A Convergence Science Approach to Understanding the Changing Arctic

Valeriy Y. Ivanov; Peter S. Ungar; John P. Ziker; Svetlana Abdulmanova; Gerardo Celis; Andrew Dixon; Dorothee Ehrich; Ivan Fufachev; Olivier Gilg; Mary Heskel; Desheng Liu; Marc Macias-Fauria; Valeriy Mazepa; Karl Mertens; Pavel Orekhov; Alexandria Peterson; Olga Pokrovskaya; Aleksey Sheshukov; Aleksandr Sokolov; Natalia Sokolova; Marcus Spiegel; Matt Sponheimer; Florian Stammler; Tyeen Taylor; Alexandra Terekhina; Victor Valdayskikh; Alexander Volkovitskiy; Jingfeng Wang; Wenbo Zhou

doi:10.1029/2023EF004157

A Convergence Science Approach to Understanding the Changing Arctic

Valeriy Y. Ivanov, Peter S. Ungar, John P. Ziker, Svetlana Abdulmanova, Gerardo Celis, Andrew Dixon, Dorothee Ehrich, Ivan Fufachev, Olivier Gilg, Mary Heskel, Desheng Liu, Marc Macias-Fauria, Valeriy Mazepa, Karl Mertens, Pavel Orekhov, Alexandria Peterson, Olga Pokrovskaya, Aleksey Sheshukov, Aleksandr Sokolov, Natalia SokolovaMarcus Spiegel, Matt Sponheimer, Florian Stammler, Tyeen Taylor, Alexandra Terekhina, Victor Valdayskikh, Alexander Volkovitskiy, Jingfeng Wang, Wenbo Zhou

Anthropology Department

Research output: Contribution to journal › Comment/debate

2 Scopus citations

Abstract

Science, engineering, and society increasingly require integrative thinking about emerging problems in complex systems, a notion referred to as convergence science. Due to the concurrent pressures of two main stressors—rapid climate change and industrialization, Arctic research demands such a paradigm of scientific inquiry. This perspective represents a synthesis of a vision for its application in Arctic system studies, developed by a group of disciplinary experts consisting of social and earth system scientists, ecologists, and engineers. Our objective is to demonstrate how convergence research questions can be developed via a holistic view of system interactions that are then parsed into material links and concrete inquiries of disciplinary and interdisciplinary nature. We illustrate the application of the convergence science paradigm to several forms of Arctic stressors using the Yamal Peninsula of the Russian Arctic as a representative natural laboratory with a biogeographic gradient from the forest-tundra ecotone to the high Arctic.

Original language	English
Article number	e2023EF004157
Journal	Earth's Future
Volume	12
Issue number	5
DOIs	https://doi.org/10.1029/2023EF004157
State	Published - May 2024

Keywords

Abrupt/rapid climate change
Arctic climate change
Arctic industrialization
Arctic microcosm
climate impacts
convergence science
emerging questions
human impacts
impacts of global change
new fields

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1029/2023EF004157

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Ivanov, V. Y., Ungar, P. S., Ziker, J. P., Abdulmanova, S., Celis, G., Dixon, A., Ehrich, D., Fufachev, I., Gilg, O., Heskel, M., Liu, D., Macias-Fauria, M., Mazepa, V., Mertens, K., Orekhov, P., Peterson, A., Pokrovskaya, O., Sheshukov, A., Sokolov, A., ... Zhou, W. (2024). A Convergence Science Approach to Understanding the Changing Arctic. Earth's Future, 12(5), Article e2023EF004157. https://doi.org/10.1029/2023EF004157

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title = "A Convergence Science Approach to Understanding the Changing Arctic",

abstract = "Science, engineering, and society increasingly require integrative thinking about emerging problems in complex systems, a notion referred to as convergence science. Due to the concurrent pressures of two main stressors—rapid climate change and industrialization, Arctic research demands such a paradigm of scientific inquiry. This perspective represents a synthesis of a vision for its application in Arctic system studies, developed by a group of disciplinary experts consisting of social and earth system scientists, ecologists, and engineers. Our objective is to demonstrate how convergence research questions can be developed via a holistic view of system interactions that are then parsed into material links and concrete inquiries of disciplinary and interdisciplinary nature. We illustrate the application of the convergence science paradigm to several forms of Arctic stressors using the Yamal Peninsula of the Russian Arctic as a representative natural laboratory with a biogeographic gradient from the forest-tundra ecotone to the high Arctic.",

keywords = "Abrupt/rapid climate change, Arctic climate change, Arctic industrialization, Arctic microcosm, climate impacts, convergence science, emerging questions, human impacts, impacts of global change, new fields",

