Abstract
Abstract. Glaciers in the tropical Andes of southern Peru have received limited attention compared to glaciers in other regions (both near and far), yet remain of vital importance to agriculture, fresh water, and hydropower supplies of downstream communities. Little is known about recent glacial-area changes and how the glaciers in this region respond to climate changes, and, ultimately, how these changes will affect lake and water supplies. To remedy this, we have used 158 multi-spectral satellite images spanning almost 4 decades, from 1975 to 2012, to obtain glacial- and lake-area outlines for the understudied Cordillera Vilcanota region, including the Quelccaya Ice Cap. Additionally, we have estimated the snow-line altitude of the Quelccaya Ice Cap using spectral unmixing methods. We have made the following four key observations: first, since 1988 glacial areas throughout the Cordillera Vilcanota (1988 glacial area: 361 km2) have been declining at a rate of 3.99 ± 1.15 km2 yr−1 (22 year average, 1988–2010, with 95% confidence interval (CI), n = 8 images). Since 1980, the Quelccaya Ice Cap (1980 glacial area: 63.1 km2) has been declining at a rate of 0.57 ± 0.10 km2 yr−1 (30 year average, 1980–2010, with 95% CI, n = 14). Second, decline rates for individual glacierized regions have been accelerating during the past decade (2000–2010) as compared to the preceding decade (1988–1999) with an average increase from 37.5 to 42.3 × 10−3 km2 yr−1 km−2 (13%). Third, glaciers with lower median elevations are declining at higher rates than those with higher median elevations. Specifically, glaciers with median elevations around 5200 m a.s.l. are retreating to higher elevations at a rate of ~1 m yr−1 faster than glaciers with median elevations around 5400 m a.s.l. Fourth, as glacial regions have decreased, 77% of lakes connected to glacial watersheds have either remained stable or shown a roughly synchronous increase in lake area, while 42% of lakes not connected to glacial watersheds have declined in area (58% have remained stable). Our new and detailed data on glacial and lake areas over 37 years provide an important spatiotemporal assessment of climate variability in this area. These data can be integrated into further studies to analyze inter-annual glacial and lake-area changes and assess hydrologic dependence and consequences for downstream populations.
Highlights
Glaciers are thought of as excellent indicators of climate change, as small climate variations can produce rapid glacial changes (e.g., Soruco et al, 2009; IPCC, 2007; Vuille et al, 2008a; Rabatel et al, 2013)
We first present our glacial results by focusing on the Quelccaya Ice Cap (Glacial ID 1), and we expand to the Cordillera Vilcanota as a whole
Results for five different proglacial lakes follow, including four located along the western margins of the Quelccaya Ice Cap (QIC), after which we present our snow-line estimates for the QIC
Summary
Glaciers are thought of as excellent indicators of climate change, as small climate variations can produce rapid glacial changes (e.g., Soruco et al, 2009; IPCC, 2007; Vuille et al, 2008a; Rabatel et al, 2013). Glacial retreat and mass-balance loss as a result of warming trends may have significant consequences in this region: the current state and future fate of Andean glaciers and seasonal snow cover are of central importance for the water, food, and power supplies of densely populated regions in countries including Peru and Bolivia (Kaser et al, 2010; Barnett et al, 2005; Bradley et al, 2006). Bookhagen: Glacial areas, lake areas, and snow lines from 1975 to 2012
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