ΔT reconstructions and climate forcings. a Northern extratropical (30–90°N) multi-proxy ΔT reconstruction11 (red; filled area = ±1σ uncertainty) and mean 1997–2016 GISTEMP37 annual ΔT for the same area (red star); b E. Beringia multi-proxy ‘all-temperature’ composite9; c E. Beringia composite pollen- (blue) and midge-based (orange) summer ΔT reconstructions9; d DHP174 (Dempster Highway Peatland, near 174 km marker) δDpore ice-based summer ΔT reconstruction (blue; filled area = ±1σ; this study) and smoothed 1900–2017 May–September GISTEMP ΔT anomalies for the study area (red; n.b., GISTEMP anomalies were smoothed with a 40-year cubic spline and normalised to the twentieth century mean of the δDpore ice ΔT reconstruction; a 1991–2001 data gap in GISTEMP was filled with ERA-interim data64); e 40-year smoothed Arctic (60–90°N) multi-proxy ΔT reconstruction7 (green; filled area = ±1σ) and mean 1997–2016 GISTEMP37 annual ΔT for the same area (green star); f June–September insolation at 65°N65; g Vostok, Law Dome and Mauna Loa composite pCO2 record66,67,68. Grey bars highlight warming intervals in the δDpore ice-based ΔT reconstruction that are also evident in other ΔT reconstructions in E. Beringia and at broader spatial scales. Graphic: Porter, et al., 2019 / Nature Communications

ΔT reconstructions and climate forcings. a Northern extratropical (30–90°N) multi-proxy ΔT reconstruction11 (red; filled area = ±1σ uncertainty) and mean 1997–2016 GISTEMP37 annual ΔT for the same area (red star); b E. Beringia multi-proxy ‘all-temperature’ composite9c E. Beringia composite pollen- (blue) and midge-based (orange) summer ΔT reconstructions9dDHP174 (Dempster Highway Peatland, near 174 km marker) δDpore ice-based summer ΔT reconstruction (blue; filled area = ±1σ; this study) and smoothed 1900–2017 May–September GISTEMP ΔT anomalies for the study area (red; n.b., GISTEMP anomalies were smoothed with a 40-year cubic spline and normalised to the twentieth century mean of the δDpore ice ΔTreconstruction; a 1991–2001 data gap in GISTEMP was filled with ERA-interim data64); e 40-year smoothed Arctic (60–90°N) multi-proxy ΔT reconstruction7 (green; filled area = ±1σ) and mean 1997–2016 GISTEMP37 annual ΔT for the same area (green star); f June–September insolation at 65°N65g Vostok, Law Dome and Mauna Loa composite pCO2 record66,67,68. Grey bars highlight warming intervals in the δDpore ice-based ΔT reconstruction that are also evident in other ΔT reconstructions in E. Beringia and at broader spatial scales. Graphic: Porter, et al., 2019 / Nature Communications

By Blake Eligh
9 April 2019

(University of Toronto) – A new University of Toronto study confirms that recent climate warming in the central Yukon region has surpassed the warmest temperatures experienced in the previous 13,600 years, a finding that could have important implications in the context of current global warming trends.

In a study published in the April issue of Nature Communications, paleoclimatologist and lead author Trevor Porter studies climate indicators such as water isotopes, tree rings and plant waxes for signs of climate patterns in the Holocene, a period of time that spans the past 11,700 years.

In glaciated regions, paleoclimate research often relies on water isotopes measured from ice core samples taken from glaciers, but in central Yukon, where glaciers have long since receded, researchers must rely on other indicators such as plant pollen and small winged insects known as midges preserved in layers of lake sediment. Pollen and midges act as proxies for ancient temperatures but sometimes offer conflicting information.

In a first for the field, Porter, an assistant professor in the department of geography at U of T Mississauga, and his colleagues used radiocarbon dating and water isotopes preserved in permafrost beneath a central Yukon peatland to reconstruct summer temperatures over the last 13,600 years.

Each summer, new peat moss accumulates at the surface, and the top of permafrost, which lies at a constant depth of 58 centimetres below ground, adjusts to the new surface. It simultaneously preserves precipitation that filtered through the ground and froze at the top of permafrost during previous summers.

“Each centimetre of permafrost holds roughly 20 to 30 years of precipitation, which settles into well-blended layers of information,” Porter says. “Water isotope records from ice cores are one of the most valued climate proxies but can only be developed in glaciated regions. This project demonstrates that we can develop ice core-like records in non-glaciated permafrost regions.

“This type of permafrost offers a unique archive for water isotopes that could be used to advance our understanding of Holocene climate change in other northern regions, which would be a major benefit to the climate science community.”

The results of the permafrost analysis confirms information provided by previous midge studies, and shows that early Holocene summers in the central Yukon were mostly warmer than the typical Holocene summer. The study further concludes that industrial-era warming has led to current summer temperatures that are unprecedented in the Holocene context, and exceeds all previous maximum temperatures by nearly 2 degrees Celsius.

“When compared with climate reconstructions from other northern areas, our data confirm that this region has been warming at an exceptional rate,” Porter says. “We know, based on recent historical climate data, that this area has warmed up more than other high-latitude regions. This region has experienced warming of just over 2 degrees Celsius over the past century, which is above the global average and above the average of the Arctic region in general.”

Summer warming has major implications for permafrost landscapes, Porter says.

“When temperatures go up, ice-rich permafrost can thaw, become unstable, and previously frozen soil carbon can be released to the atmosphere as carbon dioxide by microbes,” he says, noting that the region experienced a deep thaw of permafrost roughly 9,000 years ago.

“Deep permafrost thaw events did occur in this region in the early Holocene, a time we now know was relatively warm compared to the Holocene average but not nearly as warm as today. This implies that ice-rich permafrost in this region is currently vulnerable to similar thaw events.”

Porter says there is evidence that climate warming is destabilizing permafrost in northern Canada and releasing greenhouse gases. “This is potentially the new normal and, if it accelerates in the near future, it threatens to further amplify global climate change.”

Funding for the research was provided by the Natural Sciences and Engineering Research Council (NSERC).

Secrets of the permafrost: New U of T research reveals evidence of climate change in the Yukon

ABSTRACT: Eastern Beringia is one of the few Western Arctic regions where full Holocene climate reconstructions are possible. However, most full Holocene reconstructions in Eastern Beringia are based either on pollen or midges, which show conflicting early Holocene summer temperature histories. This discrepancy precludes understanding the factors that drove past (and potentially future) climate change and calls for independent proxies to advance the debate. We present a ~13.6 ka summer temperature reconstruction in central Yukon, part of Eastern Beringia, using precipitation isotopes in syngenetic permafrost. The reconstruction shows that early Holocene summers were consistently warmer than the Holocene mean, as supported by midges, and a thermal maximum at ~7.6–6.6 ka BP. This maximum was followed by a ~6 ka cooling, and later abruptly reversed by industrial-era warming leading to a modern climate that is unprecedented in the Holocene context and exceeds the Holocene thermal maximum by +1.7 ± 0.7 °C.

Recent summer warming in northwestern Canada exceeds the Holocene thermal maximum