{"id":22,"date":"2017-11-08T14:36:17","date_gmt":"2017-11-08T18:36:17","guid":{"rendered":"http:\/\/sites.nd.edu\/rocha-laboratory\/?page_id=22"},"modified":"2026-06-02T12:05:59","modified_gmt":"2026-06-02T16:05:59","slug":"publications","status":"publish","type":"page","link":"https:\/\/sites.nd.edu\/rocha-laboratory\/publications\/","title":{"rendered":"Publications"},"content":{"rendered":"

[80] Moore, M.A., E.E. Hoy, L.K Clayton, K. Schaefer, L.L. Bourgeau-Chavez et al. (in revision) In-situ soil moisture and active layer thickness in Alaska and Northwestern Canada, 2005-2024. Nature Scientific Data<\/em>.<\/p>\n

[79] Diehl, J.L., M. Javadian, B.C.Wiebe, M. Johnston, C. Kibler, J. Adams, M. Barnes, S. Bayliss, L. Bell, W.H. Brown, R. Cheng, M.R. DeVan, C. Doughty, S. Fauset, J.H. Hastings, A. Hosseini, M. Irvine, J. Kelley, G. Koch, J. Lenters, Y. Liu, S. Paleri, S. Pau, Z.A. Pierrat, M.P. Rao, A.V. Rocha, M. Rodriguez-Caton, E. Rotenberg, C.J. Still, F. Sullivan, L.M. Tan, E. Tomelleri, S. Torres, D. Uni, X. Wang, W. Woodgate, W. ZHang, W.K. Smith, A.D. Richardson, S. Serbin, and A.F. Feldman. (in review) Standardizing Near-Surface Thermal Infrared Measurements for Ecological Applications.\u00a0 Remote Sensing of Environment<\/em>.<\/p>\n

[78] Diehl, J.L., M. Javadian, B.C. Wiebe, L. Bell, M. Rae De Van, S. Fauset, W.H. Brown, J.H. Hastings, B. Hatch, S. Hook, J. Kelley, Z.A. Pierrat, A.V. Rocha<\/strong>, W.K. Smith, F. Sullivan, D. Uni, and A.D. Richardson. (in review) Not all thermal cameras are created equal: a performance comparison for ecological applications. Agricultural and Forest Meteorology<\/em>.<\/p>\n

[77] Kim, J.E., R.C. Scholten, R. Badzioch, S.R. Curasi, I. Klupar, A.A. Salinas, M.L. Goulden, J.T. Randerson, E.B. Rastetter, A.V. Rocha<\/strong>. (in revision) Burn severity as a driver of multi-year increases in Gross Primary Production and Solar-Induced Fluorescence following wildfire in Arctic tundra. AGU Advances<\/em>.\u00a0<\/p>\n

[76] Rocha, A.V.<\/strong>, R. Badzioch, J. Caraballo-Vega, I. Klupar, A.A. Salinas, S.R. Curasi, G. Schaepman-Strub, C. Reifsnyder-Brown, G.R. Shaver, E.B. Rastetter. (2026) Shared and Divergent Rates and Trajectories of Arctic Vegetation Community Reorganization after Fire and Fertilization. Arctic Science<\/em>.<\/p>\n

[75] Senevirathne, C.K., A. Huff, D. Datta, N.G. Swenson, A.V. Rocha<\/strong>. (2026) Forest health, heart rot disease, and their impact on the source of carbon-based greenhouse gas fluxes. New Phytologist<\/em>. LINK<\/a><\/p>\n

[74] Virkkala, A-M., I. Wargowksy, J. Vogt., et al. (2025) ABCFlux v2: Arctic-boreal CO2 and CH4 monthly flux observations and ancillary information across terrestrial and freshwater ecosystems.\u00a0 Earth System Science Data<\/em>. LINK<\/a><\/p>\n

[73] Reed, D., H. Chu, B.G. Peter, J. Chen et al. (2025) Network of Networks: Time series Clustering of AmeriFlux Sites. Agricultural and Forest Meteorology<\/em>. LINK<\/a>\u00a0<\/p>\n

[72] Rocha, A.V.<\/strong>, J.J. Armesto, J.F. Perez-Quezada, B. Blakely, P. Sharma, A. Gaxiola. (2025) Atmosphere, vegetation, and soil water coupling determined by stomatal regulation of transpiration. Ecosystems<\/em>. LINK<\/a><\/p>\n

