中国土壤学会会员（2020- ）

中国地理学会会员（2024-）

美国土壤学会会员（2021-）

北京市土壤学会会员（2020-）

农业资源与环境学报青年编委 副主任（2023-）

土壤学报青年编委（2023-）

水土保持学报青年编委（2023-）

Frontier in Soil Science, Applied Sciences 专刊编辑

2024 中国农业大学优秀教师

2023 国家级一流本科课程土壤学 排名4

2022 北京市教育教学成果二等奖“土壤学教材立体改革与创新” 排名3

2022 “大国三农”一流本科课程土壤学 排名4

2022 土地科学与技术学院“优秀共产党员”

2021 全国农业专业学位研究生实践教学成果奖二等奖 排名3

2021 中国农业大学教育教学成果特等奖 排名3

2021 梨树模式呵护“耕地中的大熊猫”入选自然资源部和世界自然保护联盟基于自然的解决方案中国典型案例十大案例之一 排名2

2019、2020、2023 梨树县优秀专家

一、发表论文

2024年

1.Peng, Y., Niu, L., Hu, Y., Huo, C., Shi, J., Fan, Z., Yan, Y., Zhang, Z. and Wang, X*., 2024. Long-term effects of nitrogen and phosphorus fertilization on profile distribution and characteristics of dissolved organic matter in fluvo-aquic soil. Journal of Environmental Management, 366, 121834.

2.Xiao, C., Ji, N., Wang, P, He J., Wang X., *, Li, L, *(2024). Crop diversity significantly enhances soil carbon sequestration via alleviating soil inorganic carbon decline by rhizobia inoculation, Soil and Tillage Research.

3.Shi, J.#, Lv, J.#, Peng, Y., Yao, Y., Wei, X., & Wang, X*. (2024). Mechanisms controlling the stability and sequestration of mineral associated organic carbon upon erosion and deposition. Catena, 242, 108119.

4.Wang, Z., Peng, Y., Lv, J., Shi, J., Shang, J., & Wang, X*. (2024). Effects of erosion on macroaggregation, aggregate associated organic carbon sources and compositions in a Mollisol agricultural landscape. Catena, 240, 107994.

5.Peng, Y#., Xu, H.#, Shi, J., Wang, Z., Lv, J., Li, L., & Wang, X*. (2024). Soil microbial composition, diversity, and network stability in intercropping versus monoculture responded differently to drought. Agriculture, Ecosystems & Environment, 365, 108915.

6.Xie, J., Gao, J., Cao, H., Li, J., Wang, X., Zhang, J., ... & Xu, M. (2024). Calcium carbonate promotes the formation and stability of soil macroaggregates in mining areas of China. Journal of Integrative Agriculture, 23(3), 1034-1047.

7.Wang, Z., Shi, J., Peng, Y., & Wang, X*. (2024). Deposition of eroded soil significantly increases bacterial community diversity and soil multifunctionality in a Mollisol agricultural ecosystem. Ecological Indicators, 159, 111660.

8.Sun, Y., Wu, M., Xie, S., Zang, J., Wang, X*., Yang, Y., Li, C. & Wang, J*. (2024). Homogenization of bacterial plastisphere community in soil: a continental-scale microcosm study. ISME communications, 4(1), ycad012.

9.Wang, Y., Yin, Y., Joseph, S., Flury, M., Wang, X., Tahery, S., Li, B. and Shang, J.*, 2024. Stabilization of organic carbon in top-and subsoil by biochar application into calcareous farmland. Science of The Total Environment, 907, 168046.

10.Gou, X., Hu, Y., Ni, H., Wang, X., Qiu, L., Chang, X., Shao, M, Wei, G& Wei, X*. (2024). Arbuscular mycorrhizal fungi alleviate erosional soil nitrogen loss by regulating nitrogen cycling genes and enzymes in experimental agro-ecosystems. Science of The Total Environment, 906, 167425.

