个人简介：

张海洋，男，1987年生，山东济宁人，博士，教授，博士生导师。

电子邮箱：zhanghy@hbu.edu.cn

教育经历：

2009.09–2015.07 博士，中国科学院沈阳应用生态研究所

2005.09–2009.07 学士，山东农业大学

工作经历：

2025.11–至今 教授，河北大学

2023.03–2025.11 校聘研究员，河北大学

2017.04–2023.01 项目研究员，澳大利亚西悉尼大学环境研究所

2015.10–2017.04 博士后，德国马普生物地球化学研究所

科研领域：植物微生物互作与全球变化

长期从事生态系统养分循环研究，聚焦菌根真菌生态学，重点关注以微生物功能性状为核心的植物-微生物互作机制。迄今在国内外学术期刊发表论文64篇，其中以第一作者或通讯作者身份发表论文25篇。代表性成果发表于Science、Ecology Letters、Trends in Microbiology、Ecology 和 New Phytologist等期刊。其研究成果被引用1900余次，H指数为27。担任 Functional Ecology和Plant and Soil 副主编；同时为 Science Advances、Nature Communications、Ecology Letters 等二十余种期刊审稿人。主持国家自然科学基金面上项目、河北省杰出青年科学基金项目及教育部海外引才项目等多项科研课题。

招生方向：生态学、资源利用与植物保护

欢迎生态学、植物学、土壤学、微生物学、昆虫学及相关专业学生报考。课题组聚焦植物-微生物互作与全球变化生态学研究，结合野外观测、控制实验、室内培养、分子生物学、生物信息学和稳定同位素等技术手段，探索生态系统养分循环及生物互作机制。欢迎具有相关研究背景或浓厚科研兴趣的学生加入课题组。

科研项目：

1. 国家自然科学基金面上项目：基因组大小对豆科植物共生固氮的调控机制，50万元，2024–2027，主持。

2. 河北省杰出青年科学基金项目：丛枝菌根真菌功能性状与资源利用策略，50万元，2024–2026，主持。

3. 教育部第2批博士后海外引才专项：草地共生微生物功能性状研究，90万元，2025–2027，主持。

4. 澳洲草地对极端气候变化的响应，2017–2020，项目骨干。合作导师：Prof. Ian Anderson、Prof. Sally Powell、Prof. Elise Pendall、Prof. David Tissue。

5. 澳大利亚—德国柏林自由大学短期交流项目：全球真菌孢子性状数据库构建与整合，2019–2024，项目骨干。合作导师：Prof. Ian Anderson、Prof. Matthias Rillig、Dr. Carlos Aguilar-Trigueros。

6. 丛枝菌根真菌养分计量和孢子性状研究，2020–2024，项目骨干。合作导师：Prof. Jeff Powell、Prof. Matthias Rillig。

7. 中德（CSC-DAAD）博士后奖学金项目：末次冰期低二氧化碳浓度下C3植物及其生物标识物的碳－氢－氧同位素分馏与古气候重建，2015–2017，主持。

德国马普协会与中国科学院公派项目：植物与菌根真菌之间的碳氮传递——氮素利用与同位素分馏，2012–2014，主持。

近五年代表作：

1．Ohlert, T., Smith, M., Collins, S., Knapp, A., Dukes, J., Sala, O., Wilkins, K., Munson, S., Anderson, M., Avolio, M., Chen, A., Hayden, M., Holdrege, M., et al., Zhang, H., Zhu, J. & Zuo, X. (2025). Drought intensity and duration interact to magnify losses in primary productivity. Science, 390(6770): 284-289.中科院一区，IF = 44.7

2．Liu, L., Yang, J., Wang, J., Yu, Q., Wei, C., Jiang, L., Huang, J., Zhang, Y., Jiang, Y., Zhang, H*. & Han, X. (2025). Increase in mineral-associated organic carbon does not offset the decrease in particulate organic carbon under long-term nitrogen enrichment in a steppe ecosystem. Soil Biology and Biochemistry, 202: 109695. 中科院一区，IF = 10.3

