence microscopy and X-ray absorption spectroscopy. Metallomics 11
(12):2097-2110.



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CRRICULUM VITAE_PENG WANG

2018

27. 汪鹏*，王静，陈宏坪，周东美，赵方杰. 2018. 我国稻田系统镉污染风险与阻控. 农业环境科学学报, 37(7): 1409-1417.
28. Xiong L, Wang P*, Hunter MN, Kopittke PM 2018. Bioavailability and movement of hydroxyapatite
nanoparticles (HA-NPs) applied as a phosphorus fertiliser in soils. Environmental Science: Nano. 5,
2888-2898.
29. Wang P*, Lombi E, Menzies NW, Zhao F-J, Kopittke PM 2018. Engineered silver nanoparticles in
terrestrial environments: a meta-analysis shows that the overall environmental risk is small.
Environmental Science: Nano 5, 2531-2544. (封面文章)

30. Xiong L, Wang P*, Kopittke PM 2018. Tailoring hydroxyapatite nanoparticles to increase their
efficiency as phosphorus fertilisers in soils. Geoderma 323, 116-125.
31. Li C, Wang P*, Lombi E, Cheng M, Tang C, Howard DL, Menzies NW, Kopittke PM 2018. Absorption of
foliar-applied Zn fertilizers by trichomes in soybean and tomato. Journal of Experimental Botany
69, 2717-2729.
32. Wang P*, Menzies NW, Chen H, Yang X, McGrath SP, Zhao F-J, Kopittke PM 2018. Risk of silver
transfer from soil to the food chain is low after long-term (20 years) field applications of sewage
sludge. Environmental Science & Technology 52, 4901-4909.
33. Kopittke PM, Punshon T, Paterson DJ, Tappero RV, Wang P*, Blamey FPC, van der Ent A, Lombi E
2018 Synchrotron-Based X-Ray Fluorescence Microscopy as a Technique for Imaging of Elements in
Plants. Plant Physiology 178, 507-523. (封面文章) (ESI 高被引论文)
34. Blamey FPC, McKenna BA, Li C., Cheng M, Tang C, Jiang H, Howard DL, Paterson DJ, Kappen P, Wang
P, Menzies NW, Kopittke PM 2018. Manganese distribution and speciation help to explain the effects
of silicate and phosphate on manganese toxicity in four crop species. New Phytologist 217,
116-1160.
35. Hernandez-Soriano MC, Dalal RC, Warren FJ, Wang P, Green K, Tobin MJ, Menzies NW, Kopittke PM
2018. Soil Organic Carbon Stabilization: Mapping Carbon Speciation from Intact Microaggregates.
Environmental Science & Technology 52, 12275-12284.
36. Chen H, Yang X, Wang P, Wang Z, Li M, Zhao F-J 2018. Dietary cadmium intake from rice and
vegetables and potential health risk: A case study in Xiangtan, southern China. Science of the
Total Environment 639, 271-277. (ESI 高被引论文)
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CRRICULUM VITAE_PENG WANG

37. Chen H, Tang Z, Wang P, Zhao F-J 2018. Geographical variations of cadmium and arsenic
concentrations and arsenic speciation in Chinese rice. Environmental Pollution 238, 482-490.
38. Chen H, Zhang W, Yang X, Wang P, McGrath SP, Zhao F-J 2018. Effective methods to reduce cadmium
accumulation in rice grain. Chemosphere 207, 699-707.
39. Li Z., Wang P*, Menzies NW and Kopittke PM 2018. Defining appropriate methods for studying
toxicities of trace metals in nutrient solutions. Ecotoxicology and Environmental Safety 147, 872-
880.
40. Kopittke P M, Dalal R C, Wang P and Menzies NW 2018. Effects of long-term cultivation on
phosphorus (P) in five low-input, subtropical Australian soils. Agricultural Ecosystem Environment
252, 191-199.
41. Li C, Wang P, Lombi E, Wu J, Blamey FPC, Fernández V, Howard DL, Menzies NW, Kopittke PM 2018.
Absorption of foliar applied Zn is decreased in Zn deficient sunflower (Helianthus annuus) due to
changes in leaf properties. Plant and Soil 433, 309-322.
42. Cheah ZX, Kopittke PM, Harper SM, O’Hare TJ, Wang P, Paterson DJ, de Jonge MD, Bell MJ 2018. In
situ analyses of inorganic nutrient distribution in sweetcorn and maize kernels using
synchrotron-based X-ray fluorescence microscopy. Annals of Botany, mcy189-mcy189.


