Carbon residence time dominates uncertainty in terrestrial vegetation responses to future climate and atmospheric CO2 AD Friend, W Lucht, TT Rademacher, R Keribin, R Betts, P Cadule, ... Proceedings of the National Academy of Sciences 111 (9), 3280-3285, 2014 | 579 | 2014 |
Belowground consequences of vegetation change and their treatment in models RB Jackson, HJ Schenk, EG Jobbagy, J Canadell, GD Colello, ... Ecological applications 10 (2), 470-483, 2000 | 521 | 2000 |
Modeling root water uptake in hydrological and climate models RA Feddes, H Hoff, M Bruen, T Dawson, P De Rosnay, P Dirmeyer, ... Bulletin of the American meteorological society 82 (12), 2797-2810, 2001 | 498 | 2001 |
Non-equilibrium thermodynamics and the production of entropy: life, earth, and beyond A Kleidon, RD Lorenz Springer Science & Business Media, 2004 | 390 | 2004 |
A green planet versus a desert world: Estimating the maximum effect of vegetation on the land surface climate A Kleidon, K Fraedrich, M Heimann Climatic Change 44, 471-493, 2000 | 268 | 2000 |
A global distribution of biodiversity inferred from climatic constraints: results from a process‐based modelling study A Kleidon, HA Mooney Global Change Biology 6 (5), 507-523, 2000 | 245 | 2000 |
The Jena Diversity-Dynamic Global Vegetation Model (JeDi-DGVM): a diverse approach to representing terrestrial biogeography and biogeochemistry based on plant functional trade-offs R Pavlick, DT Drewry, K Bohn, B Reu, A Kleidon Biogeosciences 10 (6), 4137-4177, 2013 | 228 | 2013 |
Maximum entropy production in environmental and ecological systems A Kleidon, Y Malhi, PM Cox Philosophical transactions of the royal society B: Biological Sciences 365 …, 2010 | 201 | 2010 |
Life, hierarchy, and the thermodynamic machinery of planet Earth A Kleidon Physics of life reviews 7 (4), 424-460, 2010 | 200 | 2010 |
Nonequilibrium thermodynamics and maximum entropy production in the Earth system: applications and implications A Kleidon Naturwissenschaften 96 (6), 1-25, 2009 | 197 | 2009 |
A method of determining rooting depth from a terrestrial biosphere model and its impacts on the global water and carbon cycle A Kleidon, M Heimann Global Change Biology 4 (3), 275-286, 1998 | 178 | 1998 |
Assessing the role of deep rooted vegetation in the climate system with model simulations: mechanism, comparison to observations and implications for Amazonian deforestation A Kleidon, M Heimann Climate Dynamics 16, 183-199, 2000 | 162 | 2000 |
Estimating impacts of lichens and bryophytes on global biogeochemical cycles P Porada, B Weber, W Elbert, U Pöschl, A Kleidon Global Biogeochemical Cycles 28 (2), 71-85, 2014 | 149 | 2014 |
Beyond Gaia: Thermodynamics of life and Earth system functioning A Kleidon Climatic Change 66 (3), 271-319, 2004 | 147 | 2004 |
Estimating maximum global land surface wind power extractability and associated climatic consequences LM Miller, F Gans, A Kleidon Earth system dynamics 2 (1), 1-12, 2011 | 132 | 2011 |
Estimating global carbon uptake by lichens and bryophytes with a process-based model P Porada, B Weber, W Elbert, U Pöschl, A Kleidon Biogeosciences 10 (11), 6989-7033, 2013 | 131 | 2013 |
Thermodynamic foundations of the Earth system A Kleidon Cambridge University Press, 2016 | 123 | 2016 |
Advancing catchment hydrology to deal with predictions under change U Ehret, HV Gupta, M Sivapalan, SV Weijs, SJ Schymanski, G Blöschl, ... Hydrology and Earth System Sciences 18 (2), 649-671, 2014 | 121 | 2014 |
How does the Earth system generate and maintain thermodynamic disequilibrium and what does it imply for the future of the planet? A Kleidon Philosophical Transactions of the Royal Society A: Mathematical, Physical …, 2012 | 114 | 2012 |
Significant contribution of non-vascular vegetation to global rainfall interception P Porada, JT Van Stan, A Kleidon Nature Geoscience 11 (8), 563-567, 2018 | 112 | 2018 |