11.Wang, Z., Pan, S., Lv, J., Peng, Y., Shi, J., & Wang, X*. (2024). Erosion and deposition controlling redistribution and biodegradation of nitrogen fractions along a Mollisol agricultural landscape. Journal of Soils and Sediments, 1-12.

12.石佳,王祥,汪杰*. 微塑料介导的土壤碳循环:微塑料对土壤有机碳的形成，矿化和稳定过程的影响, 中国科学：技术科学.

13.李玮，尹广生，陈冲，彭钰梅，商建英，王祥*. 秸秆及其配施对黄灌区盐碱土壤团聚体结构、持水及收缩特性的影响. 农业资源与环境学报.

14.尹广生,李玮,彭钰梅,陈冲,商建英,王祥*.秸秆及其配施有机物料对黄灌区盐碱土淋洗效果的影响.农业环境科学学报:1-11.

2023年：

1.Shi, J., Wang, Z., Peng, Y., Fan, Z., Zhang, Z., Wang, X*., Zhu, K., Shang, J. and Wang, J.*, 2023. Effects of microplastics on soil carbon mineralization: the crucial role of oxygen dynamics and electron transfer. Environmental Science & Technology, 57(36), 13588-13600.

2.Wang, Z., Zhang, C., Pan, S., Shang, J., & Wang, X*. (2023). Responses of molecular composition and biodegradation of dissolved organic matter to erosion in topsoil versus subsoil in a Mollisol agricultural ecosystem. Agriculture, Ecosystems & Environment, 354, 108569.

3.Lv, J.,# Shi, J.,# Wang, Z., Peng, Y., & Wang, X*. (2023). Effects of erosion and deposition on the extent and characteristics of organic carbon associated with soil minerals in Mollisol landscape. CATENA, 228, 107190.

4.Ding, X., Li, G., Zhao, X., Lin, Q. and Wang, X*., 2023. Biochar application significantly increases soil organic carbon under conservation tillage: an 11-year field experiment. Biochar, 5(1), pp.1-14.

5.Shi, J., Wang, Z., Peng, Y., Zhang, Z., Fan, Z., Wang, J., & Wang, X.* (2023). Microbes drive metabolism, community diversity, and interactions in response to microplastic-induced nutrient imbalance. Science of The Total Environment, 162885.

6.Pan, S., Shi, J., Peng, Y., Wang, Z., & Wang, X.* (2023). Soil organic carbon pool distribution and stability with grazing and topography in a Mongolian grassland. Agriculture, Ecosystems & Environment, 348, 108431.

7.Peng, Y., Xu, H., Wang, Z., Shi, J., Lv, J., & Wang, X. * (2023). Responses of the content and spectral characteristics of dissolved organic matter in intercropping soil to drought in northeast China. Plant and Soil, 1-15.

8.Wang, Y., Joseph, S., Wang, X., Weng, Z.H., Mitchell, D.R., Nancarrow, M., Taherymoosavi, S., Munroe, P., Li, G., Lin, Q. Chen, Q., …… Li, B., & Shang, J*,2023. Inducing inorganic carbon accrual in subsoil through biochar application on calcareous topsoil. Environmental Science & Technology, 57(4),.1837-1847.

9.Zhang, Y., Chen, A., Wang, Z., Wang, X., Lin, Y., & Ye, C. (2023). Soil organic carbon accumulation along a chronosequence of vegetation colonization on debris flow fans in Southwest China. Catena, 223, 106936.

10.Mao, N., Wang, X.*, & Wei, X*. (2023). Earthworms regulate plants’ effects on soil microbial nutrient limitations: Examinations with contrasting soils and moisture. Journal of Environmental Management, 329, 117061.

11.Peng, Y.#, Xu, H#., Wang, Z., Li, L., Shang, J., Li, B., & Wang, X.* (2023). Effects of intercropping and drought on soil aggregation and associated organic carbon and nitrogen. Soil Use and Management, 39(1), 316-328.

