Monitoring permafrost and periglacial processes in Sierra Nevada (Spain) from 2001 to 2016

Gómez‐Ortiz, Antonio; Oliva, Marc; Franch, Ferran Salvador; Palacios, David; Tanarro, Luis M.; Blasco, José Juan de Sanjosé; Catarineu, Montserrat Salvà

doi:10.1002/ppp.2002

Cited by 19 publications

(9 citation statements)

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“…In Sierra Nevada, the remnants of LIA glaciers are preserved in the form of ice bodies and permafrost patches buried under a thick debris cover (Gómez-Ortiz et al 2014). Some permafrost-related landforms, such as protalus lobes and rock glaciers, developed above those subsurface frozen masses, though their degradation in response to warming is accelerating their stabilization and generating subsidence and collapses on the surface debris cover (Gómez-Ortiz et al 2019). If the decrease of winter precipitation and increase of annual temperatures continue (Pérez-Luque et al 2016), it is expected that the fossil relict ice and permafrost will disappear in the next decades.…”

Section: Discussionmentioning

confidence: 99%

“…Currently, there are no glaciers in Sierra Nevada and periglacial dynamics prevail between 2600 m and the summits above 3400 m; small permanent snow fields only exist in northern glacial cirques at the foot of the highest peaks (Gómez-Ortiz et al 2019). Mean annual air temperatures at 2500 m average 4.4 °C with an annual precipitation of 710 mm, in the form of snow between October and May (1965-1992, Oliva et al 2014b.…”

Section: Study Areamentioning

confidence: 99%

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Multiproxy reconstruction of Holocene glaciers in Sierra Nevada (south Spain)

et al. 2019

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Pleistocene glaciers shaped the highest lands of the National Park of Sierra Nevada, South Spain. Alpine glaciers filled the western valleys of the massif with hundreds of meters of ice. Surface exposure dating shows evidence of glacial expansion during the Younger Dryas and the subsequent disappearance of glaciers of the massif during the Early Holocene. Since then, glacial records and lake sediments reveal that the massif has been ice-free for the most part of the Holocene, with the development of small glaciers during the coldest phases inside the highest northern cirques. This occurred at 2.8-2.7, 1.4-1.2 cal. ka BP and during the Little Ice Age (1300-1850 CE), when documentary sources confirm also the existence of some glaciers at the foot of the highest summits. This historical period was probably the coldest and wettest phase of the Holocene in the massif and recorded the largest glaciers of the current interglacial. Those glaciers finally melted away during the mid-20th century.

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Section: Discussionmentioning

confidence: 99%

Section: Study Areamentioning

confidence: 99%

Multiproxy reconstruction of Holocene glaciers in Sierra Nevada (south Spain)

et al. 2019

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“…Located in the southern fringe of Iberia at latitude of 37ºN, the Sierra Nevada is the highest massif of the Betic Range (Fig.1) (Atlantic/Mediterranean) and subtropical high pressure belt/mid-latitude westerlies (Oliva et al, 2011). Currently, the mean annual air temperature at 2500 m is 4.4 ºC , whereas at the highest summits of the massif at 3400 it is 0 ºC (2001-2016) (Gómez-Ortiz et al, 2019). Annual precipitation reaches 710 mm, mostly as snow between October and April (Oliva, 2009;Oliva et al, 2008).…”

Section: Study Areamentioning

confidence: 99%

“…2019) and a protalus lobe in the Mulhacén cirque (Serrano et al, 2018), where small isolated permafrost patches exist under the debris cover Serrano et al, 2018). These landforms are geoindicators of the end of cold periods and are out of balance with current climate conditions, and therefore, tend to become inactive Gómez-Ortiz et al, 2019).…”

Section: Common and Diverse Geomorphological Phases In The Sierra Nevmentioning

confidence: 99%

“…These processes, highly sensitive to small climatic variations, led to intense geomorphic readjustments typical of the paraglacial phase (Oliva et al, 2016;Palacios et al, 2019;Serrano et al, 2018;Gómez-Ortiz et al, 2019 and references therein). As a result, landforms from this cirque are considered key geoindicators for monitoring the impact of climate change on mountain geomorphological processes in southern Europe (Gómez-Ortiz et al, 2019). The other cirque that hosted a glacier during the LIA in the Sierra Nevada is located under the northern rock wall of Mulhacén peak.…”

Section: Introductionmentioning

confidence: 99%

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Climate sensitivity and geomorphological response of cirque glaciers from the late glacial to the Holocene, Sierra Nevada, Spain