[71] Heim, R.J., A.V. Rocha<\/strong>, V. Zemlianskii, K. Barrett, H. Bultmann, A. Breen, G.V. Frost, T.N. Hollingsworth, R. Jandt, M. Kozlova, A. Kurka, M.T. Jorgenson, S. Lanhausser, M.M. Loranty, E.A. Miller, K. Narita, E. Pravdolyubova, N. Holzel, and G. Schaepman-Strub (2025) Arctic tundra ecosystems under fire\u2014Alternative ecosystem states in a changing climate? Journal of Ecology.\u00a0<\/em>LINK<\/span><\/a><\/p>\n

[70] Frost, G.V., U.S. Bhatt, M.J. Macander, L.T. Berner, A. Bartsch, J.W. Bjerke, H. Epstein, B.C. Forbes, S. Goetz, E.E. Hoy, S.R. Karlsen, T. Kumpula, T.C. Lantz, M.J. Lara, E. Lopez-Blanco, R. Magnusson, P. Montesano, C.S. Neigh, I. Nitze, K.M. Orndahl, T. Park, G.K. Phoenix, M.K. Raynolds, A.V. Rocha<\/strong>, B.M. Rogers, G. Schaepman-Strub, H. Tommervik, M. Vrdonen, A. Veremeeva, A.M. Virkkala, C. Waigl, D.A. Walker, D. Yang. (2025) The changing face of the Arctic: Four decades of greening and implications for tundra ecosystems. Frontiers in Environmental Science<\/em>. LINK<\/a><\/p>\n

[69] Talucci, A., Loranty, M. M., Holloway, J. E., Rogers, B. M., Alexander, H. D., Baillargeon, N., Baltzer, J. L., Berner, L. T., Breen, A., Brodt, L., Buma, B., Dean, J., Delcourt, C. J. F., Diaz, L. R., Dieleman, C. M., Douglas, T. A., Frost, G. V., Gaglioti, B. V., Hewitt, R. E., Hollingsworth, T., Jorgenson, M. T., Lara, M. J., Loehman, R. A., Mack, M. C., Manies, K. L., Minions, C., Natali, S. M., O’Donnell, J. A., Olefeldt, D., Paulson, A. K., Rocha, A. V.<\/strong>, Saperstein, L. B., Shestakova, T. A., Sistla, S., Sizov, O., Soromotin, A., Turetsky, M. R., Veraverbeke, S., and Walvoord, M. A. (2024) Permafrost-wildfire interactions: Active layer thickness estimates for paired burned and unburned sites in northern high-latitudes, Earth Syst. Sci. Data Discuss<\/em>. LINK<\/a><\/p>\n

[68] Min, E., N.T. Boelman, L. Gough, J.R. Mclaren, E.B. Rastetter, R.J. Rowe, A.V.Rocha<\/strong>, M.H. Turnbull, and K.L. Griffin. (2024) The give and take of Arctic greening: differential responses of the carbon sink-to-source threshold to light and temperature in tussock tundra may be influenced by vegetation cover.\u00a0 Communications Biology<\/em>. LINK<\/a><\/p>\n

[67] Bonan, G.B., O. Lucier, D.R. Coen, A.C. Foster, J.K. Shuman, M.M Lague, A.L.S. Swann, D.L. Lombardozzi, W.R. Wieder, K.M. Dahlin, A.V. Rocha<\/strong>, and M.D. SanClements. (2024) Reimagining Earth in the Earth System. Journal of Advances in Modeling Earth Systems<\/em>. LINK<\/a><\/p>\n

[66] Zhu, X. et al. \u00a0(2024) A synthesized field survey database of vegetation and active layer properties for the Alaskan tundra (1972\u20132020).\u00a0 Earth System Science Data<\/em>. LINK<\/a><\/p>\n

[65] Curasi, S.R., N. Fetcher, K.S. Wright, D. Weldon, A.V. Rocha<\/strong> (2023) Insights into the tussock growth form with model data fusion. New Phytologist<\/em>. 239: 562-575. LINK<\/a> (Also see New Phytologist Commentary Highlight of this manuscript by Kevin Wilcox<\/em> [LINK<\/a>])<\/p>\n

[64] Cheng, R., T.S. Magney, E.L. Orcutt, Z. Pierrat, P. Kohler, D.R. Bowling, M.S. Bret-Harte, E.S. Euskirchen, M. Jung, H. Kobayashi, A.V. Rocha<\/strong>, O. Sonnentag, S. Walther, D. Zona, C. Frankenberg. (2022) Evaluating photosynthetic activity across Arctic-Boreal land cover types using solar-induced fluorescence. Environmental Research Letters<\/em>. LINK<\/a><\/p>\n

[63] Schaepman-Strub, G., J-S. Kim, R. Grysko, H. Kropp, I. Grunberg, V. Zemlianskii, O. Sonnentag, et al. (2022) Vegetation type is an important predictor of the arctic summer land surface energy budget. Nature Communications<\/em>. LINK<\/a><\/p>\n

