Arctic Sea Level and Surface Circulation Response to the Arctic Oscillation

Armitage, Thomas; Bacon, Sheldon; Kwok, R.

doi:10.1029/2018gl078386

Cited by 51 publications

(49 citation statements)

References 24 publications

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“…Alkire et al () point out the large interannual variability in surface salinity in the central Arctic, partly attributed to shifts in the alignment of the TPD. Several studies document the contribution of the Arctic Oscillation index in the shifts of the TPD and Arctic general surface circulation (Alkire et al, ; Armitage et al, ; Morison et al, ). However, the relationship between Arctic Oscillation and river runoff pathways in the present data set remains unclear.…”

Section: Summary and Discussionmentioning

confidence: 99%

New Hydrographic Measurements of the Upper Arctic Western Eurasian Basin in 2017 Reveal Fresher Mixed Layer and Shallower Warm Layer Than 2005–2012 Climatology

et al. 2019

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In 2017, Ice Atmosphere Ocean Observing System autonomous drifting platforms provided extensive physical and biogeochemical data in the upper 350 m of the western Eurasian Basin through their 8‐month drift across the Amundsen Basin, the Gakkel Ridge, the Nansen Basin and western Fram Strait. Comparison with WOA13 climatology indicates a fresher surface layer and shallower warm layer in 2017 than in 2005–2012. The Ice Atmosphere Ocean Observing System 2017 data feature two halocline eddies in the Amundsen Basin and two Atlantic Water (AW) mesoscale structures in the Nansen Basin. Analysis of the global (1/12)° Mercator Ocean operational system suggests that the halocline eddies resulted from instabilities in the frontal zone between fresher Makarov waters and saltier Eurasian waters. This frontal region appears to have shifted further southeast in 2017 (near 88°N, 10°E) compared to 2005–2012. The operational system depicts the large AW structure in the Nansen Basin (140 km crossed as far as 83.7°N, 34.5°E) as an AW meander from the Arctic Circumpolar Boundary Current, which turned into an anticyclonic eddy about a month after the platforms drifted away. The AW structure at 82.8°N, 3°W, northwest of the Yermak Plateau, corresponds to an AW recirculating branch detaching from the Yermak Plateau slope back toward Fram Strait.

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Section: Summary and Discussionmentioning

confidence: 99%

New Hydrographic Measurements of the Upper Arctic Western Eurasian Basin in 2017 Reveal Fresher Mixed Layer and Shallower Warm Layer Than 2005–2012 Climatology

et al. 2019

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“…The current work focuses on only the contributions of SSTAs in the tropical Pacific and NA oceans, which can explain only part of the SPC variance. Other factors, such as the SSTAs in the Indian Ocean, snow cover over the Eurasian continent, sea ice over the polar region, anomalous Tibetan Plateau heating, and greenhouse gases, may also contribute to the interdecadal change in the SPC variation (e.g., Armitage et al, ; Dunstone et al, ; Jia et al, ; Li et al, ; Menon et al, ; Xing & Huang, ). For example, some recent studies (Armitage et al, ; Dunstone et al, ; Xing & Huang, ) have revealed that the sea ice concentration in the Arctic during the preceding autumn might signify anomalous NAO and SST conditions in the NA, which can persist until early summer and affect EA precipitation in May–June.…”

Section: Summary and Discussionmentioning

confidence: 99%

Interdecadal Changes in the Dominant Modes of the Interannual Variation of Spring Precipitation over China in the Mid‐1980s

