Global and Zonal‐Mean Hydrological Response to Early Eocene Warmth

Earth's hydrological cycle is expected to intensify in response to global warming, with a “wet‐gets‐wetter, dry‐gets‐drier” response anticipated over the ocean. Subtropical regions (∼15°–30°N/S) are predicted to become drier, yet proxy evidence from past warm climates suggests these regions may be characterized by wetter conditions. Here we use an integrated data‐modeling approach to reconstruct global and zonal‐mean rainfall patterns during the early Eocene (∼56–48 million years ago). The Deep‐Time Model Intercomparison Project (DeepMIP) model ensemble indicates that the mid‐ (30°–60°N/S) and high‐latitudes (>60°N/S) are characterized by a thermodynamically dominated hydrological response to warming and overall wetter conditions. The tropical band (0°–15°N/S) is also characterized by wetter conditions, with several DeepMIP models simulating narrowing of the Inter‐Tropical Convergence Zone. However, the latter is not evident from the proxy data. The subtropics are characterized by negative precipitation‐evaporation anomalies (i.e., drier conditions) in the DeepMIP models, but there is surprisingly large inter‐model variability in mean annual precipitation (MAP). Intriguingly, we find that models with weaker meridional temperature gradients (e.g., CESM, GFDL) are characterized by a reduction in subtropical moisture divergence, leading to an increase in MAP. These model simulations agree more closely with our new proxy‐derived precipitation reconstructions and other key climate metrics and imply that the early Eocene was characterized by reduced subtropical moisture divergence. If the meridional temperature gradient was even weaker than suggested by those DeepMIP models, circulation‐induced changes may have outcompeted thermodynamic changes, leading to wetter subtropics. This highlights the importance of accurately reconstructing zonal temperature gradients when reconstructing past rainfall patterns.

[1]  J. Tierney,et al.  Expansion and Intensification of the North American Monsoon During the Pliocene , 2022, AGU Advances.

[2]  J. Tierney,et al.  Spatial patterns of climate change across the Paleocene–Eocene Thermal Maximum , 2022, Proceedings of the National Academy of Sciences of the United States of America.

[3]  T. Stocker,et al.  Ambitious partnership needed for reliable climate prediction , 2022, Nature Climate Change.

[4]  D. Lunt,et al.  Plant Proxy Evidence for High Rainfall and Productivity in the Eocene of Australia , 2022, Paleoceanography and Paleoclimatology.

[5]  B. Otto‐Bliesner,et al.  African Hydroclimate During the Early Eocene From the DeepMIP Simulations , 2022, Paleoceanography and paleoclimatology.

[6]  W. Peltier,et al.  Past terrestrial hydroclimate sensitivity controlled by Earth system feedbacks , 2022, Nature Communications.

[7]  M. Huber,et al.  The latitudinal temperature gradient and its climate dependence as inferred from foraminiferal δ18O over the past 95 million years , 2022, Proceedings of the National Academy of Sciences of the United States of America.

[8]  Corinne Le Quéré,et al.  Climate Change 2013: The Physical Science Basis , 2013 .

[9]  C. A. Riihimaki,et al.  Simulating Miocene Warmth: Insights From an Opportunistic Multi‐Model Ensemble (MioMIP1) , 2021, Paleoceanography and Paleoclimatology.

[10]  P. Valdes,et al.  A Middle Eocene lowland humid subtropical “Shangri-La” ecosystem in central Tibet , 2020, Proceedings of the National Academy of Sciences.

[11]  Yulong Xie,et al.  Early Eocene southern China dominated by desert: Evidence from a palynological record of the Hengyang Basin, Hunan Province , 2020 .

[12]  R. Spicer,et al.  Woody dicot leaf traits as a palaeoclimate proxy: 100 years of development and application , 2020 .

[13]  S. Bernasconi,et al.  Spatial pattern of super-greenhouse warmth controlled by elevated specific humidity , 2020, Nature Geoscience.

[14]  R. Wilkinson,et al.  Global mean surface temperature and climate sensitivity of the early Eocene Climatic Optimum (EECO), Paleocene–Eocene Thermal Maximum (PETM), and latest Paleocene , 2020, Climate of the Past.

[15]  A. Pendergrass The Global‐Mean Precipitation Response to CO2‐Induced Warming in CMIP6 Models , 2020, Geophysical Research Letters.

[16]  P. Pearson,et al.  Proxy evidence for state-dependence of climate sensitivity in the Eocene greenhouse , 2020, Nature Communications.