3．Zhang, X., Bo, Y., Jiang, L., Wang, J., Yu, L., Fu, W., He, X., Dong, X., Han, X. & Zhang, H*. (2025). Mycelium biomass and community composition impact nutrient concentration in arbuscular mycorrhizal fungi at fine spatial scale. Functional Ecology, 39: 1455–1468. 中科院一区，IF = 5.1

4．Jiang, L., Wang, J., Yang, G., Ning, Q., Wang, Y., Li, S., Yu, L., Liu, H., Lü, X., Jiang, Y., Han, X., Wei, C. & Zhang, H*. (2025). Labile carbon input alleviates nitrogen-induced community instability in a meadow steppe. Journal of Ecology, 113: 742–752. 中科院一区，IF = 5.6

5．Zhang, H., Liu, H. & Han, X. (2024). Traits-based approach: Leveraging genome size in plant–microbe interactions. Trends in Microbiology, 32(4): 333–341. 中科院一区，IF = 14.9

6．Namuhan., Wang, J., Yang, G., Song, Y., Yu, Y., Wang, J., Wang, X., Shi, Y., Shen, Y., Han, X., Wuyunna*. & Zhang, H*. (2024). Mechanisms of biodiversity loss under nitrogen enrichment: Unveiling a shift from light competition to cation toxicity. New Phytologist, 243: 1966–1979. 中科院一区，IF = 8.1

7．Zhang, H*., Bissett, A., Aguilar-Trigueros, C. A., Liu, H. & Powell, J. R. (2023). Fungal genome size and composition reflect ecological strategies along soil fertility gradients. Ecology Letters, 26: 1108–1118. 中科院一区，IF = 7.9

8．Zhang, H*., Churchill, A. C., Anderson, I. C., Igwenagu, C., Power, S. A., Plett, J. M., Macdonald, C. A., Pendall, E., Carrillo, Y. & Powell, J. R. (2023). Ecological stoichiometry and fungal community turnover reveal variation among mycorrhizal partners in their responses to warming and drought. Molecular Ecology, 32: 229–243. 中科院一区，IF = 4.8

9．Zhang, H*., Lü, X., Wei, C., Powell, J. R., Wang, X., Xing, D., Xu, Z., Li, H. & Han, X. (2021). β-diversity in temperate grasslands is driven by stronger environmental filtering of plant species with large genomes. Ecology, 105: e3941. 中科院一区，IF = 5.2

其他论文

1．Li, S., Zhang, H*., Wang, J., Jiang, L., Yang, G., Zhang, Y., Wei, C. & Han, X. (2026). Nitrogen addition enhances phytolith-occluded carbon accumulation across particulate and mineral-associated organic matter fractions in a meadow steppe. Geoderma, 471: 117875. 中科院一区，IF = 7.3

2．Namuhan, Song, Y., Guo, T., Shi, Y., Loreau, M., Wuyunna & Zhang, H. (2026). Complementarity promotes overyielding in grass-legume intercropping. Agronomy for Sustainable Development. 中科院一区，IF = 6.7

3．Liu, Y., Wang, Y., Yan, K., Wu, J., Yin, Q., Yang, J., Wang, Y., Jiang, L., Zhang, H., Sun, O. J., Jiang, Y., Han, X. & Wang, J. (2026). Elevated silicon concentrations accelerate decomposition of the dominant silicon-rich grass litter in grassland ecosystems. Soil and Tillage Research. 中科院一区，IF = 6.8

4．Liu, Y., Wu, J., Wang, Y., Yang, J., Zhang, H., Wei, L., Yin, Q., Wang, Y., Wang, X., Jiang, L., Jiang, Y., Han, X. & Wang, J. (2026). Divergent chemistry and microbiology, convergent carbon fate: insect frass and plant litter are functionally equivalent under climate warming. Soil Biology and Biochemistry, 218: 110159. 中科院一区，IF = 10.3