[62] Shuman, J., J. Balch, R. Barnes, P. Higuera, et al. (2022) Reimagine Fire Science for the Anthropocene. PNAS Nexus<\/em>. 1(3):pgac115. LINK<\/a><\/p>\n

[61] Lind\u00e9n, E., te Beest, M., Abreu, I., et al. (2022) Circum-Arctic distribution of chemical anti-herbivore compounds suggests biome-wide trade-off in defense strategies in arctic shrubs. Ecography<\/em>. LINK<\/a><\/p>\n

[60] Curasi, S.R., N. Fetcher, R.E. Hewitt, P.M. Lafleur, M.M. Loranty, M.C. Mack, J.L. May, I.H. Myers-Smith, S.M. Natali, S.F. Oberbauer, T.C. Parker, O. Sonnentag, S.A. Vargas Zesati, S.D. Wullschleger, and A.V. Rocha<\/strong>. (2022) Range shifts in a foundation sedge potentially induce large Arctic ecosystem carbon losses and gains. Environmental Research Letters<\/em>. LINK<\/a><\/p>\n

[59] Cabon, A., S.A. Kannenberg, A. Arain, F. Babst, D. Baldocchi, S. Belmecheri, N. Delpierre, R. Guerrieri, J.T. Maxwell, S. McKenzie, F.C. Meinzer, D.J. Moore, C. Pappas, A.V. Rocha<\/strong>, P. Szener, M. Ueyama, D. Ulrich, C. Vincke, S.L. Voelker, J. Wei, D. Woodruff, W.R.L Anderegg. (2022) Cross-biome synthesis of source versus sink limits to tree growth. Science<\/em>. LINK<\/a><\/p>\n

[58] Steketee, J.K, A.V. Rocha<\/strong>, L. Gough, K.L. Griffin, I. Klupar, R. An, N. Williamson, R.J. Rowe. (2022) Small herbivores with big impacts: tundra voles (Microtus oeconomus<\/em>) alter post-fire ecosystem dynamics. Ecology<\/em>. LINK<\/a><\/p>\n

[57] Curasi, S.R., I. Klupar, M.M. Loranty, A.V. Rocha<\/strong> (2022) An open source, durable, and low-cost alternative to commercially available soil temperature data loggers. Sensors. <\/em>22(1):148. LINK<\/a><\/p>\n

[56] Lembrechts, J.J. et al. (2021) Global maps of soil temperature. Global Change Biology<\/em>. LINK<\/a><\/p>\n

[55] Watts, J.D., S.M. Natali, C. Minions, D. Risk, K. Arndt, D. Zona, E.S. Euskirchen, A.V. Rocha<\/strong>, O. Sonnentag, M. Helbig, et al. (2021) Soil respiration strongly offsets carbon uptake in Alaska and Northwest Canada. Environmental Research Letters<\/em>. 16:084051. LINK<\/a><\/p>\n

[54] Thunberg, S.M., J.E. Walsh, E.S. Euskirchen, K. Redilla, and A.V. Rocha<\/strong>. (2021) Surface moisture budget of tundra and boreal ecosystems in Alaska: variations and drivers. Polar Science<\/em>. 29:100685. LINK<\/a><\/p>\n

[53] Klupar, I., A.V. Rocha<\/strong>, and E.B. Rastetter. (2021) Alleviation of nutrient co-limitation induces regime shifts in post-fire community composition and productivity in arctic tundra. Global Change Biology<\/em>. 27(14): 3324-3335. LINK<\/a><\/p>\n

[52] Clayton, L., K. Schaefer, M.J. Battaglia, L. Bourgeau-Chavez, J. Chen, R.H. Chen, A. Chen, K. Bakian-Dogaheh, S. Grelik, E. Jafarov, L. Liu, S. Ludwig, R.J. Michaelides, M. Moghaddam, A. Parsekian, A.V. Rocha<\/strong>, S.R. Schaefer, T. Sullivan, A. Tabatabaeenejad, K. Wang, C. Wilson, H.A. Zebker, T. Zhang, Y. Zhao. (2021) Active layer thickness as a function of soil water content. Environmental Research Letters<\/em>. 16: 055028. LINK<\/a><\/p>\n

[51] Abbott, B.W., A.V. Rocha<\/strong>, A. Shogren, J.P. Zarnetske, F. Iannucci, W.B. Bowden, S.P. Bratsman, L. Patch, R. Watts, R. Fulweber, R.J. Frei, A.M. Huebner, S.M. Ludwig, G. Carling, and J.A. O’Donnell. (2021) Tundra wildfire triggers sustained lateral nutrient loss in Alaskan Arctic. Global Change Biology. 27: 1408-1430.\u00a0 <\/em>LINK<\/a><\/p>\n

