Abstract
With snow cover changing worldwide in several worrisome ways, it is imperative to determine both the variability in snow cover in greater detail and its relationship with ongoing climate change. Here, we used the satellite-based snow cover extent (SCE) dataset of National Oceanic and Atmospheric Administration (NOAA) to detect SCE variability and its linkages to climate over the 1967–2018 periods across the Northern Hemisphere (NH). Interannually, the time series of SCE across the NH reveal a substantial decline in both spring and summer (−0.54 and −0.71 million km2/decade, respectively), and this decreasing trend corresponded with rising spring and summer temperatures over high-latitude NH regions. Among the four seasons, the temperature rise over the NH was the highest in winter (0.39 °C/decade, p < 0.01). More precipitation in winter was closely related to an increase of winter SCE in mid-latitude areas of NH. Summer precipitation over the NH increased at a significant rate (1.1 mm/decade, p < 0.01), which likely contribute to the accelerated reduction of summer’s SCE across the NH. However, seasonal sensitivity of SCE to temperature changes differed between the Eurasian and North American continents. Thus, this study provides a better understanding of seasonal SCE variability and climatic changes that occurred at regional and hemispheric spatial scales in the past 52 years.
Highlights
The maximum terrestrial snow cover extent (SCE) over the land surfaces of the NorthernHemisphere (NH) is approximately 47 million km2 for the end of 20th century [1,2], covering nearly half of its landmass
This study investigated the variability of seasonal SCE and climate over the Northern Hemisphere (NH) and revealed that, over the past half-century, the loss of SCE has accelerated in spring and summer, but not in autumn or winter
These trends are closely associated with significant seasonal warming over the NH, Eurasia (EA), and North America (NA) during the 1967–2018 periods
Summary
The maximum terrestrial snow cover extent (SCE) over the land surfaces of the NorthernHemisphere (NH) is approximately 47 million km for the end of 20th century [1,2], covering nearly half of its landmass. The maximum terrestrial snow cover extent (SCE) over the land surfaces of the Northern. Terrestrial snow cover is the most extensive component of the cryosphere, and the most seasonally and rapidly changing cryospheric variable [3]. This pronounced variability in pattern, area, and spatiotemporal distribution of snow cover over the NH strongly affects the surface energy balance, water cycle, climatic changes, ecosystem environment, and human activities [4,5]. Reduced spring snow cover corresponds to anomalously dry local soil conditions from spring to the following summer, thereby increasing surface the heat flux and near-surface temperatures. Cohen [7] studied the potential impact of snow cover anomalies on remote and local atmospheric dynamics, showing that snow cover
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