5．Fu, W., Xu, C., Yu, Q., Han, X., Zhang, H. & Chen, B*. (2026). Beyond plant diversity: plant productivity responses to extreme drought are linked to arbuscular mycorrhizal fungal diversity. Global Change Biology, 32(1): e70697. 中科院一区，IF = 12.0

6．Liu, H., Martins, C., Zhou, G., Jayaramaiah, R., Zhang, H., Li, J., Singh, P., Yan, Z., Wang, J., Reich, P., Eisenhauer, N., Delgado-Baquerizo, M. & Singh, B. (2026). Soil protist diversity and biotic interactions shape ecosystem functions under climate change. Global Change Biology, 32(1): e70692. 中科院一区，IF = 12.0

7．Lü, R., Han, X., Su, J., Su, J., Wang, J., Yu, L., Lü, X., Yang, G., Jiang, L., Zhang, H. & Wei, C*. (2026). Divergent plant and nematode community responses to long-term nitrogen enrichment in a meadow steppe. Ecological Applications, 36(1): e70173. 中科院一区，IF = 4.3

8．Yu, J., Wu, S., Ye, J., Mo, Y., Zhao, Y., Zhang, J., Li, J., Zhang, Y., Wu, X., Jiang, L., Yang, G., Lü, X., Zhang, H., Han, X., Li, Z. & Bao, Y*. (2026). Nitrogen saturation drives shifts in response patterns of non-structural carbohydrate pools in a meadow steppe after ceasing nitrogen addition. Frontiers in Plant Science, 17: 1792060. 中科院二区，IF = 4.8

9．Zhang, Y., Ding, Z., Guo, X., Tang, Z., Zhang, H., Wang, J., Wang, R., Liu, S., Han, X., Jiang, Y. & Liu, H*. (2026). Partitioning soil carbon emissions in a temperate oak forest: insights from metabolic theory and the role of fine roots and microbial biomass. Journal of Forestry Research, 37(1): 15. 中科院一区，IF = 4.6

10．陈保冬*，仇云鹏，张海洋. (2026). 中国菌根生态学研究前沿与展望. 植物生态学报.

11．Yin, Q., Liu, Y., Li, J., Wu, J., Wang, Y., Zhang, H., Liu, H., Jiang, L., Yang, J., Wang, Y., Jiang, Y., Han, X. & Wang, J. (2025). Soil organic carbon formation in grassland ecosystems: Higher efficiency of roots than shoots and rhizodeposition. Soil and Tillage Research, 250: 106523. 中科院一区，IF = 6.8

12．Lü, J., Wang, R*., Deng, H., Ma, W., Peñuelas, J., Zhang, H., Bi, M., Jiang, L., Sardans, J., Han, X. & Jiang, Y. (2025). To converge or diverge? Phenological shifts driven by plant genome size and functional traits under nitrogen deposition and mowing. Functional Ecology. 中科院一区，IF = 5.1

13．Zhang, H*., Weinberger, N. & Powell, J. (2025). Functional diversity of arbuscular mycorrhizal fungi drives divergent plant resource allocation strategies under nitrogen limitation. Journal of Experimental Botany: eraf459. 中科院二区，IF = 5.7

14．Yan, K., Xia, W., Yu, K., Yang, X., Wang, X., Wang, J., Zhou, Y., Jing, X., Zhang, H., Jiang, Y., Han, X. & Yu, L. (2025). Grazing disrupts the trade-off between silica- and phenol-based plant defences along an aridity gradient in grasslands. Functional Ecology, 39(11): 2457-2469. 中科院一区，IF = 5.1

15．Wang, X., Xia, W., Yan, K., Yu, K., Wang, J., Yang, X., Zhou, Y., Zhang, H., Jiang, L., Han, X., Sun, O., Jiang, Y. & Yu, L*. (2025). Differential impacts of nitrogen compounds on soil phosphatase activity in a meadow steppe. Ecological Processes, 14: e28. 中科院二区，IF = 3.7

