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Publications by Author

Ricciuto, Daniel

  • Salmon VG, Brice DJ, Bridgham SD, Childs J, Graham JD, Griffiths NA, Hofmockel KS, Iversen CM, Jicha TM, Kolka RK, et al. 2021. Nitrogen and phosphorus cycling in an ombrotrophic peatland: a benchmark for assessing change. Plant and Soil. 466(1-2):649–674. doi:10.1007/s11104-021-05065-x.
  • Jiang J, Huang Y, Ma S, Stacy M, Shi Z, Ricciuto DM, Hanson PJ, Luo Y. 2018. Forecasting Responses of a Northern Peatland Carbon Cycle to Elevated CO2 and a Gradient of Experimental Warming. Journal of Geophysical Research: Biogeosciences. 123(3):1057–1071. doi:10.1002/2017jg004040.
  • Hanson PJ, Riggs JS, Nettles R, Phillips JR, Krassovski MB, Hook LA, Gu L, Richardson AD, Aubrecht DM, Ricciuto DM, et al. 2017. Attaining whole-ecosystem warming using air and deep-soil heating methods with an elevated CO<sub>2</sub> atmosphere. Biogeosciences. 14(4):861–883. doi:10.5194/bg-14-861-2017.
  • Shi X, Thornton PE, Ricciuto DM, Hanson PJ, Mao J, Sebestyen SD, Griffiths NA, Bisht G. 2015. Representing northern peatland microtopography and hydrology within the Community Land Model. Biogeosciences. 12(21):6463–6477. doi:10.5194/bg-12-6463-2015.
  • Hough M, Ma S, Huang Y, Zhou Y, Kim H-S, Lopez-Blanc E, Jiang L, Xia J, Tao F, Williams C, et al. 2023. Across-model spread and shrinking in predicting peatland carbon dynamics under global change. . Global Change Biology. 29:2759–2775. doi:10.1111/gcb.16643.
  • Huang Y, Jiang J, Ma S, Ricciuto DM, Hanson PJ, Luo Y. 2017. Soil thermal dynamics, snow cover, and frozen depth under five temperature treatments in an ombrotrophic bog: Constrained forecast with data assimilation. Journal of Geophysical Research: Biogeosciences. 122(8):2046–2063. doi:10.1002/2016jg003725.

Rich, Virginia

  • Wilson RM, Tfaily MM, Rich VI, Keller JK, Bridgham SD, Zalman CM, Meredith L, Hanson PJ, Hines M, Pfeifer-Meister L, et al. 2017. Hydrogenation of organic matter as a terminal electron sink sustains high CO2:CH4 production ratios during anaerobic decomposition. Organic Geochemistry. 112:22–32. doi:10.1016/j.orggeochem.2017.06.011.

Richardson, Andrew

  • Richardson AD, Novick K, Basler DD, Phillips JR, Krassovski MB, Warren JM, Sebestyen SD, Hanson PJ. 2024. Experimental whole‐ecosystem warming enables novel estimation of snow cover and depth sensitivities to temperature, and quantification of the snow‐albedo feedback effect. Journal of Geophysical Research – Biogeosciences . 129:2023JG007833. doi:10.1029/2023JG007833.
  • Richardson AD, Hufkens K, Milliman T, Aubrecht DM, Furze ME, Seyednasrollah B, Krassovski MB, Latimer JM, Nettles R, Heiderman RR, et al. 2018. Ecosystem warming extends vegetation activity but heightens vulnerability to cold temperatures. Nature. 560(7718):368–371. doi:10.1038/s41586-018-0399-1.
  • Richardson AD, Schadel C, Westergaard-Nielsen A, Novick K, Basler DD, Phillips JR, Krassovski MB, Warren JM, Sebestyen SD, Hanson PJ. 2024. Experimental whole-ecosystem warming enables novel estimation of snow cover and depth sensitivities to temperature, and quantification of the snow-albedo feedback effect. JGR Biogeosciences. 129(3):1–19. doi:10.1029/2023JG007833.
  • Schadel C, Seyednasrollah B, Hanson PJ, Hufkens K, Pearson K, Warren MJ, Richardson AD. 2023. Using long-term data from a whole ecosystem warming experiment to identify best spring and autumn phenology models. Plant Environment Interactions . 4:188–200. doi:10.1002/pei3.10118.
  • Hanson PJ, Riggs JS, Nettles R, Phillips JR, Krassovski MB, Hook LA, Gu L, Richardson AD, Aubrecht DM, Ricciuto DM, et al. 2017. Attaining whole-ecosystem warming using air and deep-soil heating methods with an elevated CO<sub>2</sub> atmosphere. Biogeosciences. 14(4):861–883. doi:10.5194/bg-14-861-2017.

Riggs, Jeffery

  • Barbier C, Hanson PJ, Todd DE, Belcher D, Jekabson EW, Thomas WK, Riggs JS. 2013. Air Flow and Heat Transfer in a Temperature-Controlled Open Top Enclosure. Volume 7: Fluids and Heat Transfer, Parts A, B, C, and D. doi:10.1115/imece2012-86352.
  • Krassovski MB, Riggs JS, Hook LA, Nettles R, Hanson PJ, Boden TA. 2015. A comprehensive data acquisition and management system for an ecosystem-scale peatland warming and elevated CO2 experiment. Geoscientific Instrumentation, Methods and Data Systems. 4(2):203–213. doi:10.5194/gi-4-203-2015.
  • Hanson PJ, Riggs JS, Nettles R, Phillips JR, Krassovski MB, Hook LA, Gu L, Richardson AD, Aubrecht DM, Ricciuto DM, et al. 2017. Attaining whole-ecosystem warming using air and deep-soil heating methods with an elevated CO<sub>2</sub> atmosphere. Biogeosciences. 14(4):861–883. doi:10.5194/bg-14-861-2017.
  • Krassovski MB, Lyon GE, Riggs JS, Hanson PJ. 2018. Near-real-time environmental monitoring and large-volume data collection over slow communication links. Geoscientific Instrumentation, Methods and Data Systems. 7(4):289–295. doi:10.5194/gi-7-289-2018.
  • Hanson PJ, Gill AL, Xu X, Phillips JR, Weston DJ, Kolka RK, Riggs JS, Hook LA. 2016. Intermediate-scale community-level flux of CO2 and CH4 in a Minnesota peatland: putting the SPRUCE project in a global context. Biogeochemistry. 129(3):255–272. doi:10.1007/s10533-016-0230-8.
  • Hanson PJ, Childs KW, Wullschleger SD, Riggs JS, Thomas WK, Todd DE, Warren JM. 2011. A method for experimental heating of intact soil profiles for application to climate change experiments. Global Change Biology. 17(2):1083–1096. doi:10.1111/j.1365-2486.2010.02221.x.

Rinne, J.

  • Helbig M, Živković T, Alekseychik P, Aurela M, El-Madany TS, Euskirchen ES, Flanagan LB, Griffis TJ, Hanson PJ, Hattakka J, et al. 2022. Warming response of peatland CO2 sink is sensitive to seasonality in warming trends. Nature Climate Change. doi:10.1038/s41558-022-01428-z.

