Liu, H., Jiang, M., Yu, Z., Kang, W., Shen, Z., Dong, H., Chen, S., Yan, X., and Liu, J., 2024. Contrasting north-south pattern in Holocene lacustrine carbon accumulation in China: Summer monsoon dynamics and human disturbance. Quaternary Science Reviews, 324, 108465. [PDF]
Liu, H., Han, D., and Wang, G., 2024. Considering the autogenic processes of the ecosystem to analyze the sensitivity of peatland carbon accumulation to temperature and hydroclimate change. CATENA, 236, 107717. [PDF]
Liu, J.#,Liu, H.#, Chen, H.#, Yu, Z., Piao, Z., Smol, J., Zhang, J., Huang, L., Wang, T., Yang B., Zhao, Y., and Chen, F. 2022. Anthropogenic warming reduces the carbon accumulation of Tibetan Plateau peatlands. Quaternary Science Reviews, 281, 107449. [PDF]
Liu, H., Gao, C., and Wang, G., 2022. Considering the adaptive cycle and resilience of the ecosystem to define reference conditions for wetland restoration. Earth's Future, 10(4), e2021EF002419. [PDF]
Liu, H., Yu, Z., Han, D., Gao, C., Yu, X., and Wang, G., 2019. Temperature influence on peatland carbon accumulation over the last century in Northeast China. Climate Dynamics, 53(3), 2161-2173. [PDF]
Liu, H., Gao, C., and Wang, G., 2018. Understand the resilience and regime shift of the wetland ecosystem after human disturbances. Science of the total environment, 643, 1031-1040. [PDF]
Liu, H., Gao, C., Wei, C., Wang, C.,Yu, X., and Wang, G., 2018. Evaluating the timing of the start of the Anthropocene from Northeast China: Applications of stratigraphic indicators. Ecological Indicators, 84, 738–747. [PDF]
Liu, H., Yu, X., Gao, C., Zhang, Z., Wang, C., Xing, W., and Wang, G., 2017. A 4000-yr multi-proxy record of Holocene hydrology and vegetation from a peatland in the Sanjiang Plain, Northeast China. Quaternary International, 436, 28–36. [PDF]
Liu, H., Gao, C., Yu, X., Zhang, Z., and Wang, G., 2016. The prospects in studying reference conditions constructing of ecological Restoration of wetlands based on paleoecological records. Wetland Sciences, 14(4), 568–575.(In Chinese with English abstract) [PDF]
Li, Y., Gao, C., Liu, H., Han, D., Cong, J., Li, X., and Wang, G., 2022. Distribution of phosphorus forms in surface soils of typical peatlands in northern Great Khingan Mountains and its potential to reconstruct paleo-vegetations. Journal of Environmental Management, 302, 114033. [PDF]
Han, D., Gao, C., Liu, H., Li, Y., Cong, J., Yu, X., and Wang, G., 2021. Anthropogenic and climatic‐driven peatland degradation during the past 150 years in the Greater Khingan Mountains, NE China. Land Degradation & Development. 32(17), 4845-4857. [PDF]
Han, D., Gao, C., Li, Y., Liu, H., Cong, J., Yu, X., and Wang, G., 2020. Potential in paleoclimate reconstruction of modern pollen assemblages from natural and human-induced vegetation along the Heilongjiang River basin, NE China. Science of the Total Environment. 745, 141121. [PDF]
Li, Y., Han, D., Gao, C., Liu, H., Cong, J., Yu, X., and Wang, G., 2020. A 2000-year record of phosphorus forms and accumulation in peatland of the Greater Khingan Mountains in Northeast China: Paleoenvironmental implications. Quaternary International, 562, 27-34. [PDF]
Han, D., Gao, C., Liu, H., Yu, X., Li, Y., Cong, J., and Wang, G., 2021. Anthropogenic and climatic‐driven peatland degradation during the past 150 years in the Greater Khingan Mountains, NE China. Ecological Indicators. 117, 106577. [PDF]
Gao, C., Zhang, S., Li, Y., Han, D., Liu, H., and Wang, G., 2019. Holocene mercury accumulation calibrated by peat decomposition in a peat sequence from the Sanjiang Plain, northeast China. Quaternary International. 527, 19-28. [PDF]
Cong, J., Gao, C., Han, D., Liu, H., and Wang, G., 2019. History metal (Pb, Zn, and Cu) deposition and Pb isotope variability in multiple peatland sites in the northern Great Hinggan Mountains, Northeast China. Environmental Science and Pollution Research. 26(21), 21784-21796. [PDF]
Gao, C., Wei, C., Zhang, L., Han, D., Liu, H., Yu, X., and Wang, G., 2019. Historical (1880s–2000s) impact of wind erosion on wetland patches in semi-arid regions: A case study in the western Songnen Plain (China). Aeolian Research. 38, 13-23. [PDF]
Bao, K., Xing, W., Song, L., Li, H., Liu, H., and Wang, G., 2018. A 100-year history of water level change and driving mechanism in Heilongjiang River basin wetlands. Quaternary Sciences. 38(4), 981-995.(In Chinese with English abstract) [PDF]
Gao, C., Xing, W., Liu, H., Wang, C., Hang, D., and Wang, G., 2018. Holocene wetland evolution in Northeast China and its responses to global change. Quaternary Sciences. 38(4), 854-863.(In Chinese with English abstract) [PDF]
Gao, C., Zhang, S., Liu, H., Cong, J., Li, Y., and Wang, G., 2018. The impacts of land reclamation on the accumulation of key elements in wetland ecosystems in the Sanjiang Plain, northeast China. Environmental Pollution. 237, 487-498. [PDF]
Gao, C., Liu, H., Cong, J., Hang, D., Zhao, W., Li, Q., and Wang, G., 2018. Historical sources of black carbon identified by PAHs and δ13C in Sanjiang Plain of Northeastern China. Atmospheric Environment. 181, 61-69. [PDF]
A study on the resilience of the typical lakeside wetland ecosystem under climate change based on records of plant macrofossils and carbon accumulation in the southeastern Tibetan Plateau over the last millennium, 2021-01-01——2023-12-31, National Natural Science Foundation of China Youth Science Fund, 42001081.
The response of peatland carbon accumulation to climate change in the southeastern Tibetan Plateau over the past millennium, 2021-01-01——2022-12-31, China Postdoctoral Science Foundation, 2020M680694.
Wetland evolution and Anthropocene, 2020-01-01——2021-12-31, Special Research Assistant Project of the Chinese Academy of Sciences.