Jia

You

et al. 2019

JGR Atmospheres

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In this study, the leading empirical orthogonal function mode of the interannual variations of boreal spring (April–May) precipitation over China (SPC) is shown to shift from a mono‐sign distribution during 1964–1985 (P1), with the largest loading over southern China, to a north‐south dipole structure during 1986–2004 (P2), with the northern and southern poles centered over the Yangtze River and the Pearl River Delta, respectively. The results show that the El Niño‐Southern Oscillation(ENSO)‐related negative western tropical Pacific sea surface temperature anomalies persist longer from the previous winter into the following spring in P2 than in P1. The ENSO‐related western tropical Pacific anticyclone in spring is stronger and extends farther northeastward after the mid‐1980s. As a result, in P2, the moisture transport by anomalous southerly winds along the western flank of the western tropical Pacific anticyclone penetrates northward to central China, and moisture convergence and divergence are observed over the Yangtze River and southern China, respectively. The SPC‐related North Atlantic sea surface temperature anomalies (NAST) are stronger after the mid‐1980s than before the mid‐1980s, and the NAST‐related atmospheric wave train over the middle‐latitude Eurasian continent is more pronounced in P2 than in P1. Furthermore, to the east of 90°E, the downstream propagation pathway of the NAST‐related wave train turns southeastward, which may be caused by the weakened intensity of the meridional gradient of the potential vorticity over this region. The pronounced wave train‐related positive height anomalies over the western North Pacific favor a north‐south dipole structure in the SPC variation in P2.

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“…HE Cryosat-2 Synthetic Aperture Interferometric Radar Altimeter (SIRAL) has proven an immensely successful tool for monitoring global ice and ocean properties. It has allowed us to estimate interannual ice sheet mass balance [1], the global marine gravity field [2] circulation [3,4], and sea ice thickness [5,6], with unprecedented spatial coverage, frequency and accuracy. Recent work has demonstrated that sea ice extent is closely tied to the inter-seasonal 'memory' of ice thickness [7], which means that sea ice models initialized with thickness observations can substantially improve the skill of ice extent forecasts [8,9,10].…”

Section: Introductionmentioning

confidence: 99%

A Facet-Based Numerical Model for Simulating SAR Altimeter Echoes From Heterogeneous Sea Ice Surfaces

Landy

Scharien

2019

IEEE Trans. Geosci. Remote Sensing

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Cryosat-2 has provided measurements of pan-Arctic sea ice thickness since 2010 with unprecedented spatial coverage and frequency. However, it remains uncertain how the Ku-band radar interacts with the vast range of scatterers that can be present within the satellite footprint, including sea ice with varying physical properties and multi-scale roughness, snow cover, and leads. Here, we present a numerical model designed to simulate delay-Doppler SAR (Synthetic Aperture Radar) altimeter echoes from snow-covered sea ice, such as those detected by Cryosat-2. Backscattered echoes are simulated directly from triangular facetbased models of actual sea ice topography generated from Operation IceBridge Airborne Topographic Mapper (ATM) data, as well as virtual statistical models simulated artificially. We use these waveform simulations to investigate the sensitivity of SAR altimeter echoes to variations in satellite parameters (height, pitch, roll) and sea ice properties (physical properties, roughness, presence of water). We show that the conventional Gaussian assumption for sea ice surface roughness may be introducing significant error into the Cryosat-2 waveform retracking process. Compared to a more representative lognormal surface, an echo simulated from a Gaussian surface with rms roughness height of 0.2 m underestimates the ice freeboard by 5 cmpotentially underestimating sea ice thickness by around 50 cm. We present a set of 'ideal' waveform shape parameters simulated for sea ice and leads to inform existing waveform classification techniques. This model will ultimately be used to improve retrievals of key sea ice properties, including freeboard, surface roughness and snow depth, from SAR altimeter observations.

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Arctic Sea Level and Surface Circulation Response to the Arctic Oscillation

Cited by 51 publications

References 24 publications

New Hydrographic Measurements of the Upper Arctic Western Eurasian Basin in 2017 Reveal Fresher Mixed Layer and Shallower Warm Layer Than 2005–2012 Climatology

New Hydrographic Measurements of the Upper Arctic Western Eurasian Basin in 2017 Reveal Fresher Mixed Layer and Shallower Warm Layer Than 2005–2012 Climatology

Interdecadal Changes in the Dominant Modes of the Interannual Variation of Spring Precipitation over China in the Mid‐1980s

A Facet-Based Numerical Model for Simulating SAR Altimeter Echoes From Heterogeneous Sea Ice Surfaces

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