Rocca, Jennifer

  • Bell CW, Fricks BE, Rocca JD, Steinweg JM, McMahon SK, Wallenstein MD. 2013. High-throughput Fluorometric Measurement of Potential Soil Extracellular Enzyme Activities. Journal of Visualized Experiments.(81). doi:10.3791/50961.
  • DeWitt K, Carrell AA, Rocca JD, Votzke S, Yammine A, Peralta A, Weston DJ, Pelletier DA, Gilbert J. 2025. Predation by a ciliate community mediates temperature and nutrient effects on a peatland prey prokaryotic community. . mSphere.

Roman, D.

  • Helbig M, Živković T, Alekseychik P, Aurela M, El-Madany TS, Euskirchen ES, Flanagan LB, Griffis TJ, Hanson PJ, Hattakka J, et al. 2022. Warming response of peatland CO2 sink is sensitive to seasonality in warming trends. Nature Climate Change. doi:10.1038/s41558-022-01428-z.

Romero‐Olivares, Adriana

  • Defrenne CE, Abs E, Cordeiro AL, Dietterich L, Hough M, Jones JM, Kivlin SN, Chen W, Cusack D, Franco ALC, et al. 2021. The Ecology Underground coalition: building a collaborative future of belowground ecology and ecologists. New Phytologist. 229(6):3058–3064. doi:10.1111/nph.17163.

Roth, S

  • Roth S, Griffiths NA, Oleheiser KC, Carrell AA, Klingeman D, Seibert A, Chanton JP, Hanson PJ, Schadt CW. 2023. Elevated temperature alters microbial communities, but not decomposition rates, during 3 years of in situ peat decomposition. . mSystems . 8:00337–23. doi:10.1128/msystems.00337-23.
  • Duchesneau K, Aldeguer Riquelme B, Petro C, Makke G, Green MB, Tfaily MM, Wilson RM, Roth S, Johnston ER, Kluber LA, et al. 2025. Northern peatland microbial communities exhibit resistance to warming and acquire electron acceptors from soil organic matter. Nature Communications. doi:doi.org/10.1101/2024.07.17.603906.

Rumpel, C.

  • Torn MS, Chabbi A, Crill P, Hanson PJ, Janssens IA, Luo Y, Hicks Pries CE, Rumpel C, Schmidt MWI, Six J, et al. 2015. A call for international soil experiment networks for studying, predicting, and managing global change impacts. SOIL. 1(2):575–582. doi:10.5194/soil-1-575-2015.

Sachdeva, R

  • Schoelmerich M, Ly L, West-Roberts J, Shi L-D, Shen C, Malvankar N, Taib N, Gribaldo S, Woodcroft B, Schadt CW, et al. 2024. Borg extrachromosomal elements of methane-oxidizing archaea have conserved and expressed genetic repertoires. . Nature Communications. doi:10.1038/s41467-024-49548-8.

Saleska, Scott

  • Wilson RM, Tfaily MM, Rich VI, Keller JK, Bridgham SD, Zalman CM, Meredith L, Hanson PJ, Hines M, Pfeifer-Meister L, et al. 2017. Hydrogenation of organic matter as a terminal electron sink sustains high CO2:CH4 production ratios during anaerobic decomposition. Organic Geochemistry. 112:22–32. doi:10.1016/j.orggeochem.2017.06.011.

Salmon, Verity

  • Hanson PJ, Griffiths NA, Salmon VG, Birkebak J, Warren JM, Phillips JR, Guilliams M, Oleheiser KC, Jones M, Jones N, et al. 2025. Peatland plant community changes in annual production and composition through 8 years of warming manipulations under ambient and elevated CO2 atmospheres. JGR-Biogeosciences. 130.
  • Salmon VG, Brice DJ, Bridgham SD, Childs J, Graham JD, Griffiths NA, Hofmockel KS, Iversen CM, Jicha TM, Kolka RK, et al. 2021. Nitrogen and phosphorus cycling in an ombrotrophic peatland: a benchmark for assessing change. Plant and Soil. 466(1-2):649–674. doi:10.1007/s11104-021-05065-x.
  • Salmon VG, Brice DJ, Bridgham SD, Childs J, Graham JD, Griffiths NA, Hofmockel KS, Iversen CM, Jicha TM, Kolka RK, et al. 2021. Nitrogen and phosphorus cycling in an ombrotrophic peatland: a benchmark for assessing change. Plant and Soil. 466(1-2):649–674. doi:10.1007/s11104-021-05065-x.
  • Iversen CM, Latimer JM, Brice DJ, Childs J, Vander Stel H, Defrenne CE, Graham JD, Griffiths NA, Malhotra A, Norby RJ, et al. 2022. Whole-Ecosystem Warming Increases Plant-Available Nitrogen and Phosphorus in an Ombrotrophic Bog. Ecosystems. doi:10.1007/s10021-022-00744-x.

Sargsyan, Khachik

  • Griffiths NA, Hanson PJ, Ricciuto DM, Iversen CM, Jensen AM, Malhotra A, McFarlane KJ, Norby RJ, Sargsyan K, Sebestyen SD, et al. 2017. Temporal and Spatial Variation in Peatland Carbon Cycling and Implications for Interpreting Responses of an Ecosystem-Scale Warming Experiment. Soil Science Society of America Journal. 81(6):1668–1688. doi:10.2136/sssaj2016.12.0422.

Saruta, Volodymyr

  • Huang Y, Stacy M, Jiang J, Sundi N, Ma S, Saruta V, Jung CG, Shi Z, Xia J, Hanson PJ, et al. 2019. Realized ecological forecast through an interactive Ecological Platform for Assimilating Data (EcoPAD, v1.0) into models. Geoscientific Model Development. 12(3):1119–1137. doi:10.5194/gmd-12-1119-2019.

Schadel, C

  • Schadel C, Seyednasrollah B, Hanson PJ, Hufkens K, Pearson K, Warren MJ, Richardson AD. 2023. Using long-term data from a whole ecosystem warming experiment to identify best spring and autumn phenology models. Plant Environment Interactions . 4:188–200. doi:10.1002/pei3.10118.
  • Richardson AD, Schadel C, Westergaard-Nielsen A, Novick K, Basler DD, Phillips JR, Krassovski MB, Warren JM, Sebestyen SD, Hanson PJ. 2024. Experimental whole-ecosystem warming enables novel estimation of snow cover and depth sensitivities to temperature, and quantification of the snow-albedo feedback effect. JGR Biogeosciences. 129(3):1–19. doi:10.1029/2023JG007833.