[17]  D. Greenwood,et al.  Paleobotanical proxies for early Eocene climates and ecosystems in northern North America from middle to high latitudes , 2020 .

[18]  B. Tian,et al.  The Double‐ITCZ Bias in CMIP3, CMIP5, and CMIP6 Models Based on Annual Mean Precipitation , 2020, Geophysical Research Letters.

[19]  D. Jarzen,et al.  Paleocene–Eocene Palynomorphs from the Chicxulub Impact Crater, Mexico. Part 2: Angiosperm Pollen , 2020, Palynology.

[20]  P. Valdes,et al.  DeepMIP: Model intercomparison of early Eocene climatic optimum (EECO) large-scale climate features and comparison with proxy data , 2020, Climate of the Past.

[21]  Huayu Lu,et al.  Asian monsoon rainfall variation during the Pliocene forced by global temperature change , 2019, Nature Communications.

[22]  S. Bajpai,et al.  Palynofloral diversity and palaeoenvironments of early Eocene Akri lignite succession, Kutch Basin, western India , 2019, Palaeobiodiversity and Palaeoenvironments.

[23]  J. Tierney,et al.  Simulation of Eocene extreme warmth and high climate sensitivity through cloud feedbacks , 2019, Science Advances.

[24]  M. Schmitz,et al.  Evidence for subtropical warmth in the Canadian Arctic (Beaufort-Mackenzie, Northwest Territories, Canada) during the early Eocene , 2019, Circum-Arctic Structural Events: Tectonic Evolution of the Arctic Margins and Trans-Arctic Links with Adjacent Orogens.

[25]  R. Feng,et al.  Ecological and hydroclimate responses to strengthening of the Hadley circulation in South America during the Late Miocene cooling , 2019, Proceedings of the National Academy of Sciences.

[26]  Stefan Schouten,et al.  Arctic vegetation, temperature, and hydrology during Early Eocene transient global warming events , 2018, Global and Planetary Change.

[27]  Heleen de Coninck,et al.  Technical Summary. In: Global Warming of 1.5°C. An IPCC Special Report on the impacts of global warming of 1.5°C above pre-industrial levels and related global greenhouse gas emission pathways , 2018 .

[28]  Tannecia S. Stephenson,et al.  Chapter 3: Impacts of 1.5ºC global warming on natural and human systems , 2018 .

[29]  Nicholas Siler,et al.  Revisiting the surface-energy-flux perspective on the sensitivity of global precipitation to climate change , 2018, Climate Dynamics.

[30]  M. Huber,et al.  Synchronous tropical and polar temperature evolution in the Eocene , 2018, Nature.

[31]  Michel Crucifix,et al.  The PMIP4 contribution to CMIP6 – Part 1: Overview and over-arching analysis plan , 2018 .

[32]  P. Valdes,et al.  Eocene greenhouse climate revealed by coupled clumped isotope-Mg/Ca thermometry , 2018, Proceedings of the National Academy of Sciences.

[33]  J. Zachos,et al.  Subtropical sea-surface warming and increased salinity during Eocene Thermal Maximum 2 , 2017 .

[34]  A. Fedorov,et al.  Wetter subtropics in a warmer world: Contrasting past and future hydrological cycles , 2017, Proceedings of the National Academy of Sciences.

[35]  P. Valdes,et al.  Open Research Online Hydrological and associated biogeochemical consequences of rapid global warming during the Paleocene-Eocene Thermal Maximum , 2018 .

[36]  R. Spicer,et al.  Eocene–early Oligocene climate and vegetation change in southern China: Evidence from the Maoming Basin , 2017 .

[37]  F. Baudin,et al.  Subtropical climate conditions and mangrove growth in Arctic Siberia during the early Eocene , 2017 .

[38]  Gregory J. L. Tourte,et al.  The DeepMIP contribution to PMIP4 , 2017 .

[39]  R. Müller,et al.  Global plate boundary evolution and kinematics since the late Paleozoic , 2016 .

[40]  T. Schneider,et al.  Energetic Constraints on the Width of the Intertropical Convergence Zone , 2016 .

[41]  Maria Seton,et al.  The GPlates Portal: Cloud-Based Interactive 3D Visualization of Global Geophysical and Geological Data in a Web Browser , 2016, PloS one.

[42]  J. Kiehl,et al.  A model-model and data-model comparison for the early Eocene 1 hydrological cycle 2 , 2022 .

[43]  R. Drysdale,et al.  Pliocene reversal of late Neogene aridification , 2016, Proceedings of the National Academy of Sciences.