2017

43. Xu X, Chen C, Wang P, Kretzschmar R, Zhao FJ. 2017. Control of arsenic mobilization in paddy
soils by manganese and iron oxides. Environmental Pollution. 231, 37-47.
44. Kopittke PM, McKenna BA, Karunakaran C, Dynes JJ, Arthur Z, Gianoncelli A, Kourousias G,
Menzies NW, Ryan PR, Wang P*, Green K, Blamey FPC. 2017. Aluminum Complexation with Malate within
the Root Apoplast Differs between Aluminum Resistant and Sensitive Wheat Lines. Frontiers in Plant
Science. 8, 1377.
45. Kopittke PM, Wang P*. 2017. Kinetics of metal toxicity in plant roots and its effects on root
morphology. Plant and Soil. 419: 269-279.
46. Li C, Wang P*, Menzies NW, Lombi E and Kopittke PM. 2017. Effects of changes in leaf properties
mediated by methyl jasmonate (MeJA) on foliar absorption of Zn, Mn, and Fe. Annals of Botany. 120,
405-415.
47. Li M, Wang P, Dang F and Zhou DM. 2017. The transformation and fate of silver nanoparticles in
a paddy soil: Effects of soil organic matter and redox conditions. Environmental Science: Nano.
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CRRICULUM VITAE_PENG WANG

4, 919-928.

48. Kopittke PM, Wang P*, Lombi E, and Donner E. 2017. Synchrotron-based X-ray approaches for
examining toxic trace metal(loid)s in soil-plant systems. Journal of Environmental Quality. 46：
1175-1189.
49. Wang P*, Lombi E, Sun S, Scheckel KG, Malysheva A, McKenna B, Menzies N, Zhao FJ and Kopittke
PM. 2017. Characterizing the uptake, accumulation and toxicity of silver sulfide nanoparticles in
plants. Environmental Science: Nano. 4, 448-460.
50. Yang X, Pan H, Wang P*, and Zhao FJ. 2017. Particle-specific toxicity and bioavailability of
cerium oxide (CeO2) nanoparticles to Arabidopsis thaliana. Journal of Hazardous Materials. 332,
292-300. (ESI 高被引论文)


2016

51. Wang P, Liu YJ, Menzies NM, Wehr JB, de Jonge M, Howard D, Kopittke PM, and Huang L. 2016.
Ferric minerals and organic matter change arsenic speciation in copper mine tailings. Environmental
Pollution. 218, 835-843.
52. Cheng M, Wang P, Kopittke PM, Wang A, Sale PWG, and Tang C. 2016. Cadmium accumulation is
enhanced by ammonium compared to nitrate in two hyperaccumulators, without affecting speciation.
Journal of Experimental Botany. 67, 5041-5050.
53. Wang P*, Menzies NW, Dennis PG, Guo J, Forstner C, Sekine R, Lombi E, Kappen P, Bertsch PM and
Kopittke PM. 2016. Silver nanoparticles entering soils via the wastewater-sludge-soil pathway pose
low risk to plants but elevated Cl concentrations increase Ag bioavailability. Environmental
Science & Technology. 50, 8274-8281. (Highlighted by European Commission “Science for Environmental
Policy”)
54. Wang P*, Lombi E, Zhao F-J, and Kopittke PM. 2016. Nanotechnology: A new opportunity in plant
sciences. Trends in Plant Science. 22, 699-712. (ESI 高被引论文)
55. Kopittke PM, Menzies NW, Wang P*, and Blamey FP. 2016. Kinetics and nature of aluminium
rhizotoxic effects: A review. Journal of Experimental Botany. 67, 44514-4467.
56. Forstner C, Wang P, Kopittke PM and Dennis Paul. 2016. The effects of graphene oxide on soil
bacterial diversity remain unknown. RCS Advances. 6, 51203-51204.