Schadt, Christopher

  • Schoelmerich M, Ly L, West-Roberts J, Shi L-D, Shen C, Malvankar N, Taib N, Gribaldo S, Woodcroft B, Schadt CW, et al. 2024. Borg extrachromosomal elements of methane-oxidizing archaea have conserved and expressed genetic repertoires. . Nature Communications. doi:10.1038/s41467-024-49548-8.
  • Wilson RM, Tfaily MM, Kolton M, Johnston ER, Petro C, Zalman CM, Hanson PJ, Heyman HM, Kyle JE, Hoyt DW, et al. 2021. Soil metabolome response to whole-ecosystem warming at the Spruce and Peatland Responses under Changing Environments experiment. Proceedings of the National Academy of Sciences. 118(25). doi:10.1073/pnas.2004192118.
  • Lin X, Tfaily MM, Steinweg JM, Chanton PR, Esson K, Yang ZK, Chanton JP, Cooper WT, Schadt CW, Kostka JE. 2014. Microbial Community Stratification Linked to Utilization of Carbohydrates and Phosphorus Limitation in a Boreal Peatland at Marcell Experimental Forest, Minnesota, USA. Lovell CR, editor. Applied and Environmental Microbiology. 80(11):3518–3530. doi:10.1128/aem.00205-14.
  • Wilson RM, Hopple AM, Tfaily MM, Sebestyen SD, Schadt CW, Pfeifer-Meister L, Medvedeff CA, McFarlane KJ, Kostka JE, Kolton M, et al. 2016. Stability of peatland carbon to rising temperatures. Nature Communications. 7(1). doi:10.1038/ncomms13723.
  • Salmon VG, Brice DJ, Bridgham SD, Childs J, Graham JD, Griffiths NA, Hofmockel KS, Iversen CM, Jicha TM, Kolka RK, et al. 2021. Nitrogen and phosphorus cycling in an ombrotrophic peatland: a benchmark for assessing change. Plant and Soil. 466(1-2):649–674. doi:10.1007/s11104-021-05065-x.
  • Duchesneau K, Aldeguer Riquelme B, Petro C, Makke G, Green MB, Tfaily MM, Wilson RM, Roth S, Johnston ER, Kluber LA, et al. 2025. Northern peatland microbial communities exhibit resistance to warming and acquire electron acceptors from soil organic matter. Nature Communications. doi:doi.org/10.1101/2024.07.17.603906.
  • Tfaily MM, Cooper WT, Kostka JE, Chanton PR, Schadt CW, Hanson PJ, Iversen CM, Chanton JP. 2014. Organic matter transformation in the peat column at Marcell Experimental Forest: Humification and vertical stratification. Journal of Geophysical Research: Biogeosciences. 119(4):661–675. doi:10.1002/2013jg002492.
  • Roth S, Griffiths NA, Oleheiser KC, Carrell AA, Klingeman D, Seibert A, Chanton JP, Hanson PJ, Schadt CW. 2023. Elevated temperature alters microbial communities, but not decomposition rates, during 3 years of in situ peat decomposition. . mSystems . 8:00337–23. doi:10.1128/msystems.00337-23.
  • Lin X, Tfaily MM, Green SJ, Steinweg JM, Chanton PR, Imvittaya A, Chanton JP, Cooper WT, Schadt CW, Kostka JE. 2014. Microbial Metabolic Potential for Carbon Degradation and Nutrient (Nitrogen and Phosphorus) Acquisition in an Ombrotrophic Peatland. Lovell CR, editor. Applied and Environmental Microbiology. 80(11):3531–3540. doi:10.1128/aem.00206-14.
  • Živković T, Carrell AA, Granath G, Shaw A, Pelletier DA, Schadt CW, Klingeman D, Nilsson MB, Helbig M, Warshan D, et al. 2025. Host species–microbiome interactions contribute to Sphagnum moss growth acclimation to warming. Global Change Biology. 31(2)(e70066). doi:10.1111/gcb.70066.
  • Salmon VG, Brice DJ, Bridgham SD, Childs J, Graham JD, Griffiths NA, Hofmockel KS, Iversen CM, Jicha TM, Kolka RK, et al. 2021. Nitrogen and phosphorus cycling in an ombrotrophic peatland: a benchmark for assessing change. Plant and Soil. 466(1-2):649–674. doi:10.1007/s11104-021-05065-x.
  • Ricciuto DM, Xu X, Shi X, Wang Y, Song X, Schadt CW, Griffiths NA, Mao J, Warren JM, Thornton PE, et al. 2021. An Integrative Model for Soil Biogeochemistry and Methane Processes: I. Model Structure and Sensitivity Analysis. Journal of Geophysical Research: Biogeosciences. 126(8). doi:10.1029/2019jg005468.
  • Ricciuto DM, Xu X, Shi X, Wang Y, Song X, Schadt CW, Griffiths NA, Mao J, Warren JM, Thornton PE, et al. 2021. An Integrative Model for Soil Biogeochemistry and Methane Processes: I. Model Structure and Sensitivity Analysis. Journal of Geophysical Research: Biogeosciences. 126(8). doi:10.1029/2019jg005468.
  • Warren MJ, Lin X, Gaby JC, Kretz CB, Kolton M, Morton PL, Pett-Ridge J, Weston DJ, Schadt CW, Kostka JE, et al. 2017. Molybdenum-Based Diazotrophy in a Sphagnum Peatland in Northern Minnesota. Stams AJM, editor. Applied and Environmental Microbiology. 83(17). doi:10.1128/aem.01174-17.
  • Kluber LA, Johnston ER, Allen SA, Hendershot N, Hanson PJ, Schadt CW. 2020. Constraints on microbial communities, decomposition and methane production in deep peat deposits. PLOS ONE. 15(2):e0223744. doi:10.1371/journal.pone.0223744.

Schmidt, M.

  • Torn MS, Chabbi A, Crill P, Hanson PJ, Janssens IA, Luo Y, Hicks Pries CE, Rumpel C, Schmidt MWI, Six J, et al. 2015. A call for international soil experiment networks for studying, predicting, and managing global change impacts. SOIL. 1(2):575–582. doi:10.5194/soil-1-575-2015.
  • Ofiti NOE, Schmidt MWI, Abiven S, Hanson PJ, Iversen CM, Wilson RM, Kostka JE, Wiesenberg GLB, Malhotra A. 2023. Climate warming and elevated CO2 alter peatland soil carbon sources and stability. Nature Communications . 14:7533. doi:10.1038/s41467-023-43410-z.
  • Ofiti NOE, Solly EF, Hanson PJ, Malhotra A, Wiesenberg GLB, Schmidt MWI. 2021. Warming and elevated CO <sub>2</sub> promote rapid incorporation and degradation of plant‐derived organic matter in an ombrotrophic peatland. Global Change Biology. 28(3):883–898. doi:10.1111/gcb.15955.

Schmutz, Jeremy

  • Weston DJ, Timm CM, Walker AP, Gu L, Muchero W, Schmutz J, Shaw J, Tuskan GA, Warren JM, Wullschleger SD. 2014. Sphagnum physiology in the context of changing climate: emergent influences of genomics, modelling and host–microbiome interactions on understanding ecosystem function. Plant, Cell & Environment. 38(9):1737–1751. doi:10.1111/pce.12458.
  • Carrell AA, Veličković D, Lawrence TJ, Bowen BP, Louie KB, Carper DL, Chu RK, Mitchell HD, Orr G, Markillie LM, et al. 2021. Novel metabolic interactions and environmental conditions mediate the boreal peatmoss-cyanobacteria mutualism. The ISME Journal. 16(4):1074–1085. doi:10.1038/s41396-021-01136-0.
  • Shaw J, Schmutz J, Devos N, Shu S, Carrell AA, Weston DJ. 2016. The Sphagnum Genome Project: A New Model for Ecological and Evolutionary Genomics. In: Advances in Botanical Research. Elsevier. pp. 167–187.
  • Carrell AA, Lawrence TJ, Cabugao KGM, Carper DL, Pelletier DA, Lee JH, Jawdy SS, Grimwood J, Schmutz J, Hanson PJ, et al. 2022. Habitat‐adapted microbial communities mediate Sphagnum peatmoss resilience to warming. New Phytologist. 234(6):2111–2125. doi:10.1111/nph.18072.

