Hostname: page-component-8448b6f56d-cfpbc Total loading time: 0 Render date: 2024-04-23T15:56:46.475Z Has data issue: false hasContentIssue false
  • English
  • Français

Thermal Conductivity and the Unfrozen Water Contents of Volcanic Ash Deposits in Cold Climate Conditions: A Review

Published online by Cambridge University Press:  01 January 2024

Elena Kuznetsova
Elena Kuznetsova*
Affiliation:
Norwegian University of Science and Technology, Trondheim, Norway
*
*E-mail address of corresponding author: elena.kuznetsova@ntnu.no
Get access Rights & Permissions [Opens in a new window]

Abstract

Layers of volcanic ash and Andosol soils derived from the ash may play an important role in preserving snow and ice as well as in the development of permafrost conditions in (a) the immediate vicinity of volcanoes at high elevations or at high latitudes and (b) land areas that are often distant from volcanic activity and are either prone to permafrost or covered by snow and ice, but have been affected by subaerial ash deposition. The special properties of volcanic ash are critically reviewed, particularly in relation to recent research in Kamchatka in the Far East of Russia. Of special importance are the thermal properties, the unfrozen water contents of ash layers, and the rate of volcanic glass weathering.Weathering of volcanic glass results in the development of amorphous clay minerals (e.g. allophane, opal, palagonite), but occurs at a much slower rate under cold compared to warm climate conditions. Existing data reveal (1) a strong correlation between the thermal conductivity, the water/ice content, and the mineralogy of the weathered part of the volcanic ash, (2) that an increase in the amounts of amorphous clay minerals (allophane, palagonite) increases the proportion of unfrozen water and decreases the thermal conductivity, and (3) that amorphous silica does not alter to halloysite or other clay minerals, even in the Early Pleistocene age (Kamchatka) volcanic ashes or in the Miocene and Pliocene deposits of Antarctica due to the cold temperatures. The significance of these findings are discussed in relation to past climate reconstruction and the influence of volcanic ash on permafrost aggradation and degradation, snow and ice ablation, and the development of glaciers.

Keywords

AllophaneAmorphous ClayClimate ChangeCold ClimateOpalPalagonitePermafrostThermal ConductivityUnfrozen WaterVolcanic Ash
Type
Article
Information
Clays and Clay Minerals , Volume 65 , Issue 3 , June 2017 , pp. 168 - 183
Copyright
Copyright © Clay Minerals Society 2017