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57. Yan J, Wang P, Wang P, Tang Z, Huang C, Yang M, Lian X, Salt DE, and Zhao F-J. 2016. A loss-
of-function allele of OsHMA3 associated with high cadmium accumulation in shoots and grain of
Japonica rice cultivars. Plant, Cell & Environment. 39, 1941-1954. (ESI 高被引论文)


2015

58. Qiu H, Vijver M, He E Liu, Y, Wang P, Xia B, Smolders E, Versieren L, and Peijnenburg WGM.
2015. Incorporating bioavailability into toxicity assessment of Cu-Ni, Cu-Cd, and Ni-Cd mixtures
with the extended biotic ligand model and the WHAM-F tox approach. Environmental Science and
Pollution Research. 22, 19213-19233.
59. Wang P*, Menzies NW, Lombi E, McKenna B, James S, Caixian T, and Kopittke PM. 2015.
Synchrotron-based XANES imaging for laterally resolved speciation of selenium in fresh roots and
leaves of wheat and rice. Journal of Experimental Botany. 66, 4795-4806.
60. Wang P*, Menzies NW, Lombi E, Sekine R, Blamey FPC, Hernandez-Soriano M, Miaomiao C, Kappen P,
Peijnenburg W, Caixian T, and Kopittke PM. 2015. Silver sulfide nanoparticles (Ag2S- NPs) are taken
up by plants and are phytotoxic. Nanotoxicology. 9, 1041-1049.
61. Kopittke P, Moore KL, Lombi E, Gianoncelli A, Ferguson BJ, Blamey FPC, Menzies NW, Nicholson
M, McKenna BA, Wang P, Gresshoff PM, Kourousias G, Webb RI, Green K, and Tollenaere A. 2015.
Identification of the primary lesion of toxic aluminum (Al) in plant roots. Plant Physiology. 167:
1402-1411. (ESI 高被引论文)
62. Yen Le TT, Swartjes F, R?mkens P, Groenenberg JE, Wang P, Lofts S, and Hendriks AJ. 2015.
Modelling metal accumulation using humic acid as a surrogate for plant roots. Chemosphere. 124:
61-69.


2014

63. Wang YM, Wang P, Ni LF, Hao XZ, Zhou DM. 2014. Assessment of the Zn–Co mixtures rhizotoxicity
under Ca deficiency: Using two conventional mixture models based on the cell membrane surface
potential. Chemosphere. 112, 232-239.
64. Wang YM, Kinraide TB, Wang P, Hao XZ, Zhou DM. 2014. Surface electrical potentials of root cell
plasma membranes: implications for ion interactions, rhizotoxicity, and uptake. International
Journal of Molecular Sciences. 15, 22661-22677.
65. Le TTY, Wang P, Vijver MG, Kinraide TB, Hendriks AJ, and Peijnenburg WJGM. 2014.
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CRRICULUM VITAE_PENG WANG

Delineating ion-ion interactions by electrostatic modeling for predicting rhizotoxicity of metal
mixtures to lettuce Lactuca sativa. Environmental Toxicology and Chemistry. 33, 1988-1995.
66. Blamey FPC, Wehr JB, Wang P, Menzies NW, and Kopittke PM. 2014. Kinetics and mechanisms of
cowpea root adaptation to changes in solution calcium. Plant and Soil. 379, 301-314.
67. Kopittke PM, de Jonge MD, Wang P, McKenna BA, Lombi E, Paterson DJ, Howard DL, James SA, Spiers
KM, Ryan CG, Johnson AAT, and Menzies NW. 2014. Laterally resolved speciation of arsenic in roots
of wheat and rice using fluorescence-XANES imaging. New Phytologist. 201, 1251-1262.
68. Kopittke PM, Wang P, Menzies NM, Naidu R, and Kinraide TB. 2014. A web-accessible computer
program for calculating electrical potentials and ion activities at cell-membrane surfaces. Plant
and Soil. 375, 35-46.
69. Kopittke PM, Menzies NW, Wang P, McKenna BA, Wehr JB, Lombi E, Kinraide TB, and Blamey FPC.
2014. The rhizotoxicity of metal cations is related to their strength of binding to hard ligands.
Environmental Toxicology and Chemistry. 33, 268-277.