Schoelmerich, M

  • Schoelmerich M, Ly L, West-Roberts J, Shi L-D, Shen C, Malvankar N, Taib N, Gribaldo S, Woodcroft B, Schadt CW, et al. 2024. Borg extrachromosomal elements of methane-oxidizing archaea have conserved and expressed genetic repertoires. . Nature Communications. doi:10.1038/s41467-024-49548-8.

Schrumpf, Marion

  • Torn MS, Chabbi A, Crill P, Hanson PJ, Janssens IA, Luo Y, Hicks Pries CE, Rumpel C, Schmidt MWI, Six J, et al. 2015. A call for international soil experiment networks for studying, predicting, and managing global change impacts. SOIL. 1(2):575–582. doi:10.5194/soil-1-575-2015.

Schwaner, G

  • Petro C, Carrell AA, Wilson RM, Duchesneau K, Noble-Kuchera S, Song T, Iversen CM, Childs J, Schwaner G, Chanton JP, et al. 2023. Climate drivers alter nitrogen availability in surface peat and decouple N2 fixation from CH4 oxidation in the Sphagnum moss microbiome. . Global Change Biology . 29:3159–76. doi:10.1111/gcb.16651.

Sebestyen, Stephen

  • Ricciuto DM, Xu X, Shi X, Wang Y, Song X, Schadt CW, Griffiths NA, Mao J, Warren JM, Thornton PE, et al. 2021. An Integrative Model for Soil Biogeochemistry and Methane Processes: I. Model Structure and Sensitivity Analysis. Journal of Geophysical Research: Biogeosciences. 126(8). doi:10.1029/2019jg005468.
  • Parsekian AD, Slater L, Ntarlagiannis D, Nolan J, Sebestyen SD, Kolka RK, Hanson PJ. 2012. Uncertainty in Peat Volume and Soil Carbon Estimated Using Ground‐Penetrating Radar and Probing. Soil Science Society of America Journal. 76(5):1911–1918. doi:10.2136/sssaj2012.0040.
  • Wilson RM, Tfaily MM, Kolton M, Johnston ER, Petro C, Zalman CM, Hanson PJ, Heyman HM, Kyle JE, Hoyt DW, et al. 2021. Soil metabolome response to whole-ecosystem warming at the Spruce and Peatland Responses under Changing Environments experiment. Proceedings of the National Academy of Sciences. 118(25). doi:10.1073/pnas.2004192118.
  • Griffiths NA, Sebestyen SD. 2016. Dynamic Vertical Profiles of Peat Porewater Chemistry in a Northern Peatland. Wetlands. 36(6):1119–1130. doi:10.1007/s13157-016-0829-5.
  • Shelley SJ, Brice DJ, Iversen CM, Kolka RK, Sebestyen SD, Griffiths NA. 2021. Deciphering the shifting role of intrinsic and extrinsic drivers on moss decomposition in peatlands over a 5‐year period. Oikos. 2022(1). doi:10.1111/oik.08584.
  • Walker AP, Carter KR, Gu L, Hanson PJ, Malhotra A, Norby RJ, Sebestyen SD, Wullschleger SD, Weston DJ. 2017. Biophysical drivers of seasonal variability in Sphagnum gross primary production in a northern temperate bog. Journal of Geophysical Research: Biogeosciences. 122(5):1078–1097. doi:10.1002/2016jg003711.
  • Wilson RM, Hopple AM, Tfaily MM, Sebestyen SD, Schadt CW, Pfeifer-Meister L, Medvedeff CA, McFarlane KJ, Kostka JE, Kolton M, et al. 2016. Stability of peatland carbon to rising temperatures. Nature Communications. 7(1). doi:10.1038/ncomms13723.
  • Yuan F, Wang Y, Ricciuto DM, Shi X, Yuan F, Brehme T, Bridgham SD, Keller JK, Warren JM, Griffiths NA, et al. 2021. Hydrological feedbacks on peatland CH4 emission under warming and elevated CO2: A modeling study. Journal of Hydrology. 603:127137. doi:10.1016/j.jhydrol.2021.127137.
  • Salmon VG, Brice DJ, Bridgham SD, Childs J, Graham JD, Griffiths NA, Hofmockel KS, Iversen CM, Jicha TM, Kolka RK, et al. 2021. Nitrogen and phosphorus cycling in an ombrotrophic peatland: a benchmark for assessing change. Plant and Soil. 466(1-2):649–674. doi:10.1007/s11104-021-05065-x.
  • Pierce CE, Furman OS, Nicholas SL, Wasik JC, Gionfriddo CM, Wymore AM, Sebestyen SD, Kolka RK, Mitchell CP, Griffiths NA, et al. 2022. Role of Ester Sulfate and Organic Disulfide in Mercury Methylation in Peatland Soils. Environmental Science &amp; Technology. 56(2):1433–1444. doi:10.1021/acs.est.1c04662.
  • Hanson PJ, Griffiths NA, Iversen CM, Norby RJ, Sebestyen SD, Phillips JR, Chanton JP, Kolka RK, Malhotra A, Oleheiser KC, et al. 2020. Rapid Net Carbon Loss From a Whole‐Ecosystem Warmed Peatland. AGU Advances. 1(3). doi:10.1029/2020av000163.
  • Griffiths NA, Sebestyen SD, Oleheiser KC. 2019. Variation in peatland porewater chemistry over time and space along a bog to fen gradient. Science of The Total Environment. 697:134152. doi:10.1016/j.scitotenv.2019.134152.
  • Ricciuto DM, Xu X, Shi X, Wang Y, Song X, Schadt CW, Griffiths NA, Mao J, Warren JM, Thornton PE, et al. 2021. An Integrative Model for Soil Biogeochemistry and Methane Processes: I. Model Structure and Sensitivity Analysis. Journal of Geophysical Research: Biogeosciences. 126(8). doi:10.1029/2019jg005468.
  • Stelling JM, Sebestyen SD, Griffiths NA, Mitchell CP, Green MB. 2021. The stable isotopes of natural waters at the Marcell Experimental Forest. Hydrological Processes. 35(10). doi:10.1002/hyp.14336.
  • Curtinrich HJ, Sebestyen SD, Griffiths NA, Hall SJ. 2021. Warming Stimulates Iron-Mediated Carbon and Nutrient Cycling in Mineral-Poor Peatlands. Ecosystems. 25(1):44–60. doi:10.1007/s10021-021-00639-3.
  • Griffiths NA, Hanson PJ, Ricciuto DM, Iversen CM, Jensen AM, Malhotra A, McFarlane KJ, Norby RJ, Sargsyan K, Sebestyen SD, et al. 2017. Temporal and Spatial Variation in Peatland Carbon Cycling and Implications for Interpreting Responses of an Ecosystem-Scale Warming Experiment. Soil Science Society of America Journal. 81(6):1668–1688. doi:10.2136/sssaj2016.12.0422.
  • Salmon VG, Brice DJ, Bridgham SD, Childs J, Graham JD, Griffiths NA, Hofmockel KS, Iversen CM, Jicha TM, Kolka RK, et al. 2021. Nitrogen and phosphorus cycling in an ombrotrophic peatland: a benchmark for assessing change. Plant and Soil. 466(1-2):649–674. doi:10.1007/s11104-021-05065-x.
  • Iversen CM, Latimer JM, Brice DJ, Childs J, Vander Stel H, Defrenne CE, Graham JD, Griffiths NA, Malhotra A, Norby RJ, et al. 2022. Whole-Ecosystem Warming Increases Plant-Available Nitrogen and Phosphorus in an Ombrotrophic Bog. Ecosystems. doi:10.1007/s10021-022-00744-x.
  • Stelling JM, Sebestyen SD, Griffiths NA, Mitchell CP, Green MB. 2021. The stable isotopes of natural waters at the Marcell Experimental Forest. Hydrological Processes. 35(10). doi:10.1002/hyp.14336.
  • Wilson RM, Griffiths NA, Visser A, McFarlane KJ, Sebestyen SD, Oleheiser KC, Bosman S, Hopple AM, Tfaily MM, Kolka RK, et al. 2021. Radiocarbon Analyses Quantify Peat Carbon Losses With Increasing Temperature in a Whole Ecosystem Warming Experiment. Journal of Geophysical Research: Biogeosciences. 126(11). doi:10.1029/2021jg006511.
  • Shi X, Thornton PE, Ricciuto DM, Hanson PJ, Mao J, Sebestyen SD, Griffiths NA, Bisht G. 2015. Representing northern peatland microtopography and hydrology within the Community Land Model. Biogeosciences. 12(21):6463–6477. doi:10.5194/bg-12-6463-2015.