12.Zhao, K., Wang, X., Li, B., & Shang, J. (2023). The roles of Fe oxyhydroxide coating and chemical aging in pyrogenic carbon nanoparticle transport in unsaturated porous media. Environmental Pollution, 317, 120776.

13.Wang, M., Li, F., Dong, L., Wang, X., Han, L., & Olesen, J. E. (2023). Effects of exogenous organic/inorganic nitrogen addition on carbon pool distribution and transformation in grassland soil. Science of The Total Environment, 858, 159919.

14.Li, Q., Zhang, X., Mao, M., Wang, X. & Shang, J., 2023. Carbon content determines the aggregation of biochar colloids from various feedstocks. Science of The Total Environment, 880, p.163313.

15.Wang, Y., Lin, Q., Liu, Z., Liu, K., Wang, X. and Shang, J., 2023. Salt-affected marginal lands: a solution for biochar production. Biochar, 5(1), p.21.

16.尹广生, 王祥*, 陈冲, 等. 暗管排水技术治理盐碱地的研究进展[J]. 灌溉排水学报, 2022, 41(Supp.2): 45-51

17.李玮，尹广生，李琪瑞，王洋，商建英，王祥*.不同改良措施对黄河南岸灌区盐碱土壤 理化性质及团聚体特征的影响

2022年：

1.Sun, Y., Shi, J., Wang, X*., Ding, C., & Wang, J*. (2022). Deciphering the mechanisms shaping the plastisphere microbiota in soil. mSystems, 7(4), e00352-22.

2.Qin, X., Zhu, H., Ren, Y., Cao, Z., Wang, X., Zhao, Z., ... & Wei, X. (2022). Erosion intensity and check dam size affect the horizontal and vertical distribution of soil particles, carbon and nitrogen: Evidence from China’s Loess Plateau. Catena, 217, 106451.

3.Shi, J., Wang, J., Lv, J., Wang, Z., Peng, Y., & Wang, X.* (2022). Microplastic presence significantly alters soil nitrogen transformation and decreases nitrogen bioavailability under contrasting temperatures. Journal of Environmental Management, 317, 115473.

4.Kong, W., Yao, Y., Hou, L., Wang, X., & Wei, X. (2022). Site and landscape position-dependent effects of vegetation removal on soil nitrogen mineralization across five sites on China’s Loess Plateau. Catena, 215, 106336.

5.Shi, J., Wang, J., Lv, J., Wang, Z., Peng, Y., Shang, J., & Wang, X.* (2022). Microplastic additions alter soil organic matter stability and bacterial community under varying temperature in two contrasting soils. Science of the Total Environment, 838, 156471

6.Shi, J., Sun, Y., Wang, X*., & Wang, J*. (2022). Microplastics reduce soil microbial network complexity and ecological deterministic selection. Environmental Microbiology, 24(4), 2157-2169.

7.Zhao, K., Tufail, S., Arai, Y., Sharma, P., Zhang, Q., Chen, Y., ...Wang, X. & Shang, J. (2022). Effect of phytic acid and morphology on Fe (oxyhydr) oxide transport under saturated flow condition. Journal of Hazardous Materials, 424, 127659.

8.Wang, X., Wackett, A. A., Toner, B. M., & Yoo, K.* (2022). Consistent mineral-associated organic carbon chemistry with variable erosion rates in a mountainous landscape. Geoderma, 405, 115448.

9.Ding, S., Li, C., Ding, X., Li, G., Ban, G., Xia, Z., ... & Wang, X.* (2022). An exploration of manure derived N in soils using 15N after the application of biochar, straw and a mix of both. Science of the Total Environment, 804, 150239.

10.Xu, G., Chen, C*., Shen, C., Zhou, H., Wang, X., Cheng, T., & Shang, J. (2022). Hydrogen peroxide and high-temperature heating differently alter the stability and aggregation of black soil colloids. Chemosphere, 287, 132018.

