近期论文
查看导师新发文章
(温馨提示:请注意重名现象,建议点开原文通过作者单位确认)
33) He, H.S. and Wang, W.J. 2020. Chapter 43. LANDIS PRO Forest Landscape Model. In Wang, Y. (Ed.). The Handbook of Natural Resources, Second Edition, Six Volume. Set. Boca Raton: CRC Press. https://doi.org/10.1201/9780429446283 (自然百科全书专著章节)
32) Zhang, W.G., Wang, W.J., Hou, G.L., Gong, C., Jiang, M., and Lyu, X.G. 2020. Cooling effects of different wetlands in a semi-arid rural region of Northeast China. Theoretical and Applied Climatology, doi:10.1007/s00704-020-03158-8.
31) Wang, L., Wang, W.J.*, and Wu, Z.F. 2020. Decreasing precipitation occurs in daily extreme precipitation intervals across in observations and model simulations. Climate Dynamics, 54, 2597–2612.
30) Liu, Z.H.*, Kimball, J.S., Parazoo, N.C., Ballantyne, A.P., Wang, W.J.*, Madani, N., Pan, C.G., Watts, J.D., Reichle, R.H., Sonnentag, O., Marsh, P., Hurkuck, M., Helbig, M., Quinton, and Euskirchen, E.S. 2020. Increased high-latitude photosynthetic carbon gain offset by respiration carbon loss during an anomalous warm winter to spring transition. Global Change Biology, 26, 682-696.
29) Wang, W.J.*, Thompson III, F.R., He, H.S., Fraser, J.S., Dijak, W.D., and Jones-Farrand, T.D. 2019. Climate change and tree harvest interact to affect future tree species distribution changes. Journal of Ecology, 107(7), 1901-1917.
28) Wang, W.J.*, Ma, S., He, H.S., Thompson III, F.R., and Others. 2019. Effects of rising atmospheric CO2, climate change, and nitrogen deposition on aboveground net primary production in a temperate forest. Environmental Research Letters, 14, 104005.
27) Wang, L., Wang, W.J.*, and Wu, Z.F. 2019. Potential distribution shifts of plant species under climate change in ChangBai Mountains, China. Forests, 10 (6), 498.
26) Fraser, J.S., Wang, W.J., Thompson III, F.R. 2019. Modeling post-fire tree mortality using a logistic regression method within a forest landscape model. Forests, 10 (1), 25.
25) Wang, W.J.*, Thompson III, F.R., He, H.S., Fraser, J.S., Dijak, W.D., and Spetich, M.A. 2018. Population dynamics has greater effects than climate change on tree species distribution in a temperate forest region. Journal of Biogeography, 45(12), 2766-2778.
24) Wang, W.J.*, He, H.S., Thompson III, F.R., Spetich, M.A., and Fraser, J.S. 2018. Effects of species biological traits and environmental heterogeneity on simulated tree species distribution shifts under climate change. Science of the Total Environment, 634, 1214–1221
23) Wang, L., Wang, W.J.*, and Wu, Z.F. 2018. Spatial and temporal variations of summer hot days and heat waves and their relationships with large-scale atmospheric circulations across Northeast China. International Journal of Climatology, 38(15), 5633-5645.
22) Liu, K., Liang, Y., He, H.S., Wang, W.J.*, Huang, C., Zong, S., Wang, L.2018. Long-Term Impacts of China’s New Commercial Harvest Exclusion Policy on Ecosystem Services and Biodiversity in the Temperate Forests of Northeast China. Sustainability, 10 (4), 1071.
21) Zhao, D., He, H.S., Wang, W.J., Liu, J, Du, H., Liu, K. 2018. Distribution and driving factors of forest swamp conversions in a cold temperate region. International Journal of Environmental Research and Public Health, 15(10).
20) Zhao, D., He, H.S., Wang, W.J., Wang, L., Du, H., Liu, K., Zong, S. 2018. Predicting Wetland Distribution Changes under Climate Change and Human Activities in a Mid-and High-Latitude Region. Sustainability, 10 (3), 863.
19) Jin, W., He H.S., Shifley S.R., Wang, W.J., Kabrick, J.M., and Davidson, B.K. 2018. How can prescribed burning and harvesting restore shortleaf pine-oak woodland at the landscape scale in central United States? Modeling joint effects of harvesting and fire regimes. Forest Ecology and Management, 410, 201-210.
18) Shifley,S.R., He,H.S., Lischek, H., Wang,W.J., Jin,W., Gustafson,E.J., Thompson, J.R., Thompson III, F.R., Dijak, W.D., and Yang, J. 2017. The past and future of modeling forest dynamics: from growth and yield curves to forest landscape models. Landscape Ecology, 32, 1307-1325.
17) Jin, W., He, H.S., Thompson III, F.R., and Wang, W. J. 2017. Future forest aboveground carbon dynamics in the central United States: the importance of forest demographic processes. Scientific Reports,7: 41821.
