The Expanding Footprint of Rapid Arctic Change

Moon, Twila; Overeem, I.; Druckenmiller, Matt; Holland, Marika M.; Huntington, Henry P.; Kling, George W.; Lovecraft, Amy Lauren; Miller, Gifford H.; Scambos, T. A.; Schädel, Christina; Schuur, Edward A. G.; Trochim, Erin; Wiese, Francis K.; Williams, Dee; Wong, G. J.

doi:10.1029/2018ef001088

Cited by 48 publications

(35 citation statements)

References 53 publications

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“…The hypothesized opening of Fram Strait between the Nordic Seas and the Arctic at around 17 Ma (Jakobson et al, 2007; Thompson et al, 2010) may have contributed to the MCO by allowing warmer surface waters to enter the Arctic Basin, thereby leading to increased Arctic SSTs and decreased seasonal Arctic sea ice (St. John, 2008). It has been argued that the strong climatic feedback of sea ice reduction in the Arctic (e.g., Moon et al, 2019) might then have led to the global warming observed during the MCO (Jakobsson et al, 2007). However, our evidence suggests that overturning circulation that resulted in the transportation of warm surface water to the Nordic Seas by a NAC‐precursor was actually relatively enhanced as the MCO came to an end, as discussed below.…”

Section: Discussionmentioning

confidence: 99%

Miocene Evolution of North Atlantic Sea Surface Temperature

Super

Thomas

Pagani

et al. 2020

Paleoceanog and Paleoclimatol

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We reconstruct sea surface temperatures (SSTs) at Deep Sea Drilling Project Site 608 (42.836°N, 23.087°), north of the Azores Front, and Ocean Drilling Program Site 982 (57.516°N, 15.866°), under the North Atlantic Current, in order to track Miocene (23.1-5.3 Ma) development of North Atlantic surface waters. Mean annual SSTs from TEX 86 and U K′37 proxy estimates at both sites were 10-15°C higher than modern through the Miocene Climatic Optimum (17-14.5 Ma). During the global cooling of the Middle Miocene Climate Transition (~14.5-12.5 Ma), SSTs at midlatitude Site 608 cooled by~6°C, whereas high-latitude Site 982 cooled by only~2°C, resulting in an~4 Myr collapse of the SST gradient between the two sites. This regional pattern is inconsistent with an increased latitudinal surface temperature gradient, as generally associated with global cooling episodes linked to decreasing pCO 2 levels. Instead, the pattern is best explained by enhanced ocean heat transport into the high-latitude North Atlantic superimposed on the global cooling trend, probably due to enhanced Atlantic meridional overturning circulation and/or a stronger North Atlantic Current. During global late Miocene cooling (~8-7 Ma), surface waters cooled bỹ 6°C at Site 982 while minimal change occurred at Site 608, reestablishing the North Atlantic SST gradient. The collapse and reemergence of the SST gradient between the middle-and high-latitude North Atlantic suggests that interaction between changes in regional ocean circulation and the global response to changes in greenhouse gas concentration was important in Miocene climate evolution.

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Section: Discussionmentioning

confidence: 99%

Miocene Evolution of North Atlantic Sea Surface Temperature

Super

Thomas

Pagani

et al. 2020

Paleoceanog and Paleoclimatol

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“…However, the Arctic is warming twice as fast as other regions [44]. Because a changing Arctic cryosphere has a far-reaching footprint of influence in distant geographies, constructive multilevel adaptive actions are needed [45]. Northern Alaska's communities, in this sense, are laboratories for learning, through which a global audience can glimpse their own future challenges related to collective adaptive action.…”

Section: Study Areamentioning

confidence: 99%

Risks Without Borders: A Cultural Consensus Model of Risks to Sustainability in Rapidly Changing Social–Ecological Systems

Blair

Lovecraft

2020

Sustainability

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Global sustainability goals cannot realistically be achieved without strategies that build on multiscale definitions of risks to wellbeing. Particularly in geographic contexts experiencing rapid and complex social and environmental changes, there is a growing need to empower communities to realize self-identified adaptation goals that address self-identified risks. Meeting this demand requires tools that can help assess shared understandings about the needs for, and barriers to, positive change. This study explores consensus about risks and uncertainties in adjacent boroughs grappling with rapid social–ecological transformations in northern Alaska. The Northwest Arctic and North Slope boroughs, like the rest of the Arctic, are coping with a climate that is warming twice as fast as in other regions. The boroughs are predominantly inhabited by Iñupiat people, for whom the region is ancestral grounds, whose livelihoods are still supported by subsistence activities, and whose traditional tribal governance has been weakened through multiple levels of governing bodies and institutions. Drawing on extensive workshop discussions and survey experiments conducted with residents of the two boroughs, we developed a model of the northern Alaska region’s social–ecological system and its drivers of change. Using cultural consensus analysis, we gauged the extent of consensus across the boroughs about what key risks threaten the sustainability of their communities. Though both boroughs occupy vast swaths of land, each with their own resource, leadership, and management challenges, we found strong consensus around how risks that impact the sustainability of communities are evaluated and prioritized. Our results further confirmed that rapid and complex changes are creating high levels of uncertainties for community planners in both boroughs. We discuss the mobilizing potential of risk consensus toward collective adaptation action in the civic process of policy making. We note the contribution of cultural consensus analysis as a tool for cross-scale learning in areas coping with rapid environmental changes and complex social challenges.

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“…Сокращение площади морского льда оказывает прямое воздействие на многие морские и прибрежные виды, находящиеся в зависящих ото льда пищевых цепочках [6,18], ставя некоторые из них на грань выживания. Уменьшение площади морского льда также имеет широкие косвенные последствия, в том числе путем воздействия на температуру и количество осадков на суше [18,20]. Условия открытой воды повышают вероятность выпадения осадков в жидкой фазе, которые могут приводить к образованию ледяной корки на снегу, препятствующей питанию животных.…”

Section: экологические последствия сокращения морского ледяного покроваunclassified

Climate Change in Arctica: Local and Global Impact on the Environment

Сердитова¹

2020

Вестник Тверского Государственного Университета. Серия: География И Геоэкология

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В работе сделан обзор последних научных исследований в области изменения климата в полярных районах и связанных с этими изменениями рисками. Отмечен ускоренный характер потепления в арктическом регионе и высокая чувствительность окружающей среды и инженерной инфраструктуры к происходящим изменениям. Рассмотрены возможные пути адаптации к этим изменениям, смягчение их последствий и информационно-образовательные аспекты. Results of recent research on climate change in polar regions and the risks associated are reviewed. The accelerated nature of warming in the Arctic region and the high sensitivity of the environment and engineering infrastructure to the changes are noted. Possible ways of adaptation to these changes, mitigation of their consequences, and informational and educational aspects are considered.

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The Expanding Footprint of Rapid Arctic Change

Cited by 48 publications

References 53 publications

Miocene Evolution of North Atlantic Sea Surface Temperature

Miocene Evolution of North Atlantic Sea Surface Temperature

Risks Without Borders: A Cultural Consensus Model of Risks to Sustainability in Rapidly Changing Social–Ecological Systems

Climate Change in Arctica: Local and Global Impact on the Environment

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