2021年：

1.Chen, C., Arthur, E., Tuller, M., Zhou, H., Wang, X., Shang, J., ... & Ren, T. (2021). Estimation of soil specific surface area from adsorbed soil water content. European Journal of Soil Science, 72(4), 1718-1725..

2.Cao, H. B., Xie, J. Y., Jie, H. O. N. G., Wang X., Wei, H. U., & Hong, J. P. (2021). Organic matter fractions within macroaggregates in response to long-term fertilization in calcareous soil after reclamation. Journal of Integrative Agriculture, 20(6), 1636-1648.

3.Qiu, L., Zhu, H., Liu, J., Yao, Y., Wang, X., Rong, G., ... & Wei, X. (2021). Soil erosion significantly reduces organic carbon and nitrogen mineralization in a simulated experiment. Agriculture, Ecosystems & Environment, 307, 107232.

4.Sun, Z*., Qin, W., Wang, X., Zhang, Y., Li, G., & Wang, Z*. (2021). Effects of manure on topsoil and subsoil organic carbon depend on irrigation regimes in a 9-year wheat-maize rotation. Soil and Tillage Research, 205, 104790.

5.Zhang, H., Niu, L. A.*, Hu, K., Hao, J., Li, F., Wang, X.*, & Chen, H. (2021). Long‐term effects of nitrogen and phosphorus fertilization on soil aggregate stability and aggregate‐associated carbon and nitrogen in the North China Plain. Soil Science Society of America Journal, 85(3), 732-745.

6.Chen, A., Wang, Z*., Lin, Y., Wang, X., Li, Y., Zhang, Y., ... & Tang, G. (2020). Temporal variation of soil organic carbon pools along a chronosequence of reforested land in Southwest China. Catena, 194, 104650.

7.Chen, C*., Arthur, E., Zhou, H., Wang, X., Shang, J., Hu, K., & Ren, T. (2021). A new model for soil water vapor sorption isotherms considering adsorption and condensation. Soil Science Society of America Journal, 85(2), 195-206

8.Wang, L., Yen, H., Wang, X., Huang, C. H., Sun, J., Hammac, A., & Wang, Y*. (2021). Deposition-and transport-dominated erosion regime effects on the loss of dissolved and sediment-bound organic carbon: Evaluation in a cultivated soil with laboratory rainfall simulations. Science of the Total Environment, 750, 141717.

2020年：

1.Zhang, H., Niu, L. A.*, Hu, K., Hao, J., Li, F., Gao, Z., & Wang, X*. (2020). Influence of tillage, straw-returning and mineral fertilization on the stability and associated organic content of soil aggregates in the North China Plain. Agronomy, 10(7), 951.

2.Zhu, S., Wang, S., Yang, X., Tufail, S., Chen, C., Wang, X., & Shang, J*. (2020). Green sustainable and highly efficient hematite nanoparticles modified biochar-clay granular composite for Cr (VI) removal and related mechanism. Journal of Cleaner Production, 276, 123009.

3.Wang, X.*, Cammeraat, E. L., & Kalbitz, K. (2020). Erosional effects on distribution and bioavailability of soil nitrogen fractions in Belgian Loess Belt. Geoderma, 365, 114231..

4.Zhu, L., Tong, L., Zhao, N., Wang, X., Yang, X., & Lv, Y.* (2020). Key factors and microscopic mechanisms controlling adsorption of cadmium by surface oxidized and aminated biochars. Journal of Hazardous Materials, 382, 121002.

2019年：

1.Wang, X., Toner, B. M., & Yoo, K*. (2019). Mineral vs. organic matter supply as a limiting factor for the formation of mineral-associated organic matter in forest and agricultural soils. Science of the Total Environment, 692, 344-353.