16．Jiang, L., Cheng, H., Peng, Y., Sun, T., Gao, Y., Wang, R., Ma, Y., Yang, J., Yu, Q., Zhang, H., Han, X. & Ning, Q. (2024). Relative role of soil nutrients vs. carbon availability on soil carbon mineralization in grassland receiving long-term N addition. Soil and Tillage Research, 235: 105864. 中科院一区，IF = 7.3

17．Liu, H., Zhang, H*., Powell, J., Delgado-Baquerizo, M., Wang, J. & Singh, B. (2023). Warmer and drier ecosystems select for smaller bacterial genomes in global soils. iMeta, 2(1): e70.中科院一区，IF = 23.8

18．Aguilar-Trigueros, C., Krah, F., Cornwell, W., Zanne, A., Abrego, N., Anderson, I., Andrew, C., Baldrian, P., Bässler, C., Bissett, A., Chaudhary, B., Chen, B., Chen, Y., Delgado-Baquerizo, M., Deveautour, C., Egidi, E., Flores-Moreno, H., Golan, J., Heilmann-Clausen, J., Hempel, S., Hu, Y., Kauserud, H., Kivlin, S., Kohout, P., Lammel, D., Maestre, F., Pringle, A., Purhonen, J., Singh, B., Veresoglou, S., Větrovský, T., Zhang, H., Rillig, M. & Powell, J. (2023). Symbiotic status alters fungal eco-evolutionary offspring trajectories. Ecology Letters, 26(9): 1523-1534. 中科院一区，IF = 9.8

19．Su, J., Zhang, H., Han, X., Lv, R., Liu, L., Jiang, Y., Li, H., Kuzyakov, Y. & Wei, C. (2023). 5300-year-old soil carbon is less primed than young soil organic matter. Global Change Biology, 29(1): 260-275. 中科院一区，IF = 13.1

20．He, P., Ling, N., Lv, X., Zhang, H., Wang, C., Wang, R., Wei, C., Yao, J., Wang, X., Han, X. & Nan, Z. (2023). Contributions of abundant and rare bacteria to soil multifunctionality depend on aridity and elevation. Applied Soil Ecology, 188: 104881. 中科院一区，IF = 5.1

21．Liu, H., Wang, J., Delgado-Baquerizo, M., Zhang, H., Li, J. & Singh, B. (2023). Crop microbiome responses to pathogen colonisation regulate the host plant defence. Plant and Soil, 488: 393-410. 中科院一区，IF = 5.4

22．Chandregowda, M., Tjoelker, M., Pendall, E., Zhang, H., Churchill, A. & Power, S. (2023). Belowground carbon allocation, root trait plasticity, and productivity during drought and warming in a pasture grass. Journal of Experimental Botany, 74(6): 2127-2145. 中科院一区，IF = 8.0

23．Churchill, A., Zhang, H., Fuller, K., Amiji, B., Anderson, I., Barton, C., Carrillo, Y., Catunda, K., Chandregowda, M., Igwenagu, C., Jacob, V., Kim, G., Macdonald, C., Medlyn, B., Moore, B., Pendall, E., Plett, J., Post, A., Powell, J., Tissue, D., Tjoelker, M. & Power, S. (2022). Pastures and Climate Extremes: Impacts of cool season warming and drought on the productivity of key pasture species in a field experiment. Frontiers in Plant Science, 13: 836968. 中科院一区，IF = 7.255

24．Su, J., Zhang, H., Han, X., Peñuelas, J., Filimonenko, E., Jiang, Y., Kuzyakov, Y. & Wei, C. (2022). Low carbon availability in paleosols nonlinearly attenuates temperature sensitivity of soil organic matter decomposition. Global Change Biology, 28(13): 4180-4193. 中科院一区，IF = 13.1

25．Jacob, V., Choat, B., Churchill, A., Zhang, H., Barton, C., Krishnananthaselvan, A., Post, A., Power, S., Medlyn, B. & Tissue, D. (2022). High safety margins to drought-induced hydraulic failure found in five pasture grasses. Plant, Cell and Environment, 45(6): 1631-1646. 中科院一区，IF = 8.5

