邻近两个残岩冰川(Niedere Tauern Range, Austria)块状表层小气候的控制因素

IF 1.4 4区地球科学 Q3 GEOGRAPHY, PHYSICAL

Geografiska Annaler Series A-Physical Geography Pub Date : 2019-09-28 DOI:10.1080/04353676.2019.1670950

T. Wagner, Marcus Pauritsch, C. Mayaud, A. Kellerer‐Pirklbauer, Felix Thalheim, G. Winkler

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引用次数: 12

摘要

与其他类型的松散地表材料相比，粗块状材料具有冷却地面的作用，这可能对多年冻土的空间分布和保存产生影响。在气候变暖的情况下，这种效应通常会延缓永久冻土退化或延长地面冷却时间。为了更好地理解这种地面冷却效应和潜在的影响因素，研究了两个具有相反方面的可比较的邻近残岩冰川的块状表面层的热状态。分布在两个岩石冰川上的9个地点，在4年期间连续测量了1米深度的空气、地表和浅层地温。尽管潜在太阳辐射较高，但西风暴露的块状岩石冰川表层温度较北东向低且不均匀。数据表明，在西南暴露的岩石冰川上，季节性积雪更薄或更不连续，导致更有效的冬季冷却。数据支持了气流驱动传热作为冷却源的重要性。结果表明，在高起伏地形中，块状层内的热非均质性和季节性积雪模式的重要性以及地形和小气候变化都是假设的。

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Controlling factors of microclimate in blocky surface layers of two nearby relict rock glaciers (Niedere Tauern Range, Austria)

ABSTRACT Coarse blocky material is known to have a ground cooling effect compared to other types of unconsolidated surface material, which may have an influence on spatial distribution and conservation of permafrost. In the light of climate warming, this effect may retard permafrost degradation or exert prolonged ground cooling in general. To contribute to a better understanding of this ground cooling effect and potential influencing factors, the thermal regime of blocky surface layers of two comparable nearby relict rock glaciers with opposing aspects was investigated. Air, surface and shallow ground temperature at 1 m depth were continuously measured over a four-year period at nine locations distributed over two rock glaciers. The blocky surface layer of the SW-exposed rock glacier exhibits lower and more heterogeneous temperatures than the NE-oriented despite a higher potential solar radiation. The data suggest a thinner or more discontinuous seasonal snow cover at the SW-exposed rock glacier, causing a more efficient winter cooling. The importance of air flow driven heat transfer as a source of cooling is supported by the data. Results illustrate thermal heterogeneities within blocky layers and the importance of the seasonal snow cover pattern in addition to topography and microclimatic variability in high relief terrain is hypothesized.

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来源期刊

Geografiska Annaler Series A-Physical Geography 地学-地质学

CiteScore

3.60

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： Geografiska Annaler: Series A, Physical Geography publishes original research in the field of Physical Geography with special emphasis on cold regions/high latitude, high altitude processes, landforms and environmental change, past, present and future. The journal primarily promotes dissemination of regular research by publishing research-based articles. The journal also publishes thematic issues where collections of articles around a specific themes are gathered. Such themes are determined by the Editors upon request. Finally the journal wishes to promote knowledge and understanding of topics in Physical Geography, their origin, development and current standing through invited review articles.