• Edgerton, B.A., Axford, Y., and M.L. Chipman  (2024). Evaluating middle to late Holocene climate variability from δ18O of aquatic invertebrate remains in southwestern Greenland. Quaternary Science Reviews, v. 333, 108664. doi.org/10.1016/j.quascirev.2024.108664. LINK
  • Medeiros, A.S. Chipman, M.L., Francis, D.R., Hamerlik, L., Langdon, P., Puleo, P.J.K., Schellinger, G., Steigleder, R., Walker, I.R., Woodroffe, S., and Y. Axford (2023) A continental-scale chironomid training set for reconstructing Arctic temperatures. Quaternary Science Reviews, 107728. doi.org/10.1016/j.quascirev.2022.107728. LINK
  • Shuman, J.K. et al. including M.L. Chipman (2022) Reimagine fire science for the Anthropocene. Proceedings of the Natural Academy of Science Nexus, 1-14. doi:10.1093/pnasnexus/pgac115. LINK
  • Napier, J.D. and M.L. Chipman (2021) Emerging palaeoecological frameworks for elucidating plant
    dynamics in response to fire and other disturbance. Global Ecology and Biogeography, in press. doi:10.1111/geb.13416. LINK
  • Chen, Y., R. Kelly, H. Genet, M.J. Lara, M.L. Chipman, A.D. McGuire, and F.S. Hu (2021) Resilience and sensitivity of ecosystem carbon stocks to fire-regime change in Alaskan tundra. Science of the Total Environment, in press. doi:10.1016/j.scitotenv.2021.151482. LINK
  • Lara, M.J. and M.L. Chipman (2021) Periglacial lake origin influences the likelihood of lake drainage in northern Alaska. Remote Sensing 13, 852. doi:10.3390/rs13050852. LINK
  • Napier, J.D., G. de Lafontaine, and M.L. Chipman (2020) The evolution of paleoecology. Trends in Ecology and Evolution 35(4), 293-295. doi:10.1016/j.tree.2019.12.006. LINK
  • McLauchlan, K.K., and Future of Fire Consortium Members including M.L. Chipman (2020) Fire as a fundamental ecological process: research advances and frontiers. Journal of Ecology 108(5), 2047-2069. doi:10.1111/1365-2745.13403. LINK
  • Chipman, M.L. and F.S. Hu (2019) Resilience of lake biogeochemistry to boreal-forest wildfires during the late Holocene. Biology Letters 15: doi:10.1098/rsbl.2019.0390. LINK
  • Lara, M.J., M.L. Chipman, and F.S. Hu (2018) Automated detection of thermoerosion in permafrost ecosystems using temporally dense Landsat image stacks. Remote Sensing of the Environment 221: doi:10.1016/j.rse.2018.11.034. LINK
  • Chipman, M.L. and F.S. Hu (2017) Linkages among climate, fire, and thermoerosion in Alaskan tundra over the past three millennia. Journal of Geophysical Research: Biogeosciences 122, doi:10.1002/2017JG00402. LINK
  • Vachula, R.S., M.L. Chipman, and F.S. Hu (2016) Holocene climatic changes in the Alaskan Arctic as inferred from carbonate oxygen isotopes. Holocene 27: doi: 10.1177/0959683617702230. LINK
  • Chipman, M.L., G.W. Kling, C.C. Lundstrom, and F.S. Hu (2016) Multiple thermo-erosional episodes during the past six millennia: Implications for the response of Arctic permafrost to climate change. Geology  44:439-442. LINK
  • Chipman, M.L., V. Hudspith, P.E. Higuera, P.A. Duffy, R. Kelly, W.W. Oswald and F.S. Hu (2015) Spatiotemporal patterns of tundra fires:  Late-Quaternary charcoal records from Alaska. Biogeosciences 12: 4017-4027. LINK
  • Hu, F.S., P.E. Higuera, P.D. Duffy, M.L. Chipman, A. Young, A. Rocha, R.K. Kelly and M. Dietze (2015) Tundra fires in the Arctic: Natural variability and responses to climate change. Frontiers in Ecology and the Environment 13: 369-377. LINK
  • Kelly, R., M.L. Chipman, P.E Higuera, V. Stephanova, L. Brubaker, and F.S. Hu (2013) Recent burning of boreal forests exceeds fire regime limits of the past 10,000 years. Proceedings of the National Academy of Sciences USA doi/10.1073/pnas.1305069110. LINK
  • Chipman, M.L., B.F. Clegg, and F.S. Hu (2012) Variation in the moisture regime of northeastern interior Alaska and possible linkages to the Aleutian Low: inferences from a late-Holocene d18O record. Journal of Paleolimnology 48: 69-81. LINK
  • Higuera, P.E., M.L. Chipman, J.L. Barnes, M.A. Urban, and F.S. Hu (2011) Variability of tundra fire regimes in Arctic Alaska: millennial-scale patterns and ecological implications. Ecological Applications 21:3211-3226. LINK
  • Higuera, P.E., J.L. Barnes, M.L. Chipman, M.A. Urban, and F.S. Hu (2011) The Burning Tundra: A Look Back at the Last 6,000 Years of Fire in the Noatak National Preserve, Northwestern Alaska. Alaska Park Science 10:36-41. LINK
  • Hu, F.S., P.E. Higuera, J.E. Walsh, W.I. Chapman, P.A. Duffy, L.B. Brubaker, and M.L. Chipman (2010) Tundra burning in Alaska: Linkages to climatic change and sea ice retreat. Journal of Geophysical Research 115: doi:10.1029/2009JG001270, 2010. LINK
  • Clegg, B.F., G.H Clarke, M.L. Chipman, I.R. Walker, W. Tinner, and F.S. Hu (2010) Six millennia of summer temperature variation based on midge analysis of lake sediments from Alaska. Quaternary Science Reviews 29: 3308-3316. LINK
  • Kaufman, D.S. et al., and Arctic Lakes 2k Project Members including M.L. Chipman (2009) Recent warming reserves long-term arctic cooling. Science 325: 1236-1239. LINK
  • Chipman, M.L., G.H. Clarke, B.F. Clegg, I. Gregory-Eaves, and F.S. Hu (2009) A 2000-year record of climate change at Ongoke Lake, southwestern Alaska. Journal of Paleolimnology 41: 57-75. LINK