Terrestrial biosphere changes over the last 120 kyr

Hoogakker, Babette A A; Smith, Robin S.; Singarayer, Joy; Marchant, Rob; Prentice, Iain Colin; Allen, Judy R M; Anderson, R. Scott; Bhagwat, Shonil A.; Behling, Hermann; Borisova, Olga; Bush, Mark B.; Correa‐Metrio, Alexander; Vernal, Anne de; Finch, Jemma; Fréchette, Bianca; Lozano‐García, Socorro; Gosling, William D.; Granoszewski, Wojciech; Grimm, Eric C.; Grüger, Eberhard; Hanselman, J. A.; Harrison, Sandy P.; Hill, Trevor; Huntley, Brian; Jiménez‐Moreno, Gonzalo; Kershaw, A. Peter; Ledru, Marie‐Pierre; Magri, Donatella; McKenzie, Merna; Müller, Ulrich; Nakagawa, Takeshi; Novenko, Elena; Penny, Dan; Sadori, Laura; Scott, Louis; Stevenson, Janelle; Valdes, Paul J.; Vandergoes, Marcus J.; Величко, А.А.; Whitlock, Cathy; Tzedakis, Polychronis C.

doi:10.5194/cp-12-51-2016

Cited by 52 publications

(57 citation statements)

References 122 publications

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“…The two y axes are scaled to illustrate the similarity in the pattern of change across the deglaciation but are not meant to imply that the magnitude of change is equivalent. 2 ka and net primary productivity increased from 8-2 ka (Hoogakker et al, 2016). This is consistent with our observation that the global mean benthic δ 13 C trend continued until at least 6 ka.…”

Section: Discussionsupporting

confidence: 92%

“…The deglacial pattern of global mean ocean δ 13 C change is a proxy for changes in the size of the terrestrial biosphere. If so, global mean δ 13 C should continue to increase after atmospheric CO 2 levels plateau at 11 ka due to the slower response times for ice sheet retreat and ecosystem change (e.g., Hoogakker et al, 2016;DaviesBarnard et al, 2017). We compare the reconstructed global mean δ 13 C change with several carbon cycle model estimates of terrestrial biosphere change.…”

Section: Introductionmentioning

confidence: 99%

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Deglacial carbon cycle changes observed in a compilation of 127 benthic δ13C time series (20–6 ka)

Peterson

Lisiecki

2018

Clim. Past

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Abstract. We present a compilation of 127 time series δ 13 C records from Cibicides wuellerstorfi spanning the last deglaciation (20-6 ka) which is well-suited for reconstructing large-scale carbon cycle changes, especially for comparison with isotope-enabled carbon cycle models. The age models for the δ 13 C records are derived from regional planktic radiocarbon compilations . The δ 13 C records were stacked in nine different regions and then combined using volume-weighted averages to create intermediate, deep, and global δ 13 C stacks. These benthic δ 13 C stacks are used to reconstruct changes in the size of the terrestrial biosphere and deep ocean carbon storage. The timing of change in global mean δ 13 C is interpreted to indicate terrestrial biosphere expansion from 19-6 ka. The δ 13 C gradient between the intermediate and deep ocean, which we interpret as a proxy for deep ocean carbon storage, matches the pattern of atmospheric CO 2 change observed in ice core records. The presence of signals associated with the terrestrial biosphere and atmospheric CO 2 indicates that the compiled δ 13 C records have sufficient spatial coverage and time resolution to accurately reconstruct large-scale carbon cycle changes during the glacial termination.

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Section: Discussionsupporting

confidence: 92%

Section: Introductionmentioning

confidence: 99%

Deglacial carbon cycle changes observed in a compilation of 127 benthic δ13C time series (20–6 ka)

Peterson

Lisiecki

2018

Clim. Past

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“…Australia has a tendency to be too wet in HadCM3 in the present day and hence the coupled model has too much vegetation in this region). However, during glacial times there is a decrease in biomass, consistent with Hoogakker et al (2016).…”

Section: Results: Vegetation Dynamicssupporting

confidence: 65%

“…This is supported by pollen and other data Anhuf et al, 2006;Wang et al, 2017) and modelling (Cowling et al, 2001) which find that although there is diminished tropical forest, there is still substantial tree cover at the LGM and little sign of widespread grasslands. Conversely, the BIOME6000 data find that the tropical rainforest area was reduced during the LGM (Pickett et al, 2004;Prentice and Jolly, 2000;Bigelow et al, 2003;Harrison et al, 2001) and grasslands expanded, as do some modelling studies (Martin Calvo and Prentice, 2015;Prentice et al, 2011;Hoogakker et al, 2016). It is interesting to note that in the present-day Amazon, BIOME6000 shows three points of tropical forest, two of savanna, two of warm-temperature forest, two of temperate forest, and three of dry grass/shrubland at the LGM.…”