[50] Rocha, A.V.<\/strong>, R. Appel, M.S. Bret-Harte, E. Euskirchen, V. Salmon, and G. Shaver. (2021) Solar position confounds the relationship between ecosystem function and vegetation indices derived from solar and photosynthetically active radiation fluxes. Agricultural and Forest Meteorology<\/em>. 298-299, 108291. LINK<\/a><\/p>\n

[49] Jones, J.A., P. Groffman, J. Blair, F. Davis, H. Dugan, E. Euskirchen, S. Frey, T. Harms, E.L. Hinckley, M. Kosmala, S. Loberg, S. Malone, K. Novick, S. Record, A.V. Rocha<\/strong>, B. Ruddell, E. Stanley, C. Sturtevant, A. Thorpe, T. White, W. Wieder, L. Zhai, K. Zhu. (2021) Synergies among environmental science research and monitoring networks: A research agenda. Earth’s Future<\/em>. 9, e2020ER001631.\u00a0 LINK<\/a><\/p>\n

[48] Kropp, H., M.M. Loranty, S.M. Natali, A.L. Kholodov, A.V. Rocha<\/strong>, I. Myers-Smith, et al. (2020) Shallow soils are warmer under trees and tall shrubs across Arctic and Boreal ecosystems.\u00a0 Environmental Research Letters<\/em>. 16\u00a0015001 LINK<\/a><\/p>\n

[47] Hewitt, R.E., F.S. Chapin, T.N. Hollingsworth, M.C. Mack. A.V. Rocha<\/strong>, D.L. Taylor. (2020) Limited overall impacts of ectomycorrhizal inoculation on recruitment of boreal trees into Arctic tundra following wildfire belie species-specific responses. PLOS one<\/em>.15(7): e0235932. LINK<\/a><\/p>\n

[46] Lembrechts, J.J. et al. (2020) SoilTemp: call for data for a global database of near-surface temperature. Global Change Biology<\/em>. 26<\/span>:\u00a06616<\/span>\u2013\u00a06629<\/span>. LINK<\/a><\/p>\n

[45] Blakely, B., A.V. Rocha, <\/strong>and J.S. Mclachlan.<\/strong> (2019) A century of forest regrowth and snow loss alter the cooling effect of historical land use in the Upper Midwest. Ecosystems<\/em>. 23, 1056-1074.\u00a0 LINK<\/a><\/p>\n

[44] Carey, J.C., B.W. Abbott, and A.V. Rocha<\/strong>. (2019) Arctic tundra wildfire nearly doubles silica storage in terrestrial vegetation. Earth’s Future<\/em>. 7, 1044-1057. LINK<\/a><\/p>\n

[43] Curasi, S.R., T.C. Parker, A.V. Rocha<\/strong>, M.M. Moody, J. Tang, and N. Fetcher. (2019) Differential responses of ecotypes to climate in an ubiquitos Arctic sedge: implications for future ecosystem C cycling. New Phytologist. 223: 180-192. <\/em>LINK<\/a><\/p>\n

[42] Xiao, J.,\u00a0Li, X., B. He, M Alta Arain, J. Beringer, A.R. Desai, C. Emmel, D.Y. Hollinger, A. Krasnova, I. Mammarella, S.M. Noe, P. Serrano Ortiz, C. Rey-Sanchez, A.V. Rocha<\/strong>,\u00a0 and A. Varlagin. (2019)\u00a0Solar-induced chlorophyll fluorescence exhibits a nearly universal relationship with gross primary productivity across a wide variety of biomes. Global Change Biology<\/em>. 25: e4-e6.\u00a0 LINK<\/a><\/p>\n

[41]\u00a0Rocha, A.V.<\/strong>, B. Blakely, Y. Jiang, S. Curasi, and K. Wright. (2018) Is arctic greening consistent with the ecology of tundra? Lessons from an ecologically informed mass balance model. Environmental Research Letters<\/em>. 13, 125007. LINK<\/a><\/p>\n

[40] Zipper, S.C., P. Lamontagne-Halle, J.M. McKenzie, and A.V. Rocha<\/strong>. (2018) Groundwater controls on post-fire permafrost thaw: water and energy balance effects. JGR-Earth Surface<\/em>. 123, 2677-2694.\u00a0 LINK<\/a><\/p>\n

[39]Loranty, M.M., B.W. Abbott, D. Blok, T.A. Douglas, H.E. Epstein, B.C. Forbes, B.M. Jones, A.L. Kholodov, H. Kropp, A. Malhotra, S.D. Mamet, I.H. Myers-Smith, S.M. Natali, J.A. O’Donnell, G.K. Phoenix, A.V. Rocha<\/strong>, O. Sonnentag, K.D. Tape, and D.A. Walker. (2018) Changing ecosystem influences on soil thermal regimes in northern high-latitude permafrost regions. Biogeosciences<\/em>. 15,5287-5313.\u00a0 LINK<\/a><\/p>\n

