Dominique K. L. L. Jenny’s scientific contributions

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Publications (1)


(a) In blue: SST of ODP 1168A (west of Tasmania, TEX86H; Guitián and Stoll, 2021; Hoem et al., 2021). In brown: SST of U1404 (northwestern Atlantic, Uk37; Liu et al., 2018). (b) Published pCO2 records of the Oligocene. Dark-blue line and shading represent the median and 95 % credible interval. Grey squares: phytoplankton data. Brown squares: leaf gas exchange reconstructions. Black dots: boron isotopic data. Green triangles: land plant δ13C data. Brown crosses: palaeosol data. Green stars: stomatal frequency data (Greenop et al., 2019; Moraweck et al., 2019; Pagani et al., 2005, 2011; Roth-Nebelsick et al., 2014; Witkowski et al., 2018; Zhang et al., 2013; The CenCO2PIPm, 2023). (c, d) Deep-ocean benthic foraminifera stable carbon isotope and oxygen isotope records, respectively (Westerhold et al., 2020, notably representing the record of Pälike et al., 2006a). Red colour block: Eocene–Oligocene transition (EOT). Grey: Eocene–Oligocene Glacial Maximum (EOGM). Blue: Mid-Oligocene Glacial Interval (MOGI). Green: Oligocene–Miocene transition (OMT).
Palaeogeographic reconstruction of the Oligocene (∼28 Ma). Yellow dots: Tex86-based data. Purple hexagons: nearest living relative (NLR) data. Green squares: U37K data. Red diamonds: δ18O data. Map created using GPlates, using the Scotese and Wright (2018) plate rotation.
(a) Mean annual temperature (MAT; °C) plot over palaeolatitudes. In grey: pre-industrial (1900) MAT from Matsuura and Willmott (2018). (b) Winter temperature (WinT; °C) plot over palaeolatitudes. In grey: pre-industrial (1900) WinT from Matsuura and Willmott (2018). Darker colours represent a higher analytical certainty of the used site, and data with low reliability were excluded (see Table A1).
SST (°C) compilation for the Oligocene (CenCO2PIP, 2023). A linear interpolation was used between data points. Blue sites: SH high-latitude sites. Yellow sites: low-latitude sites. Green sites: NH high-latitude sites. See Fig. 2 for site locations and Table A3 for references.
Sea surface temperatures (SSTs; °C) over palaeolatitudes for 33.4 Ma (EOGM, black dots), 26.8 Ma (MOGI, blue triangles), and 23.4 Ma (OMT, orange squares). Brown shaded area: Baatsen et al. (2020) SST record for the late Eocene (38 Ma). Grey area: pre-industrial (1900) SST over latitude (Huang et al., 2015). Thick vertical error bars show the SST standard deviation, and thin vertical error bars represent the calibration error for each proxy. Larger symbols represent a higher data resolution, with larger symbols representing more data used and smaller points representing where fewer data were available. See Table A3 for data referral and references used.

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Climate variability, heat distribution, and polar amplification in the warm unipolar “icehouse” of the Oligocene
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July 2024

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Dominique K. L. L. Jenny

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Appy Sluijs

The Oligocene (33.9–23.03 Ma) had warm climates with flattened meridional temperature gradients, while Antarctica retained a significant cryosphere. These may pose imperfect analogues to distant future climate states with unipolar icehouse conditions. Although local and regional climate and environmental reconstructions of Oligocene conditions are available, the community lacks synthesis of regional reconstructions. To provide a comprehensive overview of marine and terrestrial climate and environmental conditions in the Oligocene, and a reconstruction of trends through time, we review marine and terrestrial proxy records and compare these to numerical climate model simulations of the Oligocene. Results, based on the present relatively sparse data, suggest temperatures around the Equator that are similar to modern temperatures. Sea surface temperatures (SSTs) show patterns similar to land temperatures, with warm conditions at mid- and high latitudes (∼60–90°), especially in the Southern Hemisphere (SH). Vegetation-based precipitation reconstructions of the Oligocene suggest regionally drier conditions compared to modern times around the Equator. When compared to proxy data, climate model simulations overestimate Oligocene precipitation in most areas, particularly the tropics. Temperatures around the mid- to high latitudes are generally underestimated in models compared to proxy data and tend to overestimate the warming in the tropics. In line with previous proxy-to-model comparisons, we find that models underestimate polar amplification and overestimate the Equator-to-pole temperature gradient suggested from the available proxy data. This further stresses the urgency of solving this widely recorded problem for past warm climates, such as the Oligocene.

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Citations (1)


... Eocene-Oligocene climate changes are associated with continuous Neo-Tethyan seaway closure during the Eurasia and India-Arabia-Africa convergence and growth of the Alpine-Himalayan Mountain belt, accompanied by a shift towards modern patterns of ocean currents (McQuarrie et al. 2003;Allen and Armstrong 2008). Cool and dry conditions during the beginning of the Early Oligocene gradually changed to warm conditions of the Late Oligocene, and caused deposition of extensive terrestrial red beds facies, such as LRF, in west and central Asia (Sun et al. 2010;Kargaranbafghi and Neubauer 2018;Wu et al. 2018;Jenny et al. 2024). Late Oligocene terrestrial conditions of Central Iran did not last long-term and shifted to shallow marine carbonate seaways of the Qom Formation (Daneshian and Ramezani Dana 2007;Reuter et al. 2009;Mohammadi et al. 2013Mohammadi et al. , 2024. ...

Reference:

Oligocene vertebrate footprints from the Lower Red Formation, Central Iran
Climate variability, heat distribution, and polar amplification in the warm unipolar “icehouse” of the Oligocene