[44]  Veronika Eyring,et al.  Overview of the Coupled Model Intercomparison Project Phase 6 (CMIP6) experimental design and organization , 2015 .

[45]  P. O’Gorman,et al.  The Response of Precipitation Minus Evapotranspiration to Climate Warming: Why the “Wet-Get-Wetter, Dry-Get-Drier” Scaling Does Not Hold over Land , 2015 .

[46]  P. Valdes,et al.  Leaf form-climate relationships on the global stage: an ensemble of characters , 2015 .

[47]  D. Greenwood,et al.  Was the Arctic Eocene 'rainforest' monsoonal? Estimates of seasonal precipitation from early Eocene megafloras from Ellesmere Island, Nunavut , 2015 .

[48]  G. Aleksandrova,et al.  Palynological and paleobotanical investigations of Paleogene sections in the Maoming basin, South China , 2015, Stratigraphy and Geological Correlation.

[49]  R. Spicer,et al.  Deriving temperature estimates from Southern Hemisphere leaves , 2014 .

[50]  R. Spicer,et al.  Cool equatorial terrestrial temperatures and the South Asian monsoon in the Early Eocene: Evidence from the Gurha Mine, Rajasthan, India , 2014 .

[51]  R. Müller,et al.  A Suite of Early Eocene (~55 Ma) Climate Model Boundary Conditions , 2014 .

[52]  P. Pearson,et al.  Early Paleogene evolution of terrestrial climate in the SW Pacific, Southern New Zealand , 2013 .

[53]  R. Seager,et al.  Diagnostic Computation of Moisture Budgets in the ERA-Interim Reanalysis with Reference to Analysis of CMIP-Archived Atmospheric Model Data , 2013 .

[54]  D. Cantrill,et al.  Early Eocene fossil plants from the Mwadui kimberlite pipe, Tanzania , 2013 .

[55]  G. Ramstein,et al.  Mid-Pliocene East Asian monsoon climate simulated in the PlioMIP , 2013 .

[56]  C. Fléhoc,et al.  Paleohydrological and paleoenvironmental changes recorded in terrestrial sediments of the Paleocene-Eocene boundary (Normandy, France) , 2013 .

[57]  F. A. McInerney,et al.  Paleohydrologic response to continental warming during the Paleocene–Eocene Thermal Maximum, Bighorn Basin, Wyoming , 2013 .

[58]  R. Knox,et al.  Marine and terrestrial environmental changes in NW Europe preceding carbon release at the Paleocene–Eocene transition , 2012 .

[59]  Claire E Huck,et al.  Persistent near-tropical warmth on the Antarctic continent during the early Eocene epoch , 2012, Nature.

[60]  A. Lotter,et al.  Coeval Eocene blooms of the freshwater fern Azolla in and around Arctic and Nordic seas , 2012 .

[61]  P. Pearson,et al.  Changes in the hydrological cycle in tropical East Africa during the Paleocene-Eocene Thermal Maximum , 2012 .

[62]  Nathan J B Kraft,et al.  Sensitivity of leaf size and shape to climate: global patterns and paleoclimatic applications. , 2011, The New phytologist.

[63]  D. Jarzen,et al.  A Preliminary Investigation of a Lower to Middle Eocene Palynoflora from Pine Island, Florida, USA , 2010 .

[64]  Stefan Schouten,et al.  Southern ocean warming, sea level and hydrological change during the Paleocene-Eocene thermal maximum , 2010 .

[65]  Naomi Naik,et al.  Thermodynamic and Dynamic Mechanisms for Large-Scale Changes in the Hydrological Cycle in Response to Global Warming* , 2010 .

[66]  C. Labandeira,et al.  Late Paleocene fossils from the Cerrejón Formation, Colombia, are the earliest record of Neotropical rainforest , 2009, Proceedings of the National Academy of Sciences.

[67]  Michel Brunet,et al.  Chad Basin: Paleoenvironments of the Sahara since the Late Miocene , 2009 .

[68]  E. Schrank,et al.  Upper Cretaceous to Neogene Palynology of the Melut Basin, Southeast Sudan , 2008 .

[69]  Milton Rueda,et al.  THE PALYNOLOGY OF THE CERREJÓN FORMATION (UPPER PALEOCENE) OF NORTHERN COLOMBIA , 2007 .

[70]  K. Freeman,et al.  Magnitude of the carbon isotope excursion at the Paleocene-Eocene thermal maximum: The role of plant community change , 2007 .

[71]  M. Kraus,et al.  Transient drying during the Paleocene–Eocene Thermal Maximum (PETM): Analysis of paleosols in the bighorn basin, Wyoming , 2007 .

