论文信息 - Increased control of vegetation on global terrestrial energy fluxes - 字舞流文

Increased control of vegetation on global terrestrial energy fluxes

Changes in vegetation structure are expected to influence the redistribution of heat and moisture; however, how variations in the leaf area index (LAI) affect this global energy partitioning is not yet quantified. Here, we estimate that a unit change in LAI leads to 3.66 ± 0.45 and −3.26 ± 0.41 W m −2 in latent (LE) and sensible ( H ) fluxes, respectively, over the 1982–2016 period. Analysis of an ensemble of data-driven products shows that these sensitivities increase by about 20% over the observational period, prominently in regions with a limited water supply, probably because of an increased transpiration/evaporation ratio. Global greening has caused a decrease in the Bowen ratio ( B = H /LE) of −0.010 ± 0.002 per decade, which is attributable to the increased evaporative surface. Such a direct LAI effect on energy fluxes is largely modulated by plant functional types (PFTs) and background climate conditions. Land surface models (LSMs) misrepresent this vegetation control, possibly due to underestimation of the biophysical responses to changes in the water availability and poor representation of LAI dynamics. Changes in the leaf area index alter the distribution of heat and moisture. The change in energy partitioning related to leaf area, increasing latent and decreasing sensible fluxes over the observational period 1982–2016, is moderated by plant functional type and background climate.

Ke Zhang | Daniel S. Goll | Philippe Ciais | Shilong Piao | Pierre Friedlingstein | Stephen Sitch | Guido Ceccherini | Diego G. Miralles | Brecht Martens | Youngryel Ryu | Alessandro Cescatti | Giovanni Forzieri | Etsushi Kato | Hanqin Tian | Almut Arneth | Vivek K. Arora | Goran Georgievski | Julia Pongratz | Eddy Robertson | Andy Wiltshire | Chongya Jiang | Danica Lombardozzi | Wei Li | Peter Anthoni | Julia E. M. S. Nabel | H. Tian | A. Arneth | P. Ciais | S. Lienert | P. Friedlingstein | Kecheng Zhang | S. Piao | S. Sitch | Y. Ryu | A. Cescatti | G. Ceccherini | P. Anthoni | G. Forzieri | V. Arora | R. Alkama | Etsushi Kato | Chongya Jiang | J. Pongratz | G. Georgievski | A. Wiltshire | D. Miralles | B. Martens | M. Kautz | D. Goll | D. Lombardozzi | J. Nabel | G. Duveiller | E. Robertson | Wei Li | P. Lawrence | Gregory Duveiller | Ramdane Alkama | Markus Kautz | Sebastian Lienert | Peter Lawrence | Sebastian Lienert

[1] Pierre Gentine,et al. Probability of afternoon precipitation in eastern United States and Mexico enhanced by high evaporation , 2011 .

[2] Hans Peter Schmid,et al. Increase in forest water-use efficiency as atmospheric carbon dioxide concentrations rise , 2013, Nature.

[3] W. Köppen,et al. Die Klimate der Erde : Grundriss der Klimakunde , 1923 .

[4] A. Cescatti,et al. Response to Comment on “Satellites reveal contrasting responses of regional climate to the widespread greening of Earth” , 2018, Science.

[5] Paul A. Dirmeyer,et al. The terrestrial segment of soil moisture–climate coupling , 2011 .

[6] Pierre Gentine,et al. Land–atmospheric feedbacks during droughts and heatwaves: state of the science and current challenges , 2018, Annals of the New York Academy of Sciences.

[7] M. Torn,et al. The influence of land cover on surface energy partitioning and evaporative fraction regimes in the U.S. Southern Great Plains , 2017 .

[8] Y. Hong,et al. Vegetation Greening and Climate Change Promote Multidecadal Rises of Global Land Evapotranspiration , 2015, Scientific Reports.

[9] A. Pitman. The evolution of, and revolution in, land surface schemes designed for climate models , 2003 .

[10] A. Prokushkin,et al. Critical analysis of root : shoot ratios in terrestrial biomes , 2006 .

[11] M. Lomas,et al. Evaluation of terrestrial carbon cycle models for their response to climate variability and to CO2 trends , 2013, Global change biology.

[12] Youngryel Ryu,et al. Multi-scale evaluation of global gross primary productivity and evapotranspiration products derived from Breathing Earth System Simulator (BESS) , 2016 .

[13] V. Brovkin,et al. China and India lead in greening of the world through land-use management , 2019, Nature Sustainability.

[14] N. Verhoest,et al. GLEAM v3: satellite-based land evaporation and root-zone soil moisture , 2016 .

[15] P. Ciais,et al. Partitioning global land evapotranspiration using CMIP5 models constrained by observations , 2018, Nature Climate Change.

[16] Jindi Wang,et al. Long-Time-Series Global Land Surface Satellite Leaf Area Index Product Derived From MODIS and AVHRR Surface Reflectance , 2016, IEEE Transactions on Geoscience and Remote Sensing.

[17] G. Bonan. Forests and Climate Change: Forcings, Feedbacks, and the Climate Benefits of Forests , 2008, Science.