[38] Wright, K.S., and A.V. Rocha<\/strong>. (2018) A test of functional convergence in carbon fluxes from coupled C and N cycles in Arctic tundra. Ecological Modelling<\/em>. 383: 31-40.\u00a0LINK<\/a><\/p>\n

[37] Li, X., J. Xiao, B. He, M Alta Arain, J. Beringer, A.R. Desai, C. Emmel, D.Y. Hollinger, A. Krasnova, I. Mammarella, S.M. Noe, P. Serrano Ortiz, C. Rey-Sanchez, A.V. Rocha<\/strong>, A. Varlagin. (2018) Solar-induced chlorophyll fluorescence is strongly correlated with terrestrial photosynthesis for a variety of biomes: First global analysis based on OCO-2 and flux tower observations.\u00a0 Global Change Biology<\/em>. 1-19.\u00a0LINK<\/a><\/p>\n

[36] Barrio, I.C., E. Linden, M. T. Beest, J Olofsson,\u00a0A.V. Rocha<\/strong>, et al. (2017) Background invertebrate herbivory on dwarf birch (Betula glandulosa-nana<\/em> complex) increases with temperature and precipitation across the tundra biome.\u00a0Polar Biology\u00a0<\/em>. 1-14.\u00a0 LINK<\/a><\/p>\n

[35] Jiang, Y.,\u00a0\u00a0E.B. Rastetter, G.R. Shaver, A.V. Rocha<\/strong>, Q. Zhuang, and B.L. Kwiatkowski. (2017) Modeling long-term changes in tundra carbon balance following wildfire, climate change, and potential nutrient addition. Ecological Applications<\/em>. 27(1): 105-117.\u00a0\u00a0LINK<\/a><\/p>\n

[34] Abbott, B.W. et al. (2016) Biomass offsets little or none of permafrost carbon release from soils, streams, and wildfire: an expert assessment. Environmental Research Letters<\/em>. 3(11).\u00a0\u00a0\u00a0LINK<\/a><\/p>\n

[33] Jiang, Y.,\u00a0A.V. Rocha<\/strong>, E.B. Rastetter, G.R. Shaver, U. Mishra, Q. Zhuang, and B.L. Kwiatkowski. (2016) C-N-P interactions control climate driven changes in regional patterns of C storage on the North Slope of Alaska.\u00a0Landscape Ecology\u00a0<\/em>. 31:195-213.\u00a0 LINK<\/a><\/p>\n

[32] Hu, F.S., P.E. Higuera, P. Duffy, M.L. Chipman,\u00a0A.V. Rocha<\/strong>, A.M. Young, R. Kelly, and M.C. Dietze. (2015) Tundra fires in the Arctic: Natural Variability and Responses to Climate Change.\u00a0Frontiers in Ecology and the Environment.<\/em>13(7):369-377.\u00a0 LINK<\/a><\/p>\n

[31] Jiang, Y., E.B.\u00a0Rastetter,\u00a0A.V. Rocha<\/strong>,\u00a0A.R. Pearce,\u00a0B.L. Kwiatkowski, G.R. Shaver. (2015) Modeling carbon-nutrient interactions during\u00a0the\u00a0early\u00a0recovery of tundra\u00a0after\u00a0fire.\u00a0Ecological Applications.<\/em>\u00a025(6):1640-1652.\u00a0 LINK<\/a><\/p>\n

[30]\u00a0Jiang, Y.,\u00a0A.V. Rocha<\/strong>, J.A. O\u2019Donnell, J.A. Drysdale, E.B. Rastetter, G.R. Shaver, and Q. Zuang. (2015) Contrasting soil thermal responses to fire in Alaskan tundra and boreal forest.\u00a0JGR-Earth Surface<\/em>. 120, doi: 10.1002\/2014JF003180.\u00a0 LINK<\/a><\/p>\n

[29]\u00a0Ueyama, M., K. Ichii, H. Iwata, E.S. Euskirchen, D. Zona,\u00a0A.V. Rocha<\/strong>, Y. Harazono, C. Iwama, T. Nakai, and W.C. Oechel. (2014) Change in the surface energy balance in Alaska due to fire and spring warming based on upscaled eddy covariance measurements.\u00a0JGR-Biogeosciences<\/em>. 119:1947-1969.\u00a0 LINK<\/a><\/p>\n

