Readings

SUGGESTED READING

A community sourced list of publications to read

Selected papers from this bibliography can be listed in the website as ‘suggested readings’ along with our sapfluxnet papers (including pre-prints).
Papers are tagged depending on the specific workshop question(s) they address. If untagged, they provide useful context or tools that can’t be unequivocally assigned to any of the questions.

Transversal topics (can be associated to any of the 3 questions)

In brackets, tags linking to papers below:

• Matching plant, site and grid-cell scales [scales]
• Context of global syntheses on plant and ecosystem functioning [synthesis]
• Improvements in SAPFLUXNET as a global network [network]
  
  

Cranko Page J, De Kauwe MG, Abramowitz G, Cleverly J, Hinko-Najera N, Hovenden MJ, Liu Y, Pitman AJ, Ogle K. 2021. Examining the Role of Environmental Memory in the Predictability of Carbon and Water Fluxes Across Australian Ecosystems. Biogeosciences Discussions 1–29. https://doi.org/10.5194/bg-2021-254

Liu Y, Schwalm CR, Samuels-Crow KE, Ogle K. 2019. Ecological memory of daily carbon exchange across the globe and its importance in drylands. Ecology Letters 22(11): 1806–1816. https://doi.org/10.1111/ele.13363

Maes WH, Pagán BR, Martens B, Gentine P, Guanter L, Steppe K, Verhoest NEC, Dorigo W, Li X, Xiao J, Miralles, DG 2020. Sun-induced fluorescence closely linked to ecosystem transpiration as evidenced by satellite data and radiative transfer models. Remote Sensing of Environment 249 112030. https://doi.org/10.1016/j.rse.2020.112030

Zhang Y, Keenan TF, Zhou S. 2021. Exacerbated drought impacts on global ecosystems due to structural overshoot. Nature Ecology & Evolution 1–9. https://doi.org/10.1038/s41559-021-01551-8

Migliavacca, M., et al. 2021. The three major axes of terrestrial ecosystem function. Nature 1–5. https://doi.org/10.1038/s41586-021-03939-9 [synthesis]

Kannenberg SA, Schwalm CR, Anderegg WRL. 2020. Ghosts of the past: how drought legacy effects shape forest functioning and carbon cycling. Ecology Letters 23: 891–901. [Q1]

Schwalm CR, Anderegg WRL, Michalak AM, Fisher JB, Biondi F, Koch G, Litvak M, Ogle K, Shaw JD, Wolf A, et al. 2017. Global patterns of drought recovery. Nature 548: 202–205. [Q1]

Jiao T, Williams CA, Kauwe MGD, Schwalm CR, Medlyn BE. 2021. Patterns of post-drought recovery are strongly influenced by drought duration, frequency, post-drought wetness, and bioclimatic setting. Global Change Biology 27: 4630–4643. [Q1]

Zhang S, Yang Y, Wu X, Li X, Shi F. 2021. Postdrought Recovery Time Across Global Terrestrial Ecosystems. Journal of Geophysical Research: Biogeosciences 126: e2020JG005699. [Q1]

Yin J, Bauerle TL. 2017. A global analysis of plant recovery performance from water stress. Oikos 126: 1377–1388. [Q1]

Liu L, Zhang Y, Wu S, Li S, Qin D. 2018. Water memory effects and their impacts on global vegetation productivity and resilience. Scientific Reports 8: 2962. [Q1]

Ingrisch J, Bahn M. 2018. Towards a Comparable Quantification of Resilience. Trends in Ecology & Evolution 33: 251–259. [Q1]

Konings AG, Saatchi SS, Frankenberg C, Keller M, Leshyk V, Anderegg WRL, Humphrey V, Matheny AM, Trugman A, Sack L, et al. 2021. Detecting Forest Response to Droughts with Global Observations of Vegetation Water Content. Global Change Biology n/a. [Q1]

Feldman AF, Gianotti DJS, Trigo IF, Salvucci GD, Entekhabi D. 2020. Land-Atmosphere Drivers of Landscape-Scale Plant Water Content Loss. Geophysical Research Letters 47: e2020GL090331. [Q1]

Feldman AF, Short Gianotti DJ, Konings AG, McColl KA, Akbar R, Salvucci GD, Entekhabi D. 2018. Moisture pulse-reserve in the soil-plant continuum observed across biomes. Nature Plants 4: 1026–1033. [Q1]

Anderegg WRL, Venturas MD. 2020. Plant hydraulics play a critical role in Earth system fluxes. New Phytologist 226: 1535–1538.[Q2]

Sabot MEB, Kauwe MGD, Pitman AJ, Medlyn BE, Verhoef A, Ukkola AM, Abramowitz G. 2020. Plant profit maximization improves predictions of European forest responses to drought. New Phytologist 226: 1638–1655. [Q2]

Eller CB, Rowland L, Mencuccini M, Rosas T, Williams K, Harper A, Medlyn BE, Wagner Y, Klein T, Teodoro GS, et al. 2020. Stomatal optimization based on xylem hydraulics (SOX) improves land surface model simulation of vegetation responses to climate. New Phytologist 226: 1622–1637. [Q2]

Liu Y, Kumar M, Katul GG, Feng X, Konings AG. 2020. Plant hydraulics accentuates the effect of atmospheric moisture stress on transpiration. Nature Climate Change 10: 691–695. [Q2]

Sloan BP, Thompson SE, Feng X. 2021. Plant hydraulic transport controls transpiration sensitivity to soil water stress. Hydrology and Earth System Sciences 25: 4259–4274. [Q2]

Liu Y, Holtzman NM, Konings AG. 2021a. Global ecosystem-scale plant hydraulic traits retrieved using model–data fusion. Hydrology and Earth System Sciences 25: 2399–2417. [Q3]

Liu Y, Konings AG, Kennedy D, Gentine P. 2021b. Global Coordination in Plant Physiological and Rooting Strategies in Response to Water Stress. Global Biogeochemical Cycles 35: e2020GB006758. [Q3]

Gallagher RV, Falster DS, Maitner BS, Salguero-Gómez R, Vandvik V, Pearse WD, Schneider FD, Kattge J, Poelen JH, Madin JS, Ankenbrand MJ, Penone C, Feng X, Adams VM, Alroy J, Andrew SC, Balk MA, Bland LM, Boyle BL, … Enquist BJ. 2020. Open Science principles for accelerating trait-based science across the Tree of Life. Nature Ecology & Evolution 1–10. https://doi.org/10.1038/s41559-020-1109-6 [network]

Novick KA, Biederman JA, Desai AR, Litvak ME, Moore DJP, Scott RL, Torn MS. 2018. The AmeriFlux network: A coalition of the willing. Agricultural and Forest Meteorology 249: 444–456. https://doi.org/10.1016/j.agrformet.2017.10.009 [network]

Fer, et al. 2021, Beyond ecosystem modeling: A roadmap to community cyberinfrastructure for ecological data-model integration. Global Change Biology 27: 13–26. https://doi.org/10.1111/gcb.15409 [network]

SAPFLUXNET Core Team
sapfluxnet@creaf.uab.cat