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Abramov, A. Gruber, S., and Gilichinsky, D., 2008 Mountain permafrost on active volcanoes: Field data and statistical mapping, Klyuchevskaya volcano group, Kamchatka, Russia Permafrost and Periglacial Processes 19 261277.CrossRefGoogle Scholar
Akagawa, S., and Fukuda, M., 1991 Frost heave mechanism in welded tuff Permafrost and Periglacial Processes 2 301309.CrossRefGoogle Scholar
Allen, C., and Conca, J.-L., 1991 Weathering of basaltic rocks under cold, arid conditions - Antarctica and Mars 1991 Lunar and Planetary Science Conference 711717.Google Scholar
Allen, C.C. Gooding, J.L. Jercinovic, M., and Keil, K., 1981 Altered basaltic glass: A terrestrial analog to the soil of Mars Icarus 45 347369.CrossRefGoogle Scholar
Andersland, O.B., and Ladanyi, B., 2004 Frozen Ground Engineering Hoboken, New Jersey, USA John Wiley & Sons.Google Scholar
Anderson, D. Tice, A.R., Hadas, A. Schwartzendruber, D. Rijtema, P.E. Fuchs, M., and Yaron, B., 1973 The unfrozen interfacial phase in frozen soil water systems Physical Aspects of Soil Water and Salts in Ecosystems Berlin Springer 107124.CrossRefGoogle Scholar
Anderson, D.M. Gaffney, E.S., and Low, P.F., 1967 Frost phenomena on Mars Science 155 319322.CrossRefGoogle ScholarPubMed
Anisimov, O.A. Shiklomanov, N.I., and Nelson, F.E., 1997 Global warming and active-layer thickness: Results from transient general circulation models Global and Planetary Change 15 6177.CrossRefGoogle Scholar
Antilén, M. Escudey, M. Förster, J.E. Moraga, N. Marty, D., and Fudym, O., 2003 Application of the hot disk method to the thermophysical characterization of soils Journal of the Chilean Chemical Society 48 2729.CrossRefGoogle Scholar
Arnalds, O., 2008 Soils of Iceland Jökull 58 409421.CrossRefGoogle Scholar
Arvidson, R.E. Anderson, R. Bartlett, P. Bell, J. Blaney, D. Christensen, P. Chu, P. Crumpler, L. Davis, K. Ehlmann, B.L. Fergason, R. Golombek, M.P. Gorevan, S. Grant, J.A. Greeley, R. Guinness, E.A. Haldemann, A.F.C. Herkenhoff, K. Johnson, J. Landis, G. Li, R. Lindemann, R. McSween, H. Ming, D.W. Myrick, T. Richter, L. Seelos IV, F.P. Squyres, S.W. Sullivan, R.J. Wang, A., and Wilson, J., 2004 Localization and physical properties experiments conducted by Spirit at Gusev Crater Science 305 821824.CrossRefGoogle ScholarPubMed
Ayris, P.M., and Delmelle, P., 2012 The immediate environmental effects of tephra emission Bulletin of Volcanology 74 19051936.CrossRefGoogle Scholar
Barton, I. Prata, A. Watterson, I., and Young, S., 1992 Identification of the Mount Hudson volcanic cloud over SE Australia Geophysical Research Letters 19 12111214.CrossRefGoogle Scholar
Bäumler, R., Phillips, M. Springman, S.M., and Arenson, L.U., 2003 Pedogenesis under permafrost and active volcanism in southern Kamchatka-new aspects about the last glaciation Permafrost Lisse, The Netherlands Swets & Zeitlinger 4954.Google Scholar
Bouyoucos, G., 1917 Classification and Measurement of the Different Forms of Water in the Soil by Means of the Dilatometer Method Michigan State University. Agricultural Experiment Station. Technical Bulletin 36. Bouyoucos G.1921Theamountofunfreewaterinsoilsatdifferentmoisurecontents.SoilScience 11, 255260.Google Scholar
Bovesecchi, G., and Coppa, P., 2013 Basic problems in thermal-conductivity measurements of soils International Journal of Thermophysics 34 19621974.CrossRefGoogle Scholar
Brailsford, A.D., and Major, K.G., 1964 The thermal conductivity of aggregates of several phases, including porous materials British Journal of Applied Physics 15 313.CrossRefGoogle Scholar
Braitseva, O. Melekestsev, I. Evteeva, I., and Lupikina, E., 1968 Stratigraphy of Quaternary Deposits and Glaciations of Kamchatka Moscow (in Russian) Akademia Nauk SSSR.Google Scholar
Braitseva, O. Sulerzhitsky, L. Litasova, S. Melekestsev, I., and Ponomareva, V., 1993 Radiocarbon dating and tephrochronology in Kamchatka Radiocarbon 35 463476.CrossRefGoogle Scholar
Braitseva, O.A. Ponomareva, V.V. Sulerzhitsky, L.D. Melekestsev, I.V., and Bailey, J., 1997 Holocene keymarker tephra layers in Kamchatka, Russia Quaternary Research 47 125139.CrossRefGoogle Scholar
Brock, B. Rivera, A. Casassa, G. Bown, F., and Acuñn, C., 2007 The surface energy balance of an active ice-covered volcano: Villarrica volcano, southern Chile Annals of Glaciology 45 104114.CrossRefGoogle Scholar
Carr, M.H., 2007 The Surface of Mars New York. Cambridge University Press.CrossRefGoogle Scholar
Chudnovsky, A., 1962 Thermal Properties of Disperse Materials Moscow Fizmatgiz.Google Scholar
Civan, F., 2000 Unfrozen water in freezing and thawing soils: Kinetics and correlation Journal of Cold Regions Engineering 14 146156.CrossRefGoogle Scholar
Clark, S.P., 1966 Handbook of Physical Constants Boulder, Colorado, USA. Geological Society of America.Google Scholar