[28] Mbufong, H.N.,M. Lund, M. Aureal, T.R. Christensen, E. Werner, T. Friborg, H. Birger, E.R. Humphreys, M. Jackowicz-Korczynski, L. Kutzbach, P.M. Lafleur, W.C. Oechel, F.J. Parmentier, D.P. Rasse,\u00a0A.V. Rocha<\/strong>, T. Sachs, M.M. van der Molen, and M.P. Tamstorf. (2014) Assessing the spatial variability in peak season CO2<\/sub>\u00a0exchange characteristics across the Arctic tundra using a light response curve parameterization.\u00a0Biogeosciences<\/em>. 11:4897-4912.\u00a0 LINK<\/a><\/p>\n

[27] Kasurinen V., K. Alfredsen, P. Kolari, I. Mammarella, P. Alekseychik, J. Rinne, T. Vesala, P. Bernier, J. Boike, M. Langer, L.B. Marchesisi, K. van Huissteden, H. Dolman, T. Sachs, T. Ohta, A. Varlagin,\u00a0A.V. Rocha<\/strong>, A. Arain, W. Oechel, M. Lund, A. Grelle, A. Lindroth, A. Black, M. Aurela, T. Laurilla, A. Lohila, F. Berninger. (2014) Latent heat exchange in the boreal and arctic biomes.\u00a0Global Change Biology<\/em>. 20:3439-3456.\u00a0 LINK<\/a><\/p>\n

[26] Heffernan, J.B., P. Soranno, M. Angilletta, L. Buckley, W.K. Dodds, D. Gruner, T. Keitt, J. Kellner, J. Kominoski,\u00a0A.V. Rocha<\/strong>, J. Xiao, T. Harms, S. Goring, L. Koenig, B. McDowell, H. Powell, A. Richardson, C. Stow, R. Vargas, and K. Weathers (2014) Macrosystems ecology: understanding ecological patterns and processes at continental scales.\u00a0Frontiers of Ecology and Environment\u00a0<\/em>, 12,5-14.\u00a0LINK<\/a><\/p>\n

[25]\u00a0Bond-Lamberty, B.,\u00a0A.V. Rocha<\/strong>, K. Calvin, B. Holmes, C. Wang , M.L. Goulden (2014) Disturbance legacies and climate jointly drive tree growth and mortality in an intensively studied boreal forest.\u00a0Global Change Biology<\/em>, 20, 216-217.\u00a0LINK<\/a><\/p>\n

[24] Jones, B., A. Breen, B. Gaglioti, D. Mann,\u00a0A.V. Rocha<\/strong>, G. Grosse, C. Arp, M. Kunz, and D. Walker (2013) Identification of unrecognized tundra fire events on the North Slope of Alaska.\u00a0JGR-Biogeosciences,\u00a0<\/em>118, 1334-1344.\u00a0LINK<\/a><\/p>\n

[23] Ueyama, M., K. Ichii, H. Iwata, E.S. Euskirchen, D. Zona,\u00a0A.V. Rocha<\/strong>, Y. Harazono, C. Iwama, T. Nakai, and W. Oechel (2013) Upscaling terrestrial carbon dioxide fluxes in Alaska with satellite remote sensing and support vector regression.\u00a0JGR-Biogeosciences,\u00a0<\/em>118, 1266-1281.\u00a0LINK<\/a><\/p>\n

[22] Oberbauer, S.F., S.C. Elmendorf, T. Troxler, R.D. Hollister,\u00a0A.V. Rocha<\/strong>, S. Bret-Harte, M. Fosaa, T.T. Hoye, G.H.R. Henry, F. Jarrad, I.S. Jonsdottir, K. Klanderud, J.A. Klein, U. Molau, C. Rixen, N.M. Schmidt, G. Shaver, R. Slider, O. Totland, C.H. Wahren, and J.M. Welker (2013) Phenological responses of tundra plants to background climate warming tested using the International Tundra Experiment.\u00a0Philosophical Transactions of Royal Society B<\/em>, 368: 20120481.\u00a0LINK<\/a><\/p>\n

[21] Shaver, G.R., E.B. Rastetter, V. Salmon, L.E. Street, M.J. van de Weg,\u00a0A.V. Rocha<\/strong>, M.T. van Wijk, M. Williams. (2013) Panarctic modeling of net ecosystem exchange of CO2<\/sub>.\u00a0Philosophical Transactions of Royal Society B<\/em>, 368: 20120485.\u00a0LINK<\/a><\/p>\n

[20]\u00a0Rocha, A.V.<\/strong>\u00a0(2013) Tracking carbon within the trees.\u00a0New Phytologist<\/em>, 197,685-686.\u00a0LINK<\/a><\/p>\n