author = "Ivanov, {Valeriy Y.} and Ungar, {Peter S.} and Ziker, {John P.} and Svetlana Abdulmanova and Gerardo Celis and Andrew Dixon and Dorothee Ehrich and Ivan Fufachev and Olivier Gilg and Mary Heskel and Desheng Liu and Marc Macias-Fauria and Valeriy Mazepa and Karl Mertens and Pavel Orekhov and Alexandria Peterson and Olga Pokrovskaya and Aleksey Sheshukov and Aleksandr Sokolov and Natalia Sokolova and Marcus Spiegel and Matt Sponheimer and Florian Stammler and Tyeen Taylor and Alexandra Terekhina and Victor Valdayskikh and Alexander Volkovitskiy and Jingfeng Wang and Wenbo Zhou",

note = "Publisher Copyright: {\textcopyright} 2024 The Authors. Earth's Future published by Wiley Periodicals LLC on behalf of American Geophysical Union.",

year = "2024",

month = may,

doi = "10.1029/2023EF004157",

language = "English",

volume = "12",

number = "5",

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Ivanov, VY, Ungar, PS, Ziker, JP, Abdulmanova, S, Celis, G, Dixon, A, Ehrich, D, Fufachev, I, Gilg, O, Heskel, M, Liu, D, Macias-Fauria, M, Mazepa, V, Mertens, K, Orekhov, P, Peterson, A, Pokrovskaya, O, Sheshukov, A, Sokolov, A, Sokolova, N, Spiegel, M, Sponheimer, M, Stammler, F, Taylor, T, Terekhina, A, Valdayskikh, V, Volkovitskiy, A, Wang, J & Zhou, W 2024, 'A Convergence Science Approach to Understanding the Changing Arctic', Earth's Future, vol. 12, no. 5, e2023EF004157. https://doi.org/10.1029/2023EF004157

TY - JOUR

T1 - A Convergence Science Approach to Understanding the Changing Arctic

AU - Ivanov, Valeriy Y.

AU - Ungar, Peter S.

AU - Ziker, John P.

AU - Abdulmanova, Svetlana

AU - Celis, Gerardo

AU - Dixon, Andrew

AU - Ehrich, Dorothee

AU - Fufachev, Ivan

AU - Gilg, Olivier

AU - Heskel, Mary

AU - Liu, Desheng

AU - Macias-Fauria, Marc

AU - Mazepa, Valeriy

AU - Mertens, Karl

AU - Orekhov, Pavel

AU - Peterson, Alexandria

AU - Pokrovskaya, Olga

AU - Sheshukov, Aleksey

AU - Sokolov, Aleksandr

AU - Sokolova, Natalia

AU - Spiegel, Marcus

AU - Sponheimer, Matt

AU - Stammler, Florian

AU - Taylor, Tyeen

AU - Terekhina, Alexandra

AU - Valdayskikh, Victor

AU - Volkovitskiy, Alexander

AU - Wang, Jingfeng

AU - Zhou, Wenbo

PY - 2024/5

Y1 - 2024/5

N2 - Science, engineering, and society increasingly require integrative thinking about emerging problems in complex systems, a notion referred to as convergence science. Due to the concurrent pressures of two main stressors—rapid climate change and industrialization, Arctic research demands such a paradigm of scientific inquiry. This perspective represents a synthesis of a vision for its application in Arctic system studies, developed by a group of disciplinary experts consisting of social and earth system scientists, ecologists, and engineers. Our objective is to demonstrate how convergence research questions can be developed via a holistic view of system interactions that are then parsed into material links and concrete inquiries of disciplinary and interdisciplinary nature. We illustrate the application of the convergence science paradigm to several forms of Arctic stressors using the Yamal Peninsula of the Russian Arctic as a representative natural laboratory with a biogeographic gradient from the forest-tundra ecotone to the high Arctic.

AB - Science, engineering, and society increasingly require integrative thinking about emerging problems in complex systems, a notion referred to as convergence science. Due to the concurrent pressures of two main stressors—rapid climate change and industrialization, Arctic research demands such a paradigm of scientific inquiry. This perspective represents a synthesis of a vision for its application in Arctic system studies, developed by a group of disciplinary experts consisting of social and earth system scientists, ecologists, and engineers. Our objective is to demonstrate how convergence research questions can be developed via a holistic view of system interactions that are then parsed into material links and concrete inquiries of disciplinary and interdisciplinary nature. We illustrate the application of the convergence science paradigm to several forms of Arctic stressors using the Yamal Peninsula of the Russian Arctic as a representative natural laboratory with a biogeographic gradient from the forest-tundra ecotone to the high Arctic.

KW - Abrupt/rapid climate change

KW - Arctic climate change

KW - Arctic industrialization

KW - Arctic microcosm

KW - climate impacts

KW - convergence science

KW - emerging questions

KW - human impacts

KW - impacts of global change

KW - new fields

UR - http://www.scopus.com/inward/record.url?scp=85191363393&partnerID=8YFLogxK

U2 - 10.1029/2023EF004157

DO - 10.1029/2023EF004157

M3 - Comment/debate

AN - SCOPUS:85191363393

VL - 12

JO - Earth's Future

JF - Earth's Future

IS - 5

M1 - e2023EF004157

ER -

A Convergence Science Approach to Understanding the Changing Arctic

Abstract

Keywords

UN SDGs

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