2013

70. Wang P*, Menzies NW, Lombi E, McKenna BA, Johannessen B, Glover CJ, Kappen P, and Kopittke PM.
2013. Fate of ZnO nanoparticles in soils and cowpea (Vigna unguiculata). Environmental Science &
Technology. 47, 13822-13830.
71. Wang P*, Menzies NW, Lombi E, McKenna BA, de Jonge MD, Donner E, Blamey FPC, Ryan CG, Paterson
DJ, Howard DL, James SA, and Kopittke PM. 2013. Quantitative determination of metal and metalloid
spatial distribution in hydrated and fresh roots of cowpea using synchrotron- based X-ray
fluorescence microscopy. Science of the Total Environment. 463-464, 131-139.
72. Wang P*, Menzies NW, Lombi E, McKenna BA, de Jonge MD, Paterson DJ, Howard DL, Glover CJ, James
S, Kappen P, Johannessen B, and Kopittke PM. 2013. In situ speciation and distribution of toxic
selenium in hydrated roots of cowpea. Plant Physiology. 163, 407-418.
73. Wang P, Kinraide TB, Smolders E, Zhou DM, Menzies NW, Thakali S, Xia WW, Hao XZ, Peijnenburg W,
and Kopittke PM. 2013. An electrostatic model predicting Cu and Ni toxicity to microbial processes
in soils. Soil Biology and Biochemistry. 57, 720-730.
74. Wang YM, Kinraide TB, Wang P, Zhou DM, and Hao XZ. 2013. Modeling rhizotoxicity and uptake of
Zn and Co singly and in binary mixture in wheat in terms of the cell membrane surface
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CRRICULUM VITAE_PENG WANG

electrical potential. Environmental Science & Technology. 47, 2831-2838.

75. Kopittke PM, Lombi E, McKenna BA, Wang P, Donner E, Webb RI, Blamey FPC, de Jonge MD, Paterson
D, Howard DL, and Menzies NW. 2013. Distribution and speciation of Mn in hydrated roots of cowpea
at levels inhibiting root growth. Physiologia Plantarum. 147, 453-464.


2012

76. Wang P, Menzies N, Wang YM, Zhou DM, Zhao FJ, and Kopittke P. 2012. Identifying the species of
copper that are toxic to plant roots in alkaline nutrient solutions. Plant and Soil. 361, 317-327.
77. Wang P, De Schamphelaere KAC, Kopittke PM, Zhou DM, and Peijnenburg WJGM. 2012. Development of
an electrostatic model predicting copper toxicity to plants. Journal of Experimental Botany. 63,
659-668.
78. Kopittke PM, de Jonge MD, Menzies NW, Wang P, Donner E, McKenna BA, Paterson DJ, Howard DL, and
Lombi E. 2012. Examination of the distribution of arsenic in hydrated and fresh cowpea roots using
two- and three-dimensional techniques. Plant Physiology. 159, 1149-1158.
79. Zhou DM, Jin SY, Wang YJ, Wang P, Weng NY, and Wang Y. 2012. Assessing the impact of iron-based
nanoparticles on pH, dissolved organic carbon, and nutrient availability in soils. Soil & Sediment
Contamination. 21, 101-104.


2011

80. Wang P, Kinraide TB, Zhou DM, Kopittke PM, and Peijnenburg W. 2011. Plasma membrane surface
potential: Dual effects upon ion uptake and toxicity. Plant Physiology. 155, 808-820.
81. Wang P, Kopittke PM, De Schamphelaere KAC, Zhao FJ, Zhou DM, Lock K, Ma YB, Peijnenburg W, and
McGrath SP. 2011. Evaluation of an electrostatic toxicity model for predicting Ni2+ toxicity to
barley root elongation in hydroponic cultures and in soils. New Phytologist. 192, 414-427.
82. Wang P, Zhou DM, Weng NY, Wang DJ, and Peijnenburg W. 2011. Calcium and magnesium enhanced
arsenate rhizotoxicity and uptake in Triticum aestivum. Environmental Toxicology & Chemistry. 30,
1642-1648.
83. Li LZ, Zhou DM, Peijnenburg W, van Gestel CAM, Jin SY, Wang YJ, and Wang P. 2011.
Toxicity of zinc oxide nanoparticles in the earthworm, Eisenia fetida and subcellular fractionation
of Zn. Environment International. 37, 1098-1104.
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CRRICULUM VITAE_PENG WANG