26．Catunda, K., Churchill, A., Zhang, H., Power, S. & Moore, B. (2022). Short-term drought is a stronger driver of plant morphology and nutritional composition than warming in two common pasture species. Journal of Agronomy and Crop Science, 208(6). 中科院三区，IF = 4.9

27．Chandregowda, M., Tjoelker, M., Pendall, E., Zhang, H., Churchill, A. & Power, S. (2022). Root trait shifts towards an avoidance strategy promote productivity and recovery in C3 and C4 pasture grasses under drought. Functional Ecology, 36: 1754-1771. 中科院一区，IF = 6.6

28．Zhang, H., Powell, J., Power, S., Churchill, A., Plett, J., Macdonald, C., Jacob, V., Kim, G., Pendall, E., Tissue, D., Catunda, K., Igwenagu, C., Carrillo, Y., Moore, B. & Anderson, I. (2021). Arbuscular mycorrhizal fungal-mediated reductions in N2O emissions were not impacted by experimental warming for two common pasture species. Pedobiologia, 87-88: 150744. 中科院三区，IF = 3.2

29．Zhang, H. & Powell, J. (2021). Advances in understanding arbuscular mycorrhizal fungal effects on soil nutrient cycling. In: Understanding and Improving Crop Root Function. 书籍章节.

30．Zhang, H., Powell, J., Plett, J., Churchill, A., Power, S., Macdonald, C., Jacob, V., Kim, G., Pendall, E., Tissue, D., Catunda, K., Igwenagu, C., Carrillo, Y., Moore, B. & Anderson, I. (2020). Climate warming negates arbuscular mycorrhizal fungal reductions in soil phosphorus leaching with tall fescue but not lucerne. Soil Biology and Biochemistry. 中科院一区，IF = 10.0

31．Rillig, M., Aguilar-Trigueros, C., Anderson, I., Antonovics, J., Ballhausen, M., Bergmann, J., Bielcik, M., Chaudhary, V., Deveautour, C., et al., Zhang, H. (2020). Myristate and the ecology of AM fungi: significance, opportunities, applications and challenges. New Phytologist, 227(6): 1610-1614. 中科院一区，IF = 10.8

32．Jiang, M., Caldararu, S., Zhang, H., Fleischer, K., Crous, K., Yang, J., De Kauwe, M., Ellsworth, D., Reich, P., Tissue, D., Zaehle, S. & Medlyn, B. (2020). Low phosphorus supply constrains plant responses to elevated CO2: a meta-analysis. Global Change Biology, 26(10): 5856-5873. 中科院一区，IF = 13.1

33．Jacob, V., Zhang, H., Churchill, A., Yang, J., Choat, B., Medlyn, B., Power, S. & Tissue, D. (2020). Warming reduces net carbon gain and productivity in Medicago sativa and Festuca arundinacea. Agronomy, 10: 1601. 中科院三区，IF = 4.1

34．Qiu, Z., Wang, J., Delgado-Baquerizo, M., Trivedi, P., Egidi, E., Chen, Y., Zhang, H. & Singh, B. (2020). Plant microbiomes: do different preservation approaches and primer sets alter our capacity to assess microbial diversity and community composition? Frontiers in Plant Science, 11: 993. 中科院二区，IF = 7.3

35．Wang, X., Lü, X., Zhang, H., Dijkstra, F., Jiang, Y., Wang, X., Lu, J., Wang, Z. & Han, X. (2020). Changes in soil C:N:P stoichiometry along an aridity gradient in drylands of northern China. Geoderma, 361: 114087. 中科院一区，IF = 7.4

36．Zhang, H., Hartmann, H., Gleixner, G., Thoma, M. & Schwab, V. (2019). Carbon isotope fractionation including photosynthetic and post-photosynthetic processes in C3 plants: low [CO2] matters. Geochimica et Cosmochimica Acta, 245: 1-12. 中科院一区，IF = 6.1

37．Wang, X., Lü, X., Dijkstra, F., Zhang, H., Wang, X., Wang, Z., Feng, J. & Han, X. (2019). Changes of plant N:P stoichiometry across a 3000-km aridity transect in grasslands of northern China. Plant and Soil, 443: 107-119. 中科院一区，IF = 5.4