2.Yao, Y., Ge, N., Yu, S., Wei, X*., Wang, X., Jin, J., ... & Kang, L. (2019). Response of aggregate associated organic carbon, nitrogen and phosphorous to re-vegetation in agro-pastoral ecotone of northern China. Geoderma, 341, 172-180..

3.Yao, Y., Shao, M., Fu, X., Wang, X., & Wei, X.* (2019). Effect of grassland afforestation on soil N mineralization and its response to soil texture and slope position. Agriculture, Ecosystems & Environment, 276, 64-72..

4.Jia, X#., Wang, X#., Hou, L., Wei, X.*, Zhang, Y., Shao, M. A., & Zhao, X. (2019). Variable response of inorganic carbon and consistent increase of organic carbon as a consequence of afforestation in areas with semiarid soils. Land Degradation & Development, 30(11), 1345-1356.

5.Yao, Y., Shao, M., Fu, X., Wang, X., & Wei, X*. (2019). Effects of shrubs on soil nutrients and enzymatic activities over a 0–100 cm soil profile in the desert-loess transition zone. Catena, 174, 362-370.

6.Zhao, Z., Wei, X*., Wang, X., Ma, T., Huang, L., Gao, H., ... & Jia, X. (2019). Concentration and mineralization of organic carbon in forest soils along a climatic gradient. Forest Ecology and Management, 432, 246-255.

7.Ge, N., Wei, X.*, Wang, X., Liu, X., Shao, M., Jia, X., ... & Zhang, Q. (2019). Soil texture determines the distribution of aggregate-associated carbon, nitrogen and phosphorous under two contrasting land use types in the Loess Plateau. Catena, 172, 148-157.

8.Fu, W., Wang, X., & Wei, X*. (2019). No response of soil N mineralization to experimental warming in a northern middle-high latitude agro-ecosystem. Science of the Total Environment, 659, 240-248.

9.Wang, X., Jelinski, N. A., Toner, B., & Yoo, K*. (2019). Long-term agricultural management and erosion change soil organic matter chemistry and association with minerals. Science of the total environment, 648, 1500-1510.

2018年：

1.Wang, X., Sanderman, J., & Yoo, K*. (2018). Climate-dependent topographic effects on pyrogenic soil carbon in southeastern Australia. Geoderma, 322, 121-130.

2.Wang, X., Yoo, K*., Wackett, A. A., Gutknecht, J., Amundson, R., & Heimsath, A. (2018). Soil organic carbon and mineral interactions on climatically different hillslopes. Geoderma, 322, 71-80.

3.Eger, A*., Yoo, K., Almond, P.C., Boitt, G., Larsen, I.J., Condron, L.M., Wang, X. and Mudd, S.M., 2018. Does soil erosion rejuvenate the soil phosphorus inventory?. Geoderma, 332, 45-59.

4.Liu, J., Qiu, L*., Wang, X., Wei, X., Gao, H., Zhang, Y., & Cheng, J. (2018). Effects of wildfire and topography on soil nutrients in a semiarid restored grassland. Plant and soil, 428, 123-136..

5.Wang, X., Yoo, K.*, Mudd, S. M., Weinman, B., Gutknecht, J., & Gabet, E. J. (2018). Storage and export of soil carbon and mineral surface area along an erosional gradient in the Sierra Nevada, California. Geoderma, 321, 151-163

2017年：

1.Wei, X*., Wang, X., Ma, T., Huang, L., Pu, Q., Hao, M., & Zhang, X. (2017). Distribution and mineralization of organic carbon and nitrogen in forest soils of the southern Tibetan Plateau. Catena, 156, 298-304.

2016年：

1.Gao, J.*, Helmus, R., Cerli, C., Jansen, B., Wang, X., & Kalbitz, K. (2016). Robust analysis of underivatized free amino acids in soil by hydrophilic interaction liquid chromatography coupled with electrospray tandem mass spectrometry. Journal of Chromatography A, 1449, 78-88.