84. Kopittke PM, Kinraide TB, Wang P, Blarney FPC, Reichman SM, and Menzies NW. 2011. Alleviation
of Cu and Pb rhizotoxicities in cowpea (Vigna unguiculata) as related to ion activities at
root-cell plasma membrane surface. Environmental Science & Technology. 45, 4966-4973.
85. Kopittke PM, Blamey FPC, Wang P, and Menzies NW. 2011. Calculated activity of Mn2+ at the
outer surface of the root cell plasma membrane governs Mn nutrition of cowpea seedlings. Journal of
Experimental Botany. 62, 3993-4001.
86. Kopittke PM, Blamey FPC, Kinraide TB, Wang P, Reichman SM, and Menzies NW. 2011. Separating
multiple, short-term, deleterious effects of saline solutions on the growth of cowpea seedlings.
New Phytologist. 189, 1110-1121.
87. Kopittke PM, Blamey FPC, McKenna BA, Wang P, and Menzies NW. 2011. Toxicity of metals to roots
of cowpea in relation to their binding strength. Environmental Toxicology and Chemistry. 30,
1827-1833.
88. Li DD, Zhou DM, Wang P, and Li LZ. 2011. Temperature affects cadmium-induced phytotoxicity
involved in subcellular cadmium distribution and oxidative stress in wheat roots. Ecotoxicology and
Environmental Safety. 74, 2029-2035.
89. Li DD, Zhou DM, Wang P, Weng NY, and Zhu XD. 2011. Subcellular Cd distribution and its
correlation with antioxidant enzymatic activities in wheat (Triticum aestivum) roots. Ecotoxicology
and Environmental Safety. 74, 874-881.
90. Zhou DM, Li LZ, Peijnenburg W, Ownby DR, Hendriks AJ, Wang P, and Li DD. 2011. A QICAR approach
for quantifying binding constants for metal-ligand complexes. Ecotoxicology and Environmental
Safety. 74, 1036-1042.


2010

91. Wang P, Zhou DM, Peijnenburg W, and Li LZ. 2010. Evaluating mechanisms for plant-ion (Ca2+,
Cu2+, Cd2+ or Ni2+) interactions and their effectiveness on rhizotoxicity. Plant and Soil. 344,
277- 288.
92. Wang P, Zhou DM, Li LZ, and Luo XS. 2010. Evaluating the biotic ligand model for toxicity and
the alleviation of toxicity in terms of cell membrane surface potential. Environmental Toxicology
and Chemistry. 29, 1503-1511.
93. Kinraide TB and Wang P. 2010. The surface charge density of plant cell membranes (?): An
attempt to resolve conflicting values for intrinsic ?. Journal of Experimental Botany. 61, 2507-
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CRRICULUM VITAE_PENG WANG

2518.

94. Li LZ, Zhou DM, Peijnenburg W, Wang P, van Gestel CAM, Jin SY, and Wang QY. 2010. Uptake
pathways and toxicity of Cd and Zn in the earthworm Eisenia fetida. Soil Biology & Biochemistry.
42, 1045-1050.


2009

95. Wang P, Zhou DM, Luo XS, and Li LZ. 2009. Effects of Zn-complexes on zinc uptake by wheat
(Triticum aestivum) roots: A comprehensive consideration of physical, chemical and biological
processes on biouptake. Plant and Soil. 316, 177-192.


2008

96. Wang P, Zhou DM*, Kinraide TB, Luo XS, Li LZ, Li DD, and Zhang HL. 2008. Cell membrane surface
potential (?0) plays a dominant role in the phytotoxicity of copper and arsenate. Plant Physiology.
148, 2134-2143.


论文及引用统计数据见：
http://www.researcherid.com/rid/E-2008-2012 (ISI);
https://scholar.google.com.au/citations?user=2vL71yYAAAAJ&hl=en (Google Scholar)
https://www.researchgate.net/profile/Peng_Wang148 (Researchgate)





















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