Sebestyen, Stephen

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  • Ricciuto DM, Xu X, Shi X, Wang Y, Song X, Schadt CW, Griffiths NA, Mao J, Warren JM, Thornton PE, et al. 2021. An Integrative Model for Soil Biogeochemistry and Methane Processes: I. Model Structure and Sensitivity Analysis. Journal of Geophysical Research: Biogeosciences. 126(8). doi:10.1029/2019jg005468.

Thorp, Nathan

  • Hobbie EA, Chen J, Hanson PJ, Iversen CM, McFarlane KJ, Thorp NR, Hofmockel KS. 2017. Long-term carbon and nitrogen dynamics at SPRUCE revealed through stable isotopes in peat profiles. Biogeosciences. 14(9):2481–2494. doi:10.5194/bg-14-2481-2017.

Timm, Collin

  • Weston DJ, Timm CM, Walker AP, Gu L, Muchero W, Schmutz J, Shaw J, Tuskan GA, Warren JM, Wullschleger SD. 2014. Sphagnum physiology in the context of changing climate: emergent influences of genomics, modelling and host–microbiome interactions on understanding ecosystem function. Plant, Cell & Environment. 38(9):1737–1751. doi:10.1111/pce.12458.

Tipping, E.

  • Tipping E, Chamberlain PM, Fröberg M, Hanson PJ, Jardine PM. 2011. Simulation of carbon cycling, including dissolved organic carbon transport, in forest soil locally enriched with 14C. Biogeochemistry. 108(1-3):91–107. doi:10.1007/s10533-011-9575-1.

Todd, Donald

  • Barbier C, Hanson PJ, Todd DE, Belcher D, Jekabson EW, Thomas WK, Riggs JS. 2013. Air Flow and Heat Transfer in a Temperature-Controlled Open Top Enclosure. Volume 7: Fluids and Heat Transfer, Parts A, B, C, and D. doi:10.1115/imece2012-86352.
  • Hanson PJ, Childs KW, Wullschleger SD, Riggs JS, Thomas WK, Todd DE, Warren JM. 2011. A method for experimental heating of intact soil profiles for application to climate change experiments. Global Change Biology. 17(2):1083–1096. doi:10.1111/j.1365-2486.2010.02221.x.

Toner, Brandy

  • Kolka RK, Pierce CE, Garrioch I, Behrens K, Toner BM. 2024. Review of the influence of climate change on the hydrologic cycling and gaseous fluxes of mercury in Boreal peatlands: Implications for restoration. Water. 16:1154. doi:10.3390/w16081154.
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Torn, M.

  • Torn MS, Chabbi A, Crill P, Hanson PJ, Janssens IA, Luo Y, Hicks Pries CE, Rumpel C, Schmidt MWI, Six J, et al. 2015. A call for international soil experiment networks for studying, predicting, and managing global change impacts. SOIL. 1(2):575–582. doi:10.5194/soil-1-575-2015.

Tringe, Susannah

  • Kolton M, Weston DJ, Mayali X, Weber PK, McFarlane KJ, Pett-Ridge J, Somoza MM, Lietard J, Glass JB, Lilleskov EA, et al. 2022. Defining the Sphagnum Core Microbiome across the North American Continent Reveals a Central Role for Diazotrophic Methanotrophs in the Nitrogen and Carbon Cycles of Boreal Peatland Ecosystems. mBio. 13(1). doi:10.1128/mbio.03714-21.
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Tuittila, E.-S

  • Helbig M, Živković T, Alekseychik P, Aurela M, El-Madany TS, Euskirchen ES, Flanagan LB, Griffis TJ, Hanson PJ, Hattakka J, et al. 2022. Warming response of peatland CO2 sink is sensitive to seasonality in warming trends. Nature Climate Change. doi:10.1038/s41558-022-01428-z.

Turetsky, Merritt

  • Turetsky MR, Weston DJ, Cox W, Petro C, Shaw A. 2025. The challenging but unique eco-evolutionary aspects of Sphagnum moss. . New Phytologist. In press . doi:10.1111/nph.70233.
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Tuskan, Gerald

  • Weston DJ, Timm CM, Walker AP, Gu L, Muchero W, Schmutz J, Shaw J, Tuskan GA, Warren JM, Wullschleger SD. 2014. Sphagnum physiology in the context of changing climate: emergent influences of genomics, modelling and host–microbiome interactions on understanding ecosystem function. Plant, Cell & Environment. 38(9):1737–1751. doi:10.1111/pce.12458.
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Ueyama, M.

  • Helbig M, Živković T, Alekseychik P, Aurela M, El-Madany TS, Euskirchen ES, Flanagan LB, Griffis TJ, Hanson PJ, Hattakka J, et al. 2022. Warming response of peatland CO2 sink is sensitive to seasonality in warming trends. Nature Climate Change. doi:10.1038/s41558-022-01428-z.