[19]\u00a0Rocha, A.V.<\/strong>, M.M. Loranty, P.E. Higuera, M.C. Mack, F.S. Hu, B.M. Jones, A.L. Breen, E.B. Rastetter, S.J. Goetz, G.R. Shaver (2012) The footprint of Alaskan tundra fires during the past half-century: implications for surface properties and radiative forcing.\u00a0Environmental Research Letters<\/em>, 7, 044039.\u00a0\u00a0LINK<\/a>\u00a0 Press Release<\/a><\/p>\n

[18]\u00a0Barrett, K.,\u00a0A.V. Rocha<\/strong>, M.J. van de Weg, and G. Shaver (2012) Vegetation shifts observed in arctic tundra 17 years after fire.\u00a0Remote Sensing Letters<\/em>, 3(8), 729-736.\u00a0LINK<\/a><\/p>\n

[17]\u00a0Potts, D.L., K.N. Suding, G. Winston,\u00a0A.V. Rocha<\/strong>, and M.L. Goulden (2012) Ecological effects of experimental drought and prescribed fire in a southern California coastal grassland.\u00a0Journal of Arid Environments<\/em>, 81, 59-66.\u00a0LINK<\/a><\/p>\n

[16]\u00a0Wang, Z., C.B. Schaaf, M.J. Chopping, A.H. Strahler, M.O. Roman,\u00a0A.V. Rocha<\/strong>, C.E. Woodcock, and Y. Shuai (2012) Evaluation of Moderate Resolution Imaging Spectroradiometer (MODIS) snow albedo products over tundra.\u00a0Remote Sensing of Environment<\/em>. 117, 264-280.\u00a0LINK<\/a><\/p>\n

[15]\u00a0Peters, D.P.C., A.E. Lugo, F.S. Chapin III, S.T.A. Pickett, M. Duniway,\u00a0A.V. Rocha<\/strong>, F.J. Swanson, C. Laney, and J. Jones (2011)\u00a0Cross-system comparisons elucidate disturbance complexities and generalities.\u00a0Ecosphere,<\/em>\u00a02(7):81, doi: 10.1890\/ES11- 00115.1.\u00a0LINK<\/a><\/p>\n

[14]\u00a0Bijoor, N.S., D.E. Pataki,\u00a0A.V. Rocha<\/strong>, M.L. Goulden (2011) The application of \u03b418O and \u03b4D for understanding water pools and fluxes in a Typha Marsh.\u00a0Plant, Cell, and Environment<\/em>. 34(10):1761-1775.\u00a0LINK<\/a><\/p>\n

[13]\u00a0Rocha, A.V.<\/strong>\u00a0and G.R. Shaver (2011) Post-fire energy exchange in arctic tundra: the importance and climatic implications of burn severity.\u00a0Global Change Biology<\/em>. 17(9): 2831-2841, doi:10.1111\/j.1365-2486.2011.02441.x.\u00a0LINK<\/a><\/p>\n

[12]\u00a0Boelman, N.T.,\u00a0A.V. Rocha<\/strong>, and G.R. Shaver (2011) Understanding burn severity sensing in Arctic tundra: Exploring vegetation indices, sub-optimal assessment timing and the impact of increasing pixel size.\u00a0International Journal of Remote Sensing<\/em>. 1- 24. doi:10.1080\/01431161.2011.611187.\u00a0Abstract<\/a><\/p>\n

[11]\u00a0Loranty, M.M., S.J. Goetz, E.B. Rastetter,\u00a0A.V. Rocha<\/strong>, G.R. Shaver, E.R. Humphreys, and P.M. Lafleur (2011) Scaling an instantaneous model of tundra NEE to the Arctic landscape.\u00a0Ecosystems<\/em>. 14:1, 76-93, doi:10.1007\/s10021-010-9396-4.\u00a0LINK<\/a><\/p>\n

[10]\u00a0Rocha, A.V.<\/strong>\u00a0and G.R. Shaver (2011) Burn severity influences post-fire CO2<\/sub>\u00a0exchange in arctic tundra.\u00a0Ecological Applications.<\/em>\u00a021:2, 477-489, doi:10.1890\/10-0255.\u00a0LINK<\/a><\/p>\n

[9]\u00a0Goulden, M.L., A. McMillan, G. Winston,\u00a0A.V. Rocha<\/strong>, K.L. Manies, J.W. Harden, and B.P. Bond-Lamberty (2011) Patterns of NPP, GPP, Respiration, and NEP during boreal forest succession.\u00a0Global Change Biology<\/em>. 17, 855-871, doi: 10.1111\/j.1365- 2486.2010.02274.x.\u00a0 LINK<\/a><\/p>\n

[8]\u00a0Rocha, A.V.<\/strong>\u00a0and M.L. Goulden (2010) Drought legacies influence the long-term carbon balance of a freshwater marsh.\u00a0JGR-Biogeosciences<\/em>. 115, G00H02, doi:10.1029\/ 2009JG001215.\u00a0LINK<\/a><\/p>\n