38．Zhang, Z., Li, Q., Zhang, H., Hu, Y., Hou, S., Wei, H., Yin, J. & Lü, X. (2019). The impacts of nutrient addition and livestock exclosure on the soil nematode community in a degraded grassland. Land Degradation and Development, 30(13): 1574-1583. 中科院二区，IF = 5.2

39．Wang, X., Yao, J., Zhang, H., Wang, X., Li, K., Lü, X., Wang, Z., Zhou, J. & Han, X. (2019). Environmental and spatial variables determine the taxonomic but not functional structure patterns of microbial communities in alpine grasslands. Science of the Total Environment. 中科院一区，IF = 10.2

40．Zhang, H., Lü, X., Hartmann, H., Keller, A., Han, X., Trumbore, S. & Phillips, R. (2018). Foliar nutrient resorption differs between arbuscular mycorrhizal and ectomycorrhizal trees at local and global scales. Global Ecology and Biogeography, 27(7): 875-885. 中科院一区，IF = 8.0

41．Zhang, H., Lü, X., Knapp, A., Hartmann, H., Bai, E., Wang, Z., Wang, X., Wang, X., Yu, Q. & Han, X. (2018). Facilitation by leguminous shrubs increases along a precipitation gradient. Functional Ecology, 32(1): 203-213. 中科院一区，IF = 6.6.

42．Lü, X., Hu, Y., Zhang, H., Wei, H., Hou, S., Yang, G., Liu, Z. & Wang, X. (2018). Intraspecific variation drives community-level stoichiometric responses to nitrogen and water enrichment in a temperate steppe. Plant and Soil, 423: 307-315. 中科院一区，IF = 5.4

43．Lü, X., Liu, Z., Hu, Y. & Zhang, H. (2018). Testing nitrogen and water co-limitation of primary productivity in a temperate steppe. Plant and Soil. 中科院一区，IF = 5.4

44．Zhang, H., Yu, Q., Lü, X., Trumbore, S., Yang, J. & Han, X. (2016). Impacts of leguminous shrub encroachment on neighboring grasses include transfer of fixed nitrogen. Oecologia. 中科院二区，IF = 3.6

45．Long, M., Wu, H., Smith, M., La Pierre, K., Lü, X., Zhang, H., Han, X. & Yu, Q. (2016). Nitrogen deposition promotes phosphorus uptake of plants in a semi-arid temperate grassland. Plant and Soil, 408: 475-484. 中科院一区，IF = 5.4

46．Quan, Z., Huang, B., Lu, C., Shi, Y., Chen, X., Zhang, H. & Fang, Y. (2016). The fate of fertilizer nitrogen in a high nitrate accumulated agricultural soil. Scientific Reports, 6: 21539. 中科院二区，IF = 5.5

47．Zhang, H., Ziegler, W., Han, X., Trumbore, S. & Hartmann, H. (2015). Plant carbon limitation does not reduce nitrogen transfer from arbuscular mycorrhizal fungi to Plantago lanceolata. Plant and Soil, 396: 369-380. 中科院一区，IF = 5.4

48．Zhang, H., Wu, H., Yu, Q., Wang, Z., Wei, C., Long, M., Kattge, J., Smith, M. & Han, X. (2013). Sampling date, leaf age and root size: implications for the study of plant C:N:P stoichiometry. PLoS ONE, 8(4): e60360. 中科院二区，IF = 4.1

49．Wei, C., Zheng, H., Li, Q., Lü, X., Yu, Q., Zhang, H., Chen, Q., He, N., Kardol, P., Liang, W. & Han, X. (2012). Nitrogen addition regulates soil nematode community composition through ammonium suppression. PLoS ONE, 7(8): e43384. 中科院二区，IF = 4.1

专利发表：

1．张海洋，邵文倩，吕晓涛，姜良超，李雪阳，马安慧. 一种基于近红外光谱对豆科植物固氮的评估方法. 国家发明专利，2025.