Section: Results: Vegetation Dynamicsmentioning

confidence: 97%

Quantifying the influence of the terrestrial biosphere on glacial–interglacial climate dynamics

et al. 2017

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Abstract. The terrestrial biosphere is thought to be a key component in the climatic variability seen in the palaeorecord. It has a direct impact on surface temperature through changes in surface albedo and evapotranspiration (so-called biogeophysical effects) and, in addition, has an important indirect effect through changes in vegetation and soil carbon storage (biogeochemical effects) and hence modulates the concentrations of greenhouse gases in the atmosphere. The biogeochemical and biogeophysical effects generally have opposite signs, meaning that the terrestrial biosphere could potentially have played only a very minor role in the dynamics of the glacial-interglacial cycles of the late Quaternary. Here we use a fully coupled dynamic atmosphereocean-vegetation general circulation model (GCM) to generate a set of 62 equilibrium simulations spanning the last 120 kyr. The analysis of these simulations elucidates the relative importance of the biogeophysical versus biogeochemical terrestrial biosphere interactions with climate. We find that the biogeophysical effects of vegetation account for up to an additional −0.91 • C global mean cooling, with regional cooling as large as −5 • C, but with considerable variability across the glacial-interglacial cycle. By comparison, while opposite in sign, our model estimates of the biogeochemical impacts are substantially smaller in magnitude. Offline simulations show a maximum of +0.33 • C warming due to an increase of 25 ppm above our (pre-industrial) baseline atmospheric CO 2 mixing ratio. In contrast to shorter (century) timescale projections of future terrestrial biosphere response where direct and indirect responses may at times cancel out, we find that the biogeophysical effects consistently and strongly dominate the biogeochemical effect over the inter-glacial cycle. On average across the period, the terrestrial biosphere has a −0.26 • C effect on temperature, with −0.58 • C at the Last Glacial Maximum. Depending on assumptions made about the destination of terrestrial carbon under ice sheets and where sea level has changed, the average terrestrial biosphere contribution over the last 120 kyr could be as much as −50 • C and −0.83 • C at the Last Glacial Maximum.

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“…We do not explicitly model the terrestrial carbon cycle in our experiment. Rather, we assume here that the land biosphere would have a smaller net primary production (Hoogakker et al, 2016) and standing biomass stock and hence provide a release of carbon to the atmosphere under colder and drier conditions. The amplitude for biomass carbon loss from the land biosphere to the atmosphere was set to −1000 Pg C, in line with estimates from terrestrial palaeoclimate records according to Crowley (1995).…”

Section: Sensitivity Experimentsmentioning

confidence: 99%

Ocean carbon cycling during the past 130 000 years – a pilot study on inverse palaeoclimate record modelling

2016

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Abstract. What role did changes in marine carbon cycle processes and calcareous organisms play in glacial-interglacial variation in atmospheric pCO 2 ? In order to answer this question, we explore results from an ocean biogeochemical general circulation model. We attempt to systematically reconcile model results with time-dependent sediment core data from the observations. For this purpose, we fit simulated sensitivities of oceanic tracer concentrations to changes in governing carbon cycle parameters to measured sediment core data. We assume that the time variation in the governing carbon cycle parameters follows the general pattern of the glacial-interglacial deuterium anomaly. Our analysis provides an independent estimate of a maximum mean sea surface temperature drawdown of about 5 • C and a maximum outgassing of the land biosphere by about 430 Pg C at the Last Glacial Maximum as compared to pre-industrial times. The overall fit of modelled palaeoclimate tracers to observations, however, remains quite weak, indicating the potential of more detailed modelling studies to fully exploit the information stored in the palaeoclimatic archive. This study confirms the hypothesis that a decline in ocean temperature and a more efficient biological carbon pump in combination with changes in ocean circulation are the key factors for explaining the glacial CO 2 drawdown. The analysis suggests that potential changes in the export rain ratio POC : CaCO 3 may not have a substantial imprint on the palaeoclimatic archive. The use of the last glacial as an inverted analogue to potential ocean acidification impacts thus may be quite limited.A strong decrease in CaCO 3 export production could potentially contribute to the glacial CO 2 decline in the atmosphere, but this remains hypothetical.

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Terrestrial biosphere changes over the last 120 kyr

Cited by 52 publications

References 122 publications

Deglacial carbon cycle changes observed in a compilation of 127 benthic <i>δ</i><sup>13</sup>C time series (20–6 ka)

Deglacial carbon cycle changes observed in a compilation of 127 benthic <i>δ</i><sup>13</sup>C time series (20–6 ka)

Quantifying the influence of the terrestrial biosphere on glacial–interglacial climate dynamics

Ocean carbon cycling during the past 130 000 years – a pilot study on inverse palaeoclimate record modelling

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Terrestrial biosphere changes over the last 120 kyr

Cited by 52 publications

References 122 publications

Deglacial carbon cycle changes observed in a compilation of 127 benthic &lt;i&gt;δ&lt;/i&gt;&lt;sup&gt;13&lt;/sup&gt;C time series (20–6 ka)

Deglacial carbon cycle changes observed in a compilation of 127 benthic &lt;i&gt;δ&lt;/i&gt;&lt;sup&gt;13&lt;/sup&gt;C time series (20–6 ka)

Quantifying the influence of the terrestrial biosphere on glacial–interglacial climate dynamics

Ocean carbon cycling during the past 130 000 years – a pilot study on inverse palaeoclimate record modelling

Contact Info

Product

Resources

About

Terrestrial biosphere changes over the last 120 kyr

Deglacial carbon cycle changes observed in a compilation of 127 benthic <i>δ</i><sup>13</sup>C time series (20–6 ka)

Deglacial carbon cycle changes observed in a compilation of 127 benthic <i>δ</i><sup>13</sup>C time series (20–6 ka)

Ocean carbon cycling during the past 130 000 years – a pilot study on inverse palaeoclimate record modelling