Vander Stel, Holly

  • Iversen CM, Latimer JM, Brice DJ, Childs J, Vander Stel H, Defrenne CE, Graham JD, Griffiths NA, Malhotra A, Norby RJ, et al. 2022. Whole-Ecosystem Warming Increases Plant-Available Nitrogen and Phosphorus in an Ombrotrophic Bog. Ecosystems. doi:10.1007/s10021-022-00744-x.
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Veličković, Dušan

  • Carrell AA, Veličković D, Lawrence TJ, Bowen BP, Louie KB, Carper DL, Chu RK, Mitchell HD, Orr G, Markillie LM, et al. 2021. Novel metabolic interactions and environmental conditions mediate the boreal peatmoss-cyanobacteria mutualism. The ISME Journal. 16(4):1074–1085. doi:10.1038/s41396-021-01136-0.

Vesala, T.

  • Helbig M, Živković T, Alekseychik P, Aurela M, El-Madany TS, Euskirchen ES, Flanagan LB, Griffis TJ, Hanson PJ, Hattakka J, et al. 2022. Warming response of peatland CO2 sink is sensitive to seasonality in warming trends. Nature Climate Change. doi:10.1038/s41558-022-01428-z.

Vestin, P.

  • Helbig M, Živković T, Alekseychik P, Aurela M, El-Madany TS, Euskirchen ES, Flanagan LB, Griffis TJ, Hanson PJ, Hattakka J, et al. 2022. Warming response of peatland CO2 sink is sensitive to seasonality in warming trends. Nature Climate Change. doi:10.1038/s41558-022-01428-z.

Villanueva, R

  • Dusenge M, Warren JM, Reich P, Ward EJ, Murphy B, Stefanski A, Villanueva R, Cruz M, McLennan DA, King AW, et al. 2023. Boreal conifers maintain carbon uptake with warming despite failure to track optimal temperatures. Nature Communications. 14:4667. doi:10.1038/s41467-023-40248-3.

Visser, Ate

  • Wilson RM, Griffiths NA, Visser A, McFarlane KJ, Sebestyen SD, Oleheiser KC, Bosman S, Hopple AM, Tfaily MM, Kolka RK, et al. 2021. Radiocarbon Analyses Quantify Peat Carbon Losses With Increasing Temperature in a Whole Ecosystem Warming Experiment. Journal of Geophysical Research: Biogeosciences. 126(11). doi:10.1029/2021jg006511.

Votzke, S

  • Kilner C, Carrell AA, Wieczynski D, Votzke S, De Witt K, Yammine A, Shaw J, Pelletier DA, Weston DJ, Gilbert J. 2024. Temperature and CO2 interactively drive shifts in the compositional and functional structure of peatland protist communities. . Global Change Biology 30. 30:17203. doi:10.1016/j.soilbio.2024.109316.
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Walker, Anthony

  • Weston DJ, Timm CM, Walker AP, Gu L, Muchero W, Schmutz J, Shaw J, Tuskan GA, Warren JM, Wullschleger SD. 2014. Sphagnum physiology in the context of changing climate: emergent influences of genomics, modelling and host–microbiome interactions on understanding ecosystem function. Plant, Cell & Environment. 38(9):1737–1751. doi:10.1111/pce.12458.
  • Salmon VG, Brice DJ, Bridgham SD, Childs J, Graham JD, Griffiths NA, Hofmockel KS, Iversen CM, Jicha TM, Kolka RK, et al. 2021. Nitrogen and phosphorus cycling in an ombrotrophic peatland: a benchmark for assessing change. Plant and Soil. 466(1-2):649–674. doi:10.1007/s11104-021-05065-x.
  • Hanson PJ, Walker AP. 2019. Advancing global change biology through experimental manipulations: Where have we been and where might we go?. Global Change Biology. 26(1):287–299. doi:10.1111/gcb.14894.
  • Shi X, Ricciuto DM, Thornton PE, Xu X, Yuan F, Norby RJ, Walker AP, Warren JM, Mao J, Hanson PJ, et al. 2021. Extending a land-surface model with Sphagnum moss to simulate responses of a northern temperate bog to whole ecosystem warming and elevated CO2. Biogeosciences. 18(2):467–486. doi:10.5194/bg-18-467-2021.
  • Griffiths NA, Hanson PJ, Ricciuto DM, Iversen CM, Jensen AM, Malhotra A, McFarlane KJ, Norby RJ, Sargsyan K, Sebestyen SD, et al. 2017. Temporal and Spatial Variation in Peatland Carbon Cycling and Implications for Interpreting Responses of an Ecosystem-Scale Warming Experiment. Soil Science Society of America Journal. 81(6):1668–1688. doi:10.2136/sssaj2016.12.0422.
  • Shi X, Thornton PE, Xu X, Yuan F, Norby RJ, Walker AP, Warren JM, Mao J, Hanson PJ, Meng L, et al. 2020. Modeling the hydrology and physiology of Sphagnum moss in a northern temperate bog. Biogeosciences Discussion . 2020:1–49. doi:10.5194/bg-2020-90.
  • Salmon VG, Brice DJ, Bridgham SD, Childs J, Graham JD, Griffiths NA, Hofmockel KS, Iversen CM, Jicha TM, Kolka RK, et al. 2021. Nitrogen and phosphorus cycling in an ombrotrophic peatland: a benchmark for assessing change. Plant and Soil. 466(1-2):649–674. doi:10.1007/s11104-021-05065-x.
  • Walker AP, Carter KR, Gu L, Hanson PJ, Malhotra A, Norby RJ, Sebestyen SD, Wullschleger SD, Weston DJ. 2017. Biophysical drivers of seasonal variability in Sphagnum gross primary production in a northern temperate bog. Journal of Geophysical Research: Biogeosciences. 122(5):1078–1097. doi:10.1002/2016jg003711.

Walker, Ashley

  • Gunderson CA, Edwards NT, Walker AV, O’Hara KH, Campion CM, Hanson PJ. 2012. Forest phenology and a warmer climate - growing season extension in relation to climatic provenance. Global Change Biology. 18(6):2008–2025. doi:10.1111/j.1365-2486.2011.02632.x.

Wallenstein, Matthew

  • Bell CW, Fricks BE, Rocca JD, Steinweg JM, McMahon SK, Wallenstein MD. 2013. High-throughput Fluorometric Measurement of Potential Soil Extracellular Enzyme Activities. Journal of Visualized Experiments.(81). doi:10.3791/50961.

Wang, Gangsheng

  • Liang J, Wang G, Ricciuto DM, Gu L, Hanson PJ, Wood JD, Mayes MA. 2019. Evaluating the E3SM land model version 0 (ELMv0) at a temperate forest site using flux and soil water measurements. Geoscientific Model Development. 12(4):1601–1612. doi:10.5194/gmd-12-1601-2019.

