Arctic landscapes in transition: Responses to thawing permafrost

J. C. Rowland; C. E. Jones; G. Altmann; R. Bryan; B. T. Crosby; G. L. Geernaert; L. D. Hinzman; D. L. Kane; D. M. Lawrence; A. Mancino; P. Marsh; J. P. McNamara; V. E. Romanovsky; H. Toniolo; B. J. Travis; E. Trochim; C. J. Wilson

doi:10.1029/2010EO260001

Arctic landscapes in transition: Responses to thawing permafrost

J. C. Rowland, C. E. Jones, G. Altmann, R. Bryan, B. T. Crosby, G. L. Geernaert, L. D. Hinzman, D. L. Kane, D. M. Lawrence, A. Mancino, P. Marsh, J. P. McNamara, V. E. Romanovsky, H. Toniolo, B. J. Travis, E. Trochim, C. J. Wilson

Geosciences Department

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Abstract

Observations indicate that over the past several decades, geomorphic processes in the Arctic have been changing or intensifying. Coastal erosion, which currently supplies most of the sediment and carbon to the Arctic Ocean [Rachold et al., 2000], may have doubled since 1955 [Mars and Houseknecht, 2007]. Further inland, expansion of channel networks [Toniolo et al., 2009] and increased river bank erosion [Costard et al., 2007] have been attributed to warming. Lakes, ponds, and wetlands appear to be more dynamic, growing in some areas, shrinking in others, and changing distribution across lowland regions [e.g., Smith et al., 2005]. On the Arctic coastal plain, recent degradation of frozen ground previously stable for thousands of years suggests 10-30% of lowland and tundra landscapes may be affected by even modest warming [Jorgenson et al., 2006]. In headwater regions, hillslope soil erosion and landslides are increasing [e.g., Gooseff et al., 2009].

Original language	American English
Pages (from-to)	229-230
Number of pages	2
Journal	Eos
Volume	91
Issue number	26
DOIs	https://doi.org/10.1029/2010EO260001
State	Published - 29 Jun 2010

Keywords

Arctic
geomorphology
hydrology
permafrost

EGS Disciplines

Earth Sciences
Geophysics and Seismology

UN SDGs

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

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10.1029/2010EO260001

Arctic Landscapes in Transition Responses to Thawing PermafrostFinal published version, 195 KBLicense: Unspecified

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Rowland, J. C., Jones, C. E., Altmann, G., Bryan, R., Crosby, B. T., Geernaert, G. L., Hinzman, L. D., Kane, D. L., Lawrence, D. M., Mancino, A., Marsh, P., McNamara, J. P., Romanovsky, V. E., Toniolo, H., Travis, B. J., Trochim, E., & Wilson, C. J. (2010). Arctic landscapes in transition: Responses to thawing permafrost. Eos, 91(26), 229-230. https://doi.org/10.1029/2010EO260001

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title = "Arctic landscapes in transition: Responses to thawing permafrost",

abstract = "Observations indicate that over the past several decades, geomorphic processes in the Arctic have been changing or intensifying. Coastal erosion, which currently supplies most of the sediment and carbon to the Arctic Ocean [Rachold et al., 2000], may have doubled since 1955 [Mars and Houseknecht, 2007]. Further inland, expansion of channel networks [Toniolo et al., 2009] and increased river bank erosion [Costard et al., 2007] have been attributed to warming. Lakes, ponds, and wetlands appear to be more dynamic, growing in some areas, shrinking in others, and changing distribution across lowland regions [e.g., Smith et al., 2005]. On the Arctic coastal plain, recent degradation of frozen ground previously stable for thousands of years suggests 10-30% of lowland and tundra landscapes may be affected by even modest warming [Jorgenson et al., 2006]. In headwater regions, hillslope soil erosion and landslides are increasing [e.g., Gooseff et al., 2009].",

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AU - Rowland, J. C.

AU - Jones, C. E.

AU - Altmann, G.

AU - Bryan, R.

AU - Crosby, B. T.

AU - Geernaert, G. L.

AU - Hinzman, L. D.

AU - Kane, D. L.

AU - Lawrence, D. M.

AU - Mancino, A.

AU - Marsh, P.

AU - McNamara, J. P.

AU - Romanovsky, V. E.

AU - Toniolo, H.

AU - Travis, B. J.

AU - Trochim, E.

AU - Wilson, C. J.

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N2 - Observations indicate that over the past several decades, geomorphic processes in the Arctic have been changing or intensifying. Coastal erosion, which currently supplies most of the sediment and carbon to the Arctic Ocean [Rachold et al., 2000], may have doubled since 1955 [Mars and Houseknecht, 2007]. Further inland, expansion of channel networks [Toniolo et al., 2009] and increased river bank erosion [Costard et al., 2007] have been attributed to warming. Lakes, ponds, and wetlands appear to be more dynamic, growing in some areas, shrinking in others, and changing distribution across lowland regions [e.g., Smith et al., 2005]. On the Arctic coastal plain, recent degradation of frozen ground previously stable for thousands of years suggests 10-30% of lowland and tundra landscapes may be affected by even modest warming [Jorgenson et al., 2006]. In headwater regions, hillslope soil erosion and landslides are increasing [e.g., Gooseff et al., 2009].

AB - Observations indicate that over the past several decades, geomorphic processes in the Arctic have been changing or intensifying. Coastal erosion, which currently supplies most of the sediment and carbon to the Arctic Ocean [Rachold et al., 2000], may have doubled since 1955 [Mars and Houseknecht, 2007]. Further inland, expansion of channel networks [Toniolo et al., 2009] and increased river bank erosion [Costard et al., 2007] have been attributed to warming. Lakes, ponds, and wetlands appear to be more dynamic, growing in some areas, shrinking in others, and changing distribution across lowland regions [e.g., Smith et al., 2005]. On the Arctic coastal plain, recent degradation of frozen ground previously stable for thousands of years suggests 10-30% of lowland and tundra landscapes may be affected by even modest warming [Jorgenson et al., 2006]. In headwater regions, hillslope soil erosion and landslides are increasing [e.g., Gooseff et al., 2009].

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KW - geomorphology

KW - hydrology

KW - permafrost

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UR - https://scholarworks.boisestate.edu/geo_facpubs/28

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JO - Eos

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ER -

Arctic landscapes in transition: Responses to thawing permafrost

Abstract

Keywords

EGS Disciplines

UN SDGs

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