[7]\u00a0Rocha, A.V.<\/strong>\u00a0and G.R. Shaver (2009) Advantages of a two band EVI derived from solar and photosynthetically active radiation fluxes.\u00a0Agricultural and Forest Meteorology<\/em>. 149:1560-1563, doi:10.1016\/j.agrformet.2009.03.016.\u00a0LINK<\/a><\/p>\n

[6]\u00a0Rocha, A.V.<\/strong>\u00a0and M.L. Goulden (2009) Why is marsh productivity so high? New Insights from Eddy Covariance and Biomass Measurements in a Typha Marsh.\u00a0Agricultural and Forest Meteorology<\/em>. 149, 159-168.\u00a0LINK<\/a><\/p>\n

[5]\u00a0Rocha, A.V<\/strong>.<\/strong>\u00a0and M.L. Goulden (2008) Large interannual CO2 and energy exchange variability in a freshwater marsh under consistent environmental conditions.\u00a0JGR- Biogeosciences<\/em>. 113, G04019, doi:10.1029\/2008JG000712.\u00a0LINK<\/a><\/p>\n

[4]\u00a0Rocha, A.V.<\/strong>, D.L. Potts, and M.L. Goulden (2008) Standing litter as a driver of interannual CO2<\/sub>\u00a0exchange variability in a freshwater marsh.\u00a0JGR-Biogeosciences<\/em>. 113, G04020, doi:10.1029\/2008JG000713.\u00a0LINK<\/a><\/p>\n

[3]\u00a0Goulden, M.L., G.C. Winston, A.M.S. McMillan, M.E. Litvak, E.L. Read,\u00a0A.V. Rocha<\/strong>\u00a0and J.R. Elliot (2006) An eddy covariance mesonet to measure the effect of forest age on land-atmosphere exchange.\u00a0Global Change Biology<\/em>. 12:2146-2162.\u00a0LINK<\/a><\/p>\n

[2]\u00a0Rocha, A.V.<\/strong>, M.L. Goulden, A.L. Dunn, and S.C. Wofsy (2006) On linking interannual ring width variability with observations of whole-forest CO2<\/sub>\u00a0flux.\u00a0Global Change Biology<\/em>. 12:1378-1389 (Publication \u201crecommended\u201d by Faculty of 1000: http:\/\/ www.f1000biology.com\/article\/id\/1033682).\u00a0LINK<\/a><\/p>\n

[1]\u00a0Rocha, A.V.<\/strong>, H.B. Su, C. Vogel, H.P. Schmid, and P.S. Curtis (2004) Photosynthetic and water use efficiency responses to diffuse radiation by an aspen-dominated northern hardwood forest.\u00a0Forest Science<\/em>. 50:793-801.\u00a0LINK<\/a><\/p>\n\n\n

<\/p>\n\n\n\n

<\/p>\n","protected":false},"excerpt":{"rendered":"

[80] Moore, M.A., E.E. Hoy, L.K Clayton, K. Schaefer, L.L. Bourgeau-Chavez et al. (in revision) In-situ soil moisture and active layer thickness in Alaska and Northwestern Canada, 2005-2024. Nature Scientific Data. [79] Diehl, J.L., M. Javadian, B.C.Wiebe, M. Johnston, C. … Continue reading →<\/span><\/a><\/p>\n","protected":false},"author":2817,"featured_media":0,"parent":0,"menu_order":4,"comment_status":"closed","ping_status":"closed","template":"","meta":{"footnotes":""},"class_list":["post-22","page","type-page","status-publish","hentry"],"_links":{"self":[{"href":"https:\/\/sites.nd.edu\/rocha-laboratory\/wp-json\/wp\/v2\/pages\/22","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/sites.nd.edu\/rocha-laboratory\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/sites.nd.edu\/rocha-laboratory\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/sites.nd.edu\/rocha-laboratory\/wp-json\/wp\/v2\/users\/2817"}],"replies":[{"embeddable":true,"href":"https:\/\/sites.nd.edu\/rocha-laboratory\/wp-json\/wp\/v2\/comments?post=22"}],"version-history":[{"count":160,"href":"https:\/\/sites.nd.edu\/rocha-laboratory\/wp-json\/wp\/v2\/pages\/22\/revisions"}],"predecessor-version":[{"id":499,"href":"https:\/\/sites.nd.edu\/rocha-laboratory\/wp-json\/wp\/v2\/pages\/22\/revisions\/499"}],"wp:attachment":[{"href":"https:\/\/sites.nd.edu\/rocha-laboratory\/wp-json\/wp\/v2\/media?parent=22"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}