[18] R. B. Jackson,et al. Biophysical considerations in forestry for climate protection , 2011 .

[19] Alessandro Anav,et al. Global Data Sets of Vegetation Leaf Area Index (LAI)3g and Fraction of Photosynthetically Active Radiation (FPAR)3g Derived from Global Inventory Modeling and Mapping Studies (GIMMS) Normalized Difference Vegetation Index (NDVI3g) for the Period 1981 to 2011 , 2013, Remote. Sens..

[20] Ranga B. Myneni,et al. Climate mitigation from vegetation biophysical feedbacks during the past three decades , 2017 .

[21] R. Pielke. Influence of the spatial distribution of vegetation and soils on the prediction of cumulus Convective rainfall , 2001 .

[22] W. Oechel,et al. Energy partitioning between latent and sensible heat flux during the warm season at FLUXNET sites , 2002 .

[23] Atul K. Jain,et al. Widespread seasonal compensation effects of spring warming on northern plant productivity , 2018, Nature.

[24] Christopher O. Justice,et al. A 30+ Year AVHRR LAI and FAPAR Climate Data Record: Algorithm Description and Validation , 2016, Remote. Sens..

[25] S. Seneviratne,et al. Recent decline in the global land evapotranspiration trend due to limited moisture supply , 2010, Nature.

[26] A. Arneth,et al. Evaluating the Interplay Between Biophysical Processes and Leaf Area Changes in Land Surface Models , 2018, Journal of advances in modeling earth systems.

[27] Hongliang Fang,et al. Inconsistencies of interannual variability and trends in long‐term satellite leaf area index products , 2017, Global change biology.

[28] A. Arneth,et al. Global patterns of land-atmosphere fluxes of carbon dioxide, latent heat, and sensible heat derived from eddy covariance, satellite, and meteorological observations , 2011 .

[29] T. Holmes,et al. Global land-surface evaporation estimated from satellite-based observations , 2010 .

[30] Shilong Piao,et al. Response of terrestrial evapotranspiration to Earth's greening , 2018, Current Opinion in Environmental Sustainability.

[31] J. Thepaut,et al. The ERA‐Interim reanalysis: configuration and performance of the data assimilation system , 2011 .

[32] R. Fensholt,et al. Evaluating temporal consistency of long-term global NDVI datasets for trend analysis , 2015 .

[33] Petra Döll,et al. A global data set of the extent of irrigated land from 1900 to 2005 , 2014 .

[34] A. Arneth,et al. Biophysics and vegetation cover change: a process-based evaluation framework for confronting land surface models with satellite observations , 2018, Earth System Science Data.

[35] Xiaolin Zhu,et al. Plant phenology and global climate change: Current progresses and challenges , 2019, Global change biology.

[36] J. Canadell,et al. Greening of the Earth and its drivers , 2016 .

[37] B. Cook,et al. Phenological versus meteorological controls on land‐atmosphere water and carbon fluxes , 2013 .

[38] J. Canadell,et al. Recent increases in terrestrial carbon uptake at little cost to the water cycle , 2017, Nature Communications.

[39] Steven J. Phipps,et al. Importance of background climate in determining impact of land-cover change on regional climate , 2011 .

[40] J. Abatzoglou,et al. Tracking the rhythm of the seasons in the face of global change: phenological research in the 21st century. , 2009 .

[41] Margaret S. Torn,et al. Vegetation controls on surface heat flux partitioning, and land‐atmosphere coupling , 2015 .

[42] Darrel L. Williams,et al. BOREAS in 1997: Experiment overview, scientific results, and future directions , 1997 .

[43] A. Dai. Increasing drought under global warming in observations and models , 2013 .

[44] Chris Funk,et al. Projections of leaf area index in earth system models , 2016 .

[45] Atul K. Jain,et al. Global Carbon Budget 2018 , 2014, Earth System Science Data.

[46] J. Berry,et al. Stomata: key players in the earth system, past and present. , 2010, Current opinion in plant biology.

[47] Yi Y. Liu,et al. Multi-decadal trends in global terrestrial evapotranspiration and its components , 2016, Scientific Reports.

[48] M. Sale,et al. An analytical method for predicting surface soil moisture from rainfall observations , 2003 .

[49] B. Rudolf,et al. World Map of the Köppen-Geiger climate classification updated , 2006 .

[50] Alessandro Cescatti,et al. Satellites reveal contrasting responses of regional climate to the widespread greening of Earth , 2017, Science.

[51] W. Oechel,et al. FLUXNET: A New Tool to Study the Temporal and Spatial Variability of Ecosystem-Scale Carbon Dioxide, Water Vapor, and Energy Flux Densities , 2001 .

[52] Y. Fan,et al. Global Patterns of Groundwater Table Depth , 2013, Science.

[53] S. Seneviratne,et al. Investigating soil moisture-climate interactions in a changing climate: A review , 2010 .

[54] Bin Tan,et al. Interannual variations and trends in global land surface phenology derived from enhanced vegetation index during 1982–2010 , 2014, International Journal of Biometeorology.

[55] S. Seneviratne,et al. Global intercomparison of 12 land surface heat flux estimates , 2011 .