Abstract
Abstract. In this paper we present a method to detect airflow through ice caves and to quantify the corresponding airflow speeds by the use of temperature loggers. The time series of temperature observations at different loggers are cross-correlated. The time shift of best correlation corresponds to the travel time of the air and is used to derive the airflow speed between the loggers. We apply the method to test data observed inside Schellenberger Eishöhle (ice cave). The successful determination of airflow speeds depends on the existence of distinct temperature variations during the time span of interest. Moreover the airflow speed is assumed to be constant during the period used for the correlation analysis. Both requirements limit the applicability of the correlation analysis to determine instantaneous airflow speeds. Nevertheless the method is very helpful to characterize the general patterns of air movement and their slow temporal variations. The correlation analysis assumes a linear dependency between the correlated data. The good correlation we found for our test data confirms this assumption. We therefore in a second step estimate temperature biases and scale factors for the observed temperature variations by a least-squares adjustment. The observed phenomena, a warming and an attenuation of temperature variations, depending on the distance the air traveled inside the cave, are explained by a mixing of the inflowing air with the air inside the cave. Furthermore we test the significance of the determined parameters by a standard F test and study the sensitivity of the procedure to common manipulations of the original observations like smoothing. In the end we will give an outlook on possible applications and further development of this method.
Highlights
Ice cave research in its historical dimension has a long history in Europe (Grebe, 2010), which dates back to the 16th century
Most climate studies in ice caves concentrate on air, ice, and rock temperature, as temperature loggers are available for relatively low prices and affordable for private studies by, e.g., speleological organizations
The objective of this paper is to present the principles and the methodology of the calcFLOW method that was developed in order to be able to use air temperature measurements in static ice caves to define the airflow regime
Summary
Ice cave research in its historical dimension has a long history in Europe (Grebe, 2010), which dates back to the 16th century. Theories about the origin of the cave ice are old, numerous, and contradictory, depending on the scientific knowledge and ability to conduct measurements in the respective century. In the nineteenth century the first instrumental measurements were conducted (compare Thury, 1861; Fugger, 1888; Lohmann, 1895; Crammer, 1899) before modern ice cave research found its beginning with the works of, e.g., Bock (1913), Racovitza (1927), Saar (1956), and others. Right from the beginning the main focus was to understand the processes and dynamics of the ice body and specific cave climate elements; among those, the course of the air temperature in the specific study sites as well as the airflow regime were a main focus. Depending on the individual questioning, this may be sufficient for a basic cave climate analy-
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