Wang, Yihui

  • Yuan F, Wang Y, Ricciuto DM, Shi X, Yuan F, Hanson PJ, Bridgham SD, Keller JK, Thornton PE, Xu X. 2021. An Integrative Model for Soil Biogeochemistry and Methane Processes. II: Warming and Elevated CO2 Effects on Peatland CH4 Emissions. Journal of Geophysical Research: Biogeosciences. 126(8). doi:10.1029/2020jg005963.
  • Ricciuto DM, Xu X, Shi X, Wang Y, Song X, Schadt CW, Griffiths NA, Mao J, Warren JM, Thornton PE, et al. 2021. An Integrative Model for Soil Biogeochemistry and Methane Processes: I. Model Structure and Sensitivity Analysis. Journal of Geophysical Research: Biogeosciences. 126(8). doi:10.1029/2019jg005468.
  • Ricciuto DM, Xu X, Shi X, Wang Y, Song X, Schadt CW, Griffiths NA, Mao J, Warren JM, Thornton PE, et al. 2021. An Integrative Model for Soil Biogeochemistry and Methane Processes: I. Model Structure and Sensitivity Analysis. Journal of Geophysical Research: Biogeosciences. 126(8). doi:10.1029/2019jg005468.
  • Yuan F, Wang Y, Ricciuto DM, Shi X, Yuan F, Brehme T, Bridgham SD, Keller JK, Warren JM, Griffiths NA, et al. 2021. Hydrological feedbacks on peatland CH4 emission under warming and elevated CO2: A modeling study. Journal of Hydrology. 603:127137. doi:10.1016/j.jhydrol.2021.127137.

Ward, Eric

  • Dusenge M, Warren JM, Reich P, Ward EJ, Murphy B, Stefanski A, Bermudez R, Cruz M, McLennan DA, King AW, et al. 2024. Photosynthetic capacity in middle-aged larch and spruce acclimates independently to experimental warming and elevated CO2. . Plant, Cell & Environment. 47(12):4886–4902. doi:10.1111/pce.15068.
  • Dusenge M, Ward EJ, Warren JM, Stinziano JR, Wullschleger SD, Hanson PJ, Way DA. 2021. Warming induces divergent stomatal dynamics in co‐occurring boreal trees. Global Change Biology. 27(13):3079–3094. doi:10.1111/gcb.15620.
  • Ward EJ, Warren JM, McLennan DA, Dusenge ME, Way DA, Wullschleger SD, Hanson PJ. 2019. Photosynthetic and Respiratory Responses of Two Bog Shrub Species to Whole Ecosystem Warming and Elevated CO2 at the Boreal-Temperate Ecotone. Frontiers in Forests and Global Change. 2. doi:10.3389/ffgc.2019.00054.
  • Warren JM, Jensen AM, Ward EJ, Guha A, Childs J, Wullschleger SD, Hanson PJ. 2021. Divergent species‐specific impacts of whole ecosystem warming and elevated CO2 on vegetation water relations in an ombrotrophic peatland. Global Change Biology. 27(9):1820–1835. doi:10.1111/gcb.15543.
  • Griffiths NA, Hanson PJ, Ricciuto DM, Iversen CM, Jensen AM, Malhotra A, McFarlane KJ, Norby RJ, Sargsyan K, Sebestyen SD, et al. 2017. Temporal and Spatial Variation in Peatland Carbon Cycling and Implications for Interpreting Responses of an Ecosystem-Scale Warming Experiment. Soil Science Society of America Journal. 81(6):1668–1688. doi:10.2136/sssaj2016.12.0422.
  • Dusenge M, Warren JM, Reich P, Ward EJ, Murphy B, Stefanski A, Villanueva R, Cruz M, McLennan DA, King AW, et al. 2023. Boreal conifers maintain carbon uptake with warming despite failure to track optimal temperatures. Nature Communications. 14:4667. doi:10.1038/s41467-023-40248-3.

