Methane and nitrous oxide in the ice core record

Wolff, Eric W.; Spahni, Renato

doi:10.1098/rsta.2007.2044

Cited by 36 publications

(23 citation statements)

References 73 publications

(128 reference statements)

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“…As suggested by Bock et al (2010) and discussed above, a change in boreal wetland CH 4 emissions appears to be required during some D-O events. In these regions, slow processes such as the exposure of land surface as the ice sheet retreated are clearly not capable of producing such fast variations (Wolff and Spahni, 2007). CH 4 emissions associated with permafrost destabilization need to be incorporated into paleo-modelling studies such as the one performed here.…”

Section: Discussionmentioning

confidence: 99%

Response of methane emissions from wetlands to the Last Glacial Maximum and an idealized Dansgaard–Oeschger climate event: insights from two models of different complexity

et al. 2013

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Abstract.The role of different sources and sinks of CH 4 in changes in atmospheric methane ([CH 4 ]) concentration during the last 100 000 yr is still not fully understood. In particular, the magnitude of the change in wetland CH 4 emissions at the Last Glacial Maximum (LGM) relative to the pre-industrial period (PI), as well as during abrupt climatic warming or Dansgaard-Oeschger (D-O) events of the last glacial period, is largely unconstrained. In the present study, we aim to understand the uncertainties related to the parameterization of the wetland CH 4 emission models relevant to these time periods by using two wetland models of different complexity (SDGVM and ORCHIDEE). These models have been forced by identical climate fields from low-resolution coupled atmosphere-ocean general circulation model (FA-MOUS) simulations of these time periods. Both emission models simulate a large decrease in emissions during LGM in comparison to PI consistent with ice core observations and previous modelling studies. The global reduction is much larger in ORCHIDEE than in SDGVM (respectively −67 and −46 %), and whilst the differences can be partially explained by different model sensitivities to temperature, the major reason for spatial differences between the models is the inclusion of freezing of soil water in ORCHIDEE and the resultant impact on methanogenesis substrate availability in boreal regions. Besides, a sensitivity test performed with ORCHIDEE in which the methanogenesis substrate sensitivity to the precipitations is modified to be more realistic gives a LGM reduction of −36 %. The range of the global LGM decrease is still prone to uncertainty, and here we underline its sensitivity to different process parameterizations. Over the course of an idealized D-O warming, the magnitude of the change in wetland CH 4 emissions simulated by the two models at global scale is very similar at around 15 Tg yr −1 , but this is only around 25 % of the icecore measured changes in [CH 4 ]. The two models do show regional differences in emission sensitivity to climate with much larger magnitudes of northern and southern tropical anomalies in ORCHIDEE. However, the simulated northern and southern tropical anomalies partially compensate each other in both models limiting the net flux change. Future work may need to consider the inclusion of more detailed wetland processes (e.g. linked to permafrost or tropical floodplains), other non-wetland CH 4 sources or different patterns of D-O climate change in order to be able to reconcile emission estimates with the ice-core data for rapid CH 4 events.

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Section: Discussionmentioning

confidence: 99%

Response of methane emissions from wetlands to the Last Glacial Maximum and an idealized Dansgaard–Oeschger climate event: insights from two models of different complexity

et al. 2013

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“…The nature of this feedback can be assessed directly for the Quaternary by using archives of variations in stable GHGs recovered by analysing ancient samples of air closed-off from the atmosphere in ice (Spahni et al 2005;Wolff & Spahni 2007). Remarkable new records of N 2 O and CH 4 from polar cores extend back over the past 650 000 years and illustrate unequivocally that the current concentrations of both trace gases are unprecedented in recent Earth history.…”

Section: Trace Gases and Palaeoclimatesmentioning

confidence: 99%

“…400-500 ppbv), while the modern N 2 O concentration of 319 ppbv (Jiang et al 2007) exceeds a typical interglacial value by approximately 100 ppbv. Analyses of the covariation of GHGs and palaeoclimate from the EPICA Dome C record shows methane variations have tracked glacial-interglacial climate change for the last eight glacial cycles (Spahni et al 2005;Wolff & Spahni 2007). The response of N 2 O is more complex but exhibits a periodicity tracking millennialscale Dansgaard-Oeschger warming events (Flückiger et al 2004;Spahni et al 2005;Wolff & Spahni 2007).…”

Section: Trace Gases and Palaeoclimatesmentioning

confidence: 99%

Critical issues in trace gas biogeochemistry and global change

Beerling

Hewitt

Pyle

et al. 2007

Phil. Trans. R. Soc. A.