[72]  B. Soden,et al.  Robust Responses of the Hydrological Cycle to Global Warming , 2006 .

[73]  M. Huber,et al.  Arctic hydrology during global warming at the Palaeocene/Eocene thermal maximum , 2006, Nature.

[74]  M. Huber,et al.  Episodic fresh surface waters in the Eocene Arctic Ocean , 2006, Nature.

[75]  I. Poole,et al.  Physiognomic and Chemical Characters in Wood as Palaeoclimate Proxies , 2006, Plant Ecology.

[76]  D. Cantrill,et al.  A multi-proxy approach to determine Antarctic terrestrial palaeoclimate during the Late Cretaceous and Early Tertiary , 2005 .

[77]  C. Jaramillo,et al.  Paleogene palynostratigraphy of the eastern middle Magdalena Valley, Colombia , 2003 .

[78]  J. G. Carter,et al.  δ18O in mollusk shells from Pliocene Lake Hadar and modern Ethiopian lakes: Implications for history of the Ethiopian monsoon , 2002 .

[79]  V. Prasad,et al.  Palynological investigation of the tura formation (early eocene) exposed along the tura-dalu road, west Garo Hills, Meghalaya, India , 2000, Journal of Palaeosciences.

[80]  V. Mosbrugger,et al.  Reconstructing palaeotemperatures for the Early and Middle Pleistocene using the mutual climatic range method based on plant fossils , 2000 .

[81]  A. Graham,et al.  Studies in Neotropical paleobotany. XIV. A palynoflora from the Middle Eocene Saramaguacan Formation of Cuba. , 2000, American journal of botany.

[82]  J. Guiot,et al.  A method for climatic reconstruction of the Mediterranean Pliocene using pollen data , 1998 .

[83]  K. Portier,et al.  Dicotyledonous wood anatomical characters as predictors of climate , 1998 .

[84]  D. Greenwood,et al.  USING FOSSIL LEAVES AS PALEOPRECIPITATION INDICATORS : AN EOCENE EXAMPLE , 1998 .

[85]  P. Xie,et al.  Global Precipitation: A 17-Year Monthly Analysis Based on Gauge Observations, Satellite Estimates, and Numerical Model Outputs , 1997 .

[86]  V. Mosbrugger,et al.  The coexistence approach — a method for quantitative reconstructions of Tertiary terrestrial palaeoclimate data using plant fossils , 1997 .

[87]  Kevin E. Trenberth,et al.  Evaluation of the Global Atmospheric Moisture Budget as Seen from Analyses , 1995 .

[88]  N. Frederiksen Middle and late paleocene angiosperm pollen from Pakistan , 1994 .

[89]  D. Greenwood,et al.  Fossils and fossil climate: the case for equable continental interiors in the Eocene , 1993 .

[90]  William G. Lee,et al.  The presence of moisture deficits in Miocene New Zealand , 2019, Global and Planetary Change.

[91]  O. Ehinola,et al.  Bio-Sequence Stratigraphy of Shagamu Quarry Outcrop , Benin Basin , Southwestern Nigeria , 2013 .

[92]  D. Greenwood,et al.  Life at the top of the greenhouse Eocene world--A review of the Eocene flora and vertebrate fauna from Canada's High Arctic , 2012 .

[93]  R. Spicer,et al.  Refining CLAMP — Investigations towards improving the Climate Leaf Analysis Multivariate Program , 2011 .

[94]  D. Greenwood Fossil angiosperm leaves and climate: from Wolfe and Dilcher to Burnham and Wilf , 2007 .

[95]  D. Greenwood,et al.  Plant communities and climate change in southeastern Australia during the early Paleogene , 2003 .

[96]  M. Collinson,et al.  Cobham lignite bed and penecontemporaneous macrofloras of southern England: A record of vegetation and fire across the Paleocene-Eocene Thermal Maximum , 2003 .

[97]  M. Quattrocchio,et al.  Paleoclimatic Changes during the Paleocene-Lower Eocene in the Salta Group Basin, NW Argentina , 2000 .

[98]  D. Greenwood,et al.  Using fossil leaves as paleoprecipitation indicators: An Eocene example: Comment and Reply , 1999 .

[99]  J. A. Wolfe PALEOCLIMATIC ESTIMATES FROM TERTIARY LEAF ASSEMBLAGES , 1995 .

[100]  J. A. Wolfe A method of obtaining climatic parameters from leaf assemblages , 1993 .

[101]  T. Givnish Leaf and Canopy Adaptations in Tropical Forests , 1984 .