Warren, Jeffrey

  • Dusenge M, Ward EJ, Warren JM, Stinziano JR, Wullschleger SD, Hanson PJ, Way DA. 2021. Warming induces divergent stomatal dynamics in co‐occurring boreal trees. Global Change Biology. 27(13):3079–3094. doi:10.1111/gcb.15620.
  • Ward EJ, Warren JM, McLennan DA, Dusenge ME, Way DA, Wullschleger SD, Hanson PJ. 2019. Photosynthetic and Respiratory Responses of Two Bog Shrub Species to Whole Ecosystem Warming and Elevated CO2 at the Boreal-Temperate Ecotone. Frontiers in Forests and Global Change. 2. doi:10.3389/ffgc.2019.00054.
  • Norby RJ, Childs J, Hanson PJ, Warren JM. 2019. Rapid loss of an ecosystem engineer: Sphagnum decline in an experimentally warmed bog. Ecology and Evolution. 9(22):12571–12585. doi:10.1002/ece3.5722.
  • Hanson PJ, Griffiths NA, Salmon VG, Birkebak J, Warren JM, Phillips JR, Guilliams M, Oleheiser KC, Jones M, Jones N, et al. 2025. Peatland plant community changes in annual production and composition through 8 years of warming manipulations under ambient and elevated CO2 atmospheres. JGR-Biogeosciences. 130.
  • Yuan F, Wang Y, Ricciuto DM, Shi X, Yuan F, Brehme T, Bridgham SD, Keller JK, Warren JM, Griffiths NA, et al. 2021. Hydrological feedbacks on peatland CH4 emission under warming and elevated CO2: A modeling study. Journal of Hydrology. 603:127137. doi:10.1016/j.jhydrol.2021.127137.
  • Richardson AD, Novick K, Basler DD, Phillips JR, Krassovski MB, Warren JM, Sebestyen SD, Hanson PJ. 2024. Experimental whole‐ecosystem warming enables novel estimation of snow cover and depth sensitivities to temperature, and quantification of the snow‐albedo feedback effect. Journal of Geophysical Research – Biogeosciences . 129:2023JG007833. doi:10.1029/2023JG007833.
  • Warren JM, Jensen AM, Ward EJ, Guha A, Childs J, Wullschleger SD, Hanson PJ. 2021. Divergent species‐specific impacts of whole ecosystem warming and elevated CO2 on vegetation water relations in an ombrotrophic peatland. Global Change Biology. 27(9):1820–1835. doi:10.1111/gcb.15543.
  • Jensen AM, Eckert D, Carter KR, Persson M, Warren JM. 2021. Springtime Drought Shifts Carbon Partitioning of Recent Photosynthates in 10-Year Old Picea mariana Trees, Causing Restricted Canopy Development. Frontiers in Forests and Global Change. 3. doi:10.3389/ffgc.2020.601046.
  • Weston DJ, Timm CM, Walker AP, Gu L, Muchero W, Schmutz J, Shaw J, Tuskan GA, Warren JM, Wullschleger SD. 2014. Sphagnum physiology in the context of changing climate: emergent influences of genomics, modelling and host–microbiome interactions on understanding ecosystem function. Plant, Cell & Environment. 38(9):1737–1751. doi:10.1111/pce.12458.
  • Ricciuto DM, Xu X, Shi X, Wang Y, Song X, Schadt CW, Griffiths NA, Mao J, Warren JM, Thornton PE, et al. 2021. An Integrative Model for Soil Biogeochemistry and Methane Processes: I. Model Structure and Sensitivity Analysis. Journal of Geophysical Research: Biogeosciences. 126(8). doi:10.1029/2019jg005468.
  • Salmon VG, Brice DJ, Bridgham SD, Childs J, Graham JD, Griffiths NA, Hofmockel KS, Iversen CM, Jicha TM, Kolka RK, et al. 2021. Nitrogen and phosphorus cycling in an ombrotrophic peatland: a benchmark for assessing change. Plant and Soil. 466(1-2):649–674. doi:10.1007/s11104-021-05065-x.
  • Richardson AD, Hufkens K, Milliman T, Aubrecht DM, Furze ME, Seyednasrollah B, Krassovski MB, Latimer JM, Nettles R, Heiderman RR, et al. 2018. Ecosystem warming extends vegetation activity but heightens vulnerability to cold temperatures. Nature. 560(7718):368–371. doi:10.1038/s41586-018-0399-1.
  • Hanson PJ, Griffiths NA, Iversen CM, Norby RJ, Sebestyen SD, Phillips JR, Chanton JP, Kolka RK, Malhotra A, Oleheiser KC, et al. 2020. Rapid Net Carbon Loss From a Whole‐Ecosystem Warmed Peatland. AGU Advances. 1(3). doi:10.1029/2020av000163.
  • Griffiths NA, Hanson PJ, Ricciuto DM, Iversen CM, Jensen AM, Malhotra A, McFarlane KJ, Norby RJ, Sargsyan K, Sebestyen SD, et al. 2017. Temporal and Spatial Variation in Peatland Carbon Cycling and Implications for Interpreting Responses of an Ecosystem-Scale Warming Experiment. Soil Science Society of America Journal. 81(6):1668–1688. doi:10.2136/sssaj2016.12.0422.
  • Shi X, Ricciuto DM, Thornton PE, Xu X, Yuan F, Norby RJ, Walker AP, Warren JM, Mao J, Hanson PJ, et al. 2021. Extending a land-surface model with Sphagnum moss to simulate responses of a northern temperate bog to whole ecosystem warming and elevated CO2. Biogeosciences. 18(2):467–486. doi:10.5194/bg-18-467-2021.
  • Jensen AM, Warren JM, King AW, Ricciuto DM, Hanson PJ, Wullschleger SD. 2019. Simulated projections of boreal forest peatland ecosystem productivity are sensitive to observed seasonality in leaf physiology. Tree Physiology. 39(4):556–572. doi:10.1093/treephys/tpy140.
  • Ofiti NOE, Altermatt M, Petibon F, Warren JM, Malhotra A, Hanson PJ, Wiesenberg GLB. 2023. Warming and elevated CO2 induced shifts in carbon partitioning and lipid composition within an ombrotrophic bog plant community. Environmental and Experimental Botany . 206:105182. doi:10.1016/j.envexpbot.2022.105182.
  • Dusenge M, Warren JM, Reich P, Ward EJ, Murphy B, Stefanski A, Villanueva R, Cruz M, McLennan DA, King AW, et al. 2023. Boreal conifers maintain carbon uptake with warming despite failure to track optimal temperatures. Nature Communications. 14:4667. doi:10.1038/s41467-023-40248-3.
  • Jensen AM, Warren JM, Hanson PJ, Childs J, Wullschleger SD. 2015. Needle age and season influence photosynthetic temperature response and total annual carbon uptake in mature Picea mariana trees. Annals of Botany. 116(5):821–832. doi:10.1093/aob/mcv115.
  • Shi X, Thornton PE, Xu X, Yuan F, Norby RJ, Walker AP, Warren JM, Mao J, Hanson PJ, Meng L, et al. 2020. Modeling the hydrology and physiology of Sphagnum moss in a northern temperate bog. Biogeosciences Discussion . 2020:1–49. doi:10.5194/bg-2020-90.
  • Ricciuto DM, Xu X, Shi X, Wang Y, Song X, Schadt CW, Griffiths NA, Mao J, Warren JM, Thornton PE, et al. 2021. An Integrative Model for Soil Biogeochemistry and Methane Processes: I. Model Structure and Sensitivity Analysis. Journal of Geophysical Research: Biogeosciences. 126(8). doi:10.1029/2019jg005468.
  • Salmon VG, Brice DJ, Bridgham SD, Childs J, Graham JD, Griffiths NA, Hofmockel KS, Iversen CM, Jicha TM, Kolka RK, et al. 2021. Nitrogen and phosphorus cycling in an ombrotrophic peatland: a benchmark for assessing change. Plant and Soil. 466(1-2):649–674. doi:10.1007/s11104-021-05065-x.
  • Hanson PJ, Riggs JS, Nettles R, Phillips JR, Krassovski MB, Hook LA, Gu L, Richardson AD, Aubrecht DM, Ricciuto DM, et al. 2017. Attaining whole-ecosystem warming using air and deep-soil heating methods with an elevated CO&lt;sub&gt;2&lt;/sub&gt; atmosphere. Biogeosciences. 14(4):861–883. doi:10.5194/bg-14-861-2017.
  • Dusenge M, Warren JM, Reich P, Ward EJ, Murphy B, Stefanski A, Bermudez R, Cruz M, McLennan DA, King AW, et al. 2024. Photosynthetic capacity in middle-aged larch and spruce acclimates independently to experimental warming and elevated CO2. . Plant, Cell & Environment. 47(12):4886–4902. doi:10.1111/pce.15068.
  • Richardson AD, Schadel C, Westergaard-Nielsen A, Novick K, Basler DD, Phillips JR, Krassovski MB, Warren JM, Sebestyen SD, Hanson PJ. 2024. Experimental whole-ecosystem warming enables novel estimation of snow cover and depth sensitivities to temperature, and quantification of the snow-albedo feedback effect. JGR Biogeosciences. 129(3):1–19. doi:10.1029/2023JG007833.
  • Hanson PJ, Childs KW, Wullschleger SD, Riggs JS, Thomas WK, Todd DE, Warren JM. 2011. A method for experimental heating of intact soil profiles for application to climate change experiments. Global Change Biology. 17(2):1083–1096. doi:10.1111/j.1365-2486.2010.02221.x.

Warren, Melissa

  • Warren MJ, Lin X, Gaby JC, Kretz CB, Kolton M, Morton PL, Pett-Ridge J, Weston DJ, Schadt CW, Kostka JE, et al. 2017. Molybdenum-Based Diazotrophy in a Sphagnum Peatland in Northern Minnesota. Stams AJM, editor. Applied and Environmental Microbiology. 83(17). doi:10.1128/aem.01174-17.
  • Schadel C, Seyednasrollah B, Hanson PJ, Hufkens K, Pearson K, Warren MJ, Richardson AD. 2023. Using long-term data from a whole ecosystem warming experiment to identify best spring and autumn phenology models. Plant Environment Interactions . 4:188–200. doi:10.1002/pei3.10118.

Warshan, D.

  • Živković T, Carrell AA, Granath G, Shaw A, Pelletier DA, Schadt CW, Klingeman D, Nilsson MB, Helbig M, Warshan D, et al. 2025. Host species–microbiome interactions contribute to Sphagnum moss growth acclimation to warming. Global Change Biology. 31(2)(e70066). doi:10.1111/gcb.70066.

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