16) Dijak, W.D., Hanberry, B.B., Fraser, J.S., He, H.S., Wang, W.J., and Thompson III,F.R. 2017. Revision and application of the LINKAGES model to simulate forest growth in Central Hardwood landscapes in response to climate change. Landscape Ecology, 32,1365-1384.
15) Wang, W.J., He, H.S., Thompson III, F.R., and Fraser, J.S. 2017. Changes in forest biomass and tree species distribution under climate change in the northeastern United States. Landscape Ecology, 32, 1399-1413.
14) Xiao, J.T., Liang, Y., Thompson, J., He, H.S., and Wang, W.J. 2017. The formulations of site-scale processes affect landscape scale forest change predictions: a comparision between LANDIS PRO and LANDIS-II forest landscape models. Landscape Ecology, 32, 1347-1363.
13) Iverson, L., Prasad, A., Matthews, S., Peters, M., He, H.S., Thompson III, F.R., Dijak, W.D., Fraser, J.S., Wang, W.J., and Swanston, C. 2017. Multi-model comparision on the effects of cliamte change on tree species in the easthern US: results from an enhanced niche model and process-based ecosystem and landscape models. Landscape Ecology, 32, 1327-1346.
12) Wang, W.J., He, H.S., Thompson III, F.R., and Fraser, J.S. 2016. Landscape-and regional-scale shifts in forest composition under climate change in the Central Hardwood Region of the United States. Landscape Ecology, 31,149-163.
11) Spetich, M.A., Fan, Z., He, H.S., Wang, W.J., Crosby, M.K., and Shifley, S.R. 2016. Oak Decline Across the Ozark Highlands–from regeneration to landscape and regional scale processes. In: Proceedings of the 18th biennial southern silvicultural research conference. e–Gen.Tech.Rep.SRS–212.Asheville,NC: U.S. Department of Agriculture, Forest Service, Southern Research Station.641.P.
10) Wang, W.J., He, H.S., Thompson III, F.R., Fraser, J.S., Hanberry, B.B. and Dijak, W.D. 2015. Importance of succession, harvest, and climate change in determining future composition in U.S. Central Hardwood Forests. Ecosphere 6, art277.
9) Liang, Y., He, H.S., Wang, W.J., Fraser, J.S., and Wu, Z.W. 2015. The effects of site-scale processes in forest landscape models on prediction of tree species distribution. Ecological Modelling, 300, 89-101.
8) Wang, W.J., He, H.S., Fraser, J.S., Thompson III, F.R., Shifley, S.R., and Spetich, M.A., 2014. LANDIS PRO: a landscape model that predicts forest composition and structure changes at regional scales. Ecography, 37, 225-229.
7) Wang, W.J., He, H.S., Spetich, M.A., Shifley, S.R., and Thompson III, F.R. 2014. Evaluating forest landscape model predictions using empirical data and knowledge. Environmental Modelling and Software, 62,230–239.
6) Wang, W.J. and He, H.S. 2014. A.Srinivasan, F.H. Ling and H. Mori. (eds): Climate Smart Development in Asia: Transition to Low Carbon and Climate Resilient Economies. Landscape Ecology, 29, 559-561.
5) Luo, X., He, H.S., Liang, Y., Wang, W.J., Wu, Z.W., and Fraser, J.S. 2014. Spatial simulation of the effect of fire and harvest on aboveground tree biomass in boreal forests of Northeast China. Landscape Ecology, 29, 1187-1200.
4) Brandt, L., He, H.S, Iverson, L., Thompson III, FR. Wang, W.J., and Other. 2014. Central Hardwoods Ecosystem Vulnerability Assessment and Synthesis: A Report from the Central Hardwoods Climate Change Response Framework Project. Gen. Tech. Rep. NRS-124. Newtown Square, PA: U.S. Department of Agriculture, Forest Service, Northern Research Station. 254 p. (美国农业部政府报告)
3) Wang, W.J., He, H.S., Spetich, M.A., Shifley, S.R., Thompson III,F.R., Larsen, D.R., Fraser, J.S. and Yang, J. 2013. A large-scale forest landscape model incorporating multi-scale processes and utilizing forest inventory data. Ecosphere, 4(9),106.
2) Wang, W.J., He, H.S., Spetich, M.A., Shifley, S.R., Thompson III,F.R., and Fraser, J.S. 2013. Modeling the effects of harvest alternatives on mitigating oak decline in a Central Hardwood Forest landscape. PLoS ONE, 8(6), e66713.
1) Fraser, J.S., He, H.S., Shifley, S.R., Wang, W.J., and Thompson III, F.R. 2013. Simulating stand-level harvests across landscapes, LANDIS PRO harvest module design. Canadian Journal of Forest Research, 43(10), 972-978.