CMI Annual Report 2021
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This Year’s Publications<br />
Allen, M.R., G.P. Peters, K.P. Shine, C. Azar, et al., 2022. Indicate separate contributions<br />
of long-lived and short-lived greenhouse gases in emission targets. NPJ Climate and<br />
Atmospheric Science 5(5). (https://doi.org/10.1038/s41612-021-00226-22).<br />
Anderson, C., C. Greig, and P. Ebert, <strong>2021</strong>. From ambition to reality: Weaving the threads<br />
of net-zero delivery, Princeton University and Worley. (https://acee.princeton.edu/wpcontent/uploads/<strong>2021</strong>/08/from-ambition-to-reality-report.pdf).<br />
Baik, E., K. Chawla, J.D. Jenkins, C. Kolster, N.S. Patankar, A. Olson, S.M. Benson, and<br />
J.C.S. Long, <strong>2021</strong>. What is different about different net-zero carbon electricity systems?<br />
Energy and Climate Change 2. (https://doi.org/10.1016/j.egycc.<strong>2021</strong>.100046).<br />
Baldwin, J.W., A.R. Atwood, G.A. Vecchi, and D.S. Battisti, <strong>2021</strong>. Outsized Influence of<br />
Central American Orography on Global Climate. American Geophysical Union Advances<br />
2(2): e2020AV000343. (https://doi.org/10.1029/2020AV000343).<br />
Bertagni, M.B., F. Paulot, and A. Porporato, <strong>2021</strong>. Moisture fluctuations modulate<br />
abiotic and biotic 1 limitations of H 2<br />
soil uptake. Global Biogeochemical Cycles 35(12):<br />
e <strong>2021</strong>GB006987 (https://doi.org/10.1029/<strong>2021</strong>GB006987).<br />
Cabal, C., H.P.T. De Deurwaerder, and S. Matesanz, <strong>2021</strong>. Field methods to study the<br />
spatial root density distribution of individual plants. Plant and Soil 462:25-43. (https://<br />
doi.org/10.1007/s11104-021-04841-z).<br />
Calabrese, S., A. Garcia, J.L. Wilmoth, X. Zhang, and A. Porporato, <strong>2021</strong>. Critical<br />
inundation level for methane emissions from wetlands. Environmental Research<br />
Letters 16(4):44038. (https://doi.org/10.1088/1748-9326/abedea).<br />
Celia, M.A., <strong>2021</strong>. The role of subsurface engineering in the net-zero energy transition.<br />
IOP Conference Series: Earth and Environmental Science 861:072017. (https://<br />
iopscience.iop.org/article/10.1088/1755-1315/861/7/072017).<br />
Cerasoli, S., J. Yin, and A. Porporato, <strong>2021</strong>. Cloud cooling effects of afforestation and<br />
reforestation at midlatitudes. Proceedings of the National Academy of Sciences<br />
118(33)e2026241118. (https://doi.org/10.1073/pnas.2026241118).<br />
Chan, D., G.A. Vecchi, W. Yang, and P. Huybers, <strong>2021</strong>. Improved simulation of 19th- and<br />
20th-century North Atlantic hurricane frequency after correcting historical sea surface<br />
temperatures. Science Advances 7(26). (https://doi.org/10.1126/sciadv.abg6931).<br />
Cipolla, G., S. Calabrese, L.V. Noto, and A. Porporato, <strong>2021</strong>. The role of hydrology on<br />
enhanced weathering for carbon sequestration I. Modeling rock-dissolution reactions<br />
coupled to plant, soil moisture, and carbon dynamics. Advances in Water Resources<br />
154:103934. (https://doi.org/10.1016/j.advwatres.<strong>2021</strong>.103934).<br />
Cipolla, G., S. Calabrese, L.V. Noto, and A. Porporato, <strong>2021</strong>. The role of hydrology on<br />
enhanced weathering for carbon sequestration II. From hydroclimatic scenarios to<br />
carbon-sequestration efficiencies. Advances in Water Resources 154:103949. (https://<br />
doi.org/10.1016/j.advwatres.<strong>2021</strong>.103949).<br />
Carbon Mitigation Initiative Twenty-first Year <strong>Report</strong> <strong>2021</strong><br />
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