2015年：

1.Li, F., Wang, Z., Dai, J., Li, Q., Wang, X., Xue, C., Liu, H. and He, G., 2015. Fate of nitrogen from green manure, straw, and fertilizer applied to wheat under different summer fallow management strategies in dryland. Biology and Fertility of Soils, 51, 769-780.

2014年：

1.Wang, X*., Cammeraat, E.L., López, C.D. and Kalbitz, K., 2014. Mineralization of eroded organic carbon transported from a loess soil into water. Soil Science Society of America Journal, 78(4), 1362-1367.

2.Wang, X.*, Cammeraat, E.L., Romeijn, P. and Kalbitz, K., 2014. Soil organic carbon redistribution by water erosion–the role of CO2 emissions for the carbon budget. PLoS One, 9(5), p.e96299.

3.Wang, X.*, Cammeraat, E.L., Cerli, C. and Kalbitz, K., 2014. Soil aggregation and the stabilization of organic carbon as affected by erosion and deposition. Soil Biology and Biochemistry, 72, 55-65.

4.Li, F., Wang, Z*., Dai, J., Li, Q., Xue, C., Zhao, H., Wang, X. and Olesen, J.E., 2014. Summer fallow soil management–impact on rainfed winter wheat. Acta Agriculturae Scandinavica, Section B—Soil & Plant Science, 64(5), 398-407.

2013年：

1.Wang, X.*, Cammeraat, L.H., Wang, Z., Zhou, J., Govers, G. and Kalbitz, K., 2013. Stability of organic matter in soils of the Belgian Loess Belt upon erosion and deposition. European Journal of Soil Science, 64(2), pp.219-228.

2011年：

1.王春阳, 周建斌, 王祥, 夏志敏. 黄土高原区不同植物凋落物可溶性有机碳的含量及生物降解特性. 环境科学, 2011, 32(04): 1139-1145.

2010年：

1.高忠霞, 杨学云, 周建斌, 王祥, 王宏. 小麦-玉米轮作期间不同施肥处理氮素的淋溶形态及数量. 农业环境科学学报, 2010, 29(08): 1624-1632.

2.王祥， 王春阳， 周建斌.黄土高原水蚀风蚀交错带几种常见植物凋落物中不同形态氮素含量研究. 西北农林科技大学学报: 自然科学版. 105-111.

二、授权专利

1.陈冲,王祥,商建英. 基于暗管改良粘质盐碱土的地基结构. Zl02223428288.1

2.李伟;田慧慧;王亦波;高建伦;王祥;魏孝荣;拓行行,侯灵操. 一种退化坡草地播种用土壤疏松装置. ZL 2023 2 3079321.9

三、软件著作权

1．沈海鸥, 王祥, 侯文峰, 张月, 杨帆. 草地植被防蚀性效果测试数据评估系统. 登记号: 2024SR0016503. 2024-01-03.

四、技术标准

1.黄河灌区高标准农田盐碱地改良效果综合评价方法（DB15/T 3586-2024）. 主持

2.黄河灌区轻中度盐碱耕地建设高标准农田技术规程（DB15/T 3583-2024）. 主持

3.黄河灌区玉米秸秆促腐还田培肥地力技术规程（DB15/T 3582-2024）. 参与

4.黄河灌区智慧农业物联网设备通信规约（DB15/T 3588-2024）. 参与

5.黄河灌区农田排水种养循环利用技术规程（DB15/T 3584-2024）. 参与

6.黄河灌区黄河水喷滴灌水质处理技术规程（DB15/T 3574-2024）. 参与

7.黄河灌区高标准农田多元快速培肥技术规程参与（DB15/T 3581-2024）. 参与

8.黄河灌区暗管明沟结合排水排盐技术规程（DB15/T 3578-2024）. 参与

五、出版著作

1.土壤学（第二版）. 中国农业出版社, 2020, 参编.