Palacios

Oliva

Gómez‐Ortiz

et al. 2020

Quaternary Science Reviews

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Through a detailed geomorphological study, including thourough mapping of the geomorphic features as well as 10 Be Cosmic-Ray Exposure (CRE) dating, the geomorphological evolution of the Mulhacén cirque since the maximum ice extent of the last glacial cycle until nowadays was determined. This glacial cirque is shaped on the northern face of the Mulhacén peak (3479 m a. .l., 37 03 12 N / 3 18 41 W), Sierra Nevada, southern Spain. It includes several depositional and erosional glacial landforms that allowed reconstructing its environmental evolution since the last glacial cycle. Furthermore, the sequence of glacial oscillations from this site was compared to that of other cirques of the massif, evidencing that: (i) new glaciers formed in these cirques during the Younger Dryas (YD), and (ii) disappeared at 11.7 ± 1.0 ka. Depending on the altitude, orientation and height of the cirque walls, the final deglaciation of the cirques generated a diversity of landscapes, including a wide range of glacial and periglacial landforms, such as polished surfaces, sequences of moraines, proto-rock glaciers or large rock glacier systems. No glaciers existed in the Sierra Nevada during the Middle Holocene. Only the cirques whose summits exceed 3300 m, are north-exposed and whose walls exceed 300 m high (i.e. Mulhacén and Veleta) hosted glaciers during Neoglacial phases, including the Little Ice Age (LIA) (approx. 1300-1850 CE). During these periods, climate oscillations favoured the formation of small glaciers in these cirques, which generated large moraine systems with either one polygenic ridge or a sequence of spaced frontal arcs. The existence of glaciers impeded the formation of permafrost-related Manuscript File Click here to vie linked References 2 landforms, such as rock glaciers and protalus lobes until the end of the LIA, when they started to form. These results are compared with the deglacial evolution in 55 cirques from Iberian mountains as well as from glacial cirques from other mid-latitude mountains and subpolar regions. The chronology of their deglaciation as well as the landforms generated during glacial retreat followed similar patterns, with no significant differences at regional scale. For each mountain range, the geomorphological diversity existing in each cirque depends on the local topographic characteristics although they formed during the same climatic phases.

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Spatio‐temporal patterns of snow in the Catalan Pyrenees (NE Iberia)

Bonsoms

González

Prohom³

et al. 2021

Intl Journal of Climatology

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In a warmer climate, significant variations in the snow regime are expected. Thus, it is crucial to better understand present‐day snow cover regime, its duration and thickness, in order to anticipate future changes. This work presents the first characterization of snow patterns in the Catalan Pyrenees based on 11 snow stations located in high elevation areas (>2,000 m). Here, we examine spatio‐temporal evolution of the daily snow depth and new snow height (HN) since the earliest 2000s to 2020. In addition, we analyse the different synoptic patterns that cause HN events in the study area as well as the low frequency climate modes on the different stages of the snow season. Our results show evidence that the measured snow amount differs considerably between the western and the eastern Catalan Pyrenees independently of the considered elevation. While the eastern part has an average seasonal cumulative HN of 278 cm, the western sector gets almost twice (433 cm). Nonetheless, the onset of the snow melting does not show substantial differences, being primarily ruled by the elevation in both areas. The longest snow records (Núria, 1971 m) point to an increase of HN from 1985 to 2020, a trend which is also observed in most stations from 2000 to 2020. Nevertheless, some stations of the N western fringe record negative trends associated with the low frequency variability of the Western Mediterranean Oscillation (WeMO). Results also indicate that the NW Atlantic low‐pressure systems are the circulation weather types that provide more abundant HN in the majority of snow stations. The Atlantic advections are more frequent in autumn and winter, while the Mediterranean advections provide more intense and recurrent HN in spring. The atmospheric circulation is basically ruled by the East Atlantic/West Russia and the WeMO teleconnection patterns.

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Monitoring permafrost and periglacial processes in Sierra Nevada (Spain) from 2001 to 2016

Cited by 19 publications

References 50 publications

Multiproxy reconstruction of Holocene glaciers in Sierra Nevada (south Spain)

Multiproxy reconstruction of Holocene glaciers in Sierra Nevada (south Spain)

Climate sensitivity and geomorphological response of cirque glaciers from the late glacial to the Holocene, Sierra Nevada, Spain

Spatio‐temporal patterns of snow in the Catalan Pyrenees (NE Iberia)

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