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The atmospheric composition of trace gases and aerosols is determined by the emission of compounds from the marine and terrestrial biospheres, anthropogenic sources and their chemistry and deposition processes. Biogenic emissions depend upon physiological processes and climate, and the atmospheric chemistry is governed by climate and feedbacks involving greenhouse gases themselves. Understanding and predicting the biogeochemistry of trace gases in past, present and future climates therefore demands an interdisciplinary approach integrating across physiology, atmospheric chemistry, physics and meteorology. Here, we highlight critical issues raised by recent findings in all of these key areas to provide a framework for better understanding the past and possible future evolution of the atmosphere. Incorporating recent experimental and observational findings, especially the influence of CO 2 on trace gas emissions from marine algae and terrestrial plants, into earth system models remains a major research priority. As we move towards this goal, archives of the concentration and isotopes of N 2 O and CH 4 from polar ice cores extending back over 650 000 years will provide a valuable benchmark for evaluating such models. In the Pre-Quaternary, synthesis of theoretical modelling with geochemical and palaeontological evidence is also uncovering the roles played by trace gases in episodes of abrupt climatic warming and ozone depletion. Finally, observations and palaeorecords across a range of timescales allow assessment of the Earth's climate sensitivity, a metric influencing our ability to decide what constitutes 'dangerous' climate change.

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“…The ice core record of atmospheric N 2 O concentrations shows considerable temporal variability that closely parallels polar temperature records [2], [3], [4], [5], indicating that nitrogen trace gas emissions may be very sensitive to climate change. Variability in atmospheric N 2 O and NO x concentrations is linked to nitrogen cycling in the oceans, e.g., [6] and the terrestrial biosphere [1].…”

Section: Introductionmentioning

confidence: 99%

“…Over the last decade, a number of studies have attempted to quantify N 2 O emissions both for the present-day and the past based on measurement-based inventories of N 2 O concentrations in ice cores [2], [3], [4], [5]. In addition, several research groups have attempted to model regional and global source emissions of N 2 O and NO x , e.g [9], [10], [11].…”

Section: Introductionmentioning

confidence: 99%

Response of terrestrial N₂O and NO_xemissions to abrupt climate change

Pfeiffer

Kaplan

2010

IOP Conf. Ser.: Earth Environ. Sci.

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Abstract. Being a potent greenhouse gas, N 2 O emitted by the terrestrial biosphere during abrupt climate change events could have amplified externally forced warming. To investigate this possibility, we tested the sensitivity of terrestrial N 2 O emissions to an abrupt warming event by applying the ARVE-DGVM in combination with a novel scheme for process-based simulation of terrestrial N 2 O and NO x emissions at the Gerzensee site in Switzerland. In this study, we aim to quantify the magnitude of change in emissions for the abrupt climate change event that occurred at the transition from Oldest Dryas to Bøl-ling during the last deglaciation. Using high-resolution multiproxy records obtained from the Gerzensee that cover the Late Glacial, we apply a prescribed vegetation change derived from the pollen record and temperature and precipitation reconstructions derived from δ 18 O in lake sediments. Changes in soil temperature and moisture are simulated by the ARVE-DGVM using the reconstructed paleoclimate as a driver. Our results show a pronounced increase in mean annual N 2 O and NO x emissions for the transition (by factor 2.55 and 1.97, respectively), with highest amounts generally being emitted during summer. Our findings suggest that summertime emissions are limited by soil moisture, while temperature controls emissions during winter. For the time between 14670 and 14620 cal. years BP, our simulated N 2 O emissions show increase rates as high as 1% per year, indicating that local reactions of emissions to changing climate could have been considerably faster than the atmospheric concentration changes observed in polar ice.

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Methane and nitrous oxide in the ice core record

Cited by 36 publications

References 73 publications

Response of methane emissions from wetlands to the Last Glacial Maximum and an idealized Dansgaard–Oeschger climate event: insights from two models of different complexity

Response of methane emissions from wetlands to the Last Glacial Maximum and an idealized Dansgaard–Oeschger climate event: insights from two models of different complexity

Critical issues in trace gas biogeochemistry and global change

Response of terrestrial N₂O and NO_xemissions to abrupt climate change

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Methane and nitrous oxide in the ice core record

Cited by 36 publications

References 73 publications

Response of methane emissions from wetlands to the Last Glacial Maximum and an idealized Dansgaard–Oeschger climate event: insights from two models of different complexity

Response of methane emissions from wetlands to the Last Glacial Maximum and an idealized Dansgaard–Oeschger climate event: insights from two models of different complexity

Critical issues in trace gas biogeochemistry and global change

Response of terrestrial N2O and NOxemissions to abrupt climate change

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Product

Resources

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Response of terrestrial N₂O and NO_xemissions to abrupt climate change