Connor, C. Lichtner, P. Conway, F. Hill, B. Ovsyannikov, A. Federchenko, I. Doubik, Y. Shapar, V., and Taran, Y.A., 1997 Cooling of an igneous dike 20 yr after intrusion Geology 25 711714.2.3.CO;2>CrossRefGoogle Scholar
Demidov, N.E. Gilichinsky, D.A., Margesin, R., 2009 Terrestrial permafrost models and analogues of Martian habitats and inhabitants Permafrost Soils Berlin Springer 323341.CrossRefGoogle Scholar
Denton, G.H., and Karlén, W., 1977 Holocene glacial and treeline variations in the White River Valley and Skolai Pass, Alaska and Yukon Territory Quaternary Research 7 63111.CrossRefGoogle Scholar
Dixon, J.L. Chadwick, O.A., and Vitousek, P.M., 2016 Climate driven thresholds for chemical weathering in postglacial soils of New Zealand Journal of Geophysical Research: Earth Surface 121 16191634.CrossRefGoogle Scholar
Driedger, C., Lipman, P.W., and Mullineaux, D.R., 1981 Effect of ash thickness on snow ablation The 1980 Eruptions of Mount St. Helens, Washington 757760.Google Scholar
Dulnev, G., 1960 The theory of thermal regular regime and its application to the determination of thermal characteristics International Journal of Heat and Mass Transfer 1 152160.CrossRefGoogle Scholar
Ershov, D. Akimov, J. Cheverev, V., and Kuchuckov, E., 1978 Phase composition of water in frozen rocks Moscow (in Russian) Moscow State University.Google Scholar
Ershov, D., and Motenko, R., 2001 The influence of rock’s lithology and moisture content on the thickness of frozen soils Dynamic Geocryology 4 321325.Google Scholar
Etzelmüller, B. Farbrot, H. Guđmundsson, Humlum, O. Tveito, O.E., and Björnsson, H., 2007 The regional distribution of mountain permafrost in Iceland Permafrost and Periglacial Processes 18 185199.CrossRefGoogle Scholar
Farbrot, H. Etzelmüller, B. Schuler, T.V. Guđmundsson, Eiken, T. Humlum, O., and Björnsson, H., 2007 Thermal characteristics and impact of climate change on mountain permafrost in Iceland Journal of Geophysical Research: Earth Surface 112 F03S90.CrossRefGoogle Scholar
Farouki, O.T., 1981 Thermal Properties of Soils Hanover, New Hampshire, USA U.S. Army Corps of Engineers, Cold Regions Research and Engineering Laboratory..CrossRefGoogle Scholar
Farouki, O.T., 1981 The thermal properties of soils in cold regions Cold Regions Science and Technology 5 6775.CrossRefGoogle Scholar
French, H.M., 2013 The Periglacial Environment Hoboken, New Jersey, USA John Wiley & Sons.Google Scholar
Froese, D.G. Westgate, J.A. Reyes, A.V. Enkin, R.J., and Preece, S.J., 2008 Ancient permafrost and a future, warmer Arctic Science 321 16481648.CrossRefGoogle Scholar
Fukuo, Y., and Ariga, Y., 1967 Unfrozen Water Content of Artificially Frozen Soil Kyoto University, Japan Disaster Prevention Research Institute.Google Scholar
Geptner, A., and Ponomareva, V., 1979 Application of mineralogical analysis to correlate ashes of Shiveluch volcano Bulletin of Volcanological Station 56 l26130.Google Scholar
Gooding, J.L., and Keil, K., 1978 Alteration of glass as a possible source of clay minerals on Mars Geophysical Research Letters 5 727730.CrossRefGoogle Scholar
GOST25100-95., 1995 Soils. Classification Moscow State Standard 35.Google Scholar
Gow, A.J., and Williamson, T., 1971 Volcanic ash in the antarctic ice sheet and its possible climatic implications Earth and Planetary Science Letters 13 210218.CrossRefGoogle Scholar
Greuell, W., and Oerlemans, J., 1986 Sensitivity studies with a mass balance model including temperature profile calculations inside the glacier Zeitschrift für Gletscherkunde und Glazialgeologie 22 101124.Google Scholar
Gushchenko, I., 1965 Ashes From North Kamchatka and Conditions of Their Formation Moscow Nauka.Google Scholar
Henmi, T., and Wada, K., 1976 Morphology and composition of allophane American Mineralogist 61 379390.Google Scholar
Herrera, M. Lizcano, A. Santamarina, J., Phoon, K.K. Hight, D.W. Lerouell, S., and Tan, T.S., 2007 Colombian volcanic ash soils Characterization and Engineering Properties of Natural Soils Boca Raton, Florida, USA. Two Volume Set. Taylor & Francis 23852409.Google Scholar
Hinzman, L.D. Goering, D.J., and Kane, D.L., 1998 A distributed thermal model for calculating soil temperature profiles and depth of thaw in permafrost regions Journal of Geophysical Research: Atmospheres 103 2897528991.CrossRefGoogle Scholar
Hock, R., 2005 Glacier melt: A review of processes and their modelling Progress in Physical Geography 29 362391.CrossRefGoogle Scholar
Ivanov, A. Shoba, S., and Krasilnikov, P., 2014 A pedogeographical view of volcanic soils under cold humid conditions: The commander islands Geoderma 235 4858.CrossRefGoogle Scholar
Jaramillo, S.S. McCarthy, P.J. Trainor, T.P. Fowell, S.J., and Fiorillo, A.R., 2015 Origin of clay minerals in alluvial paleosols, prince creek formation, north slope, alaska, USA: Influence of volcanic ash on pedogenesis in the late cretaceous arctic Journal of Sedimentary Research 85 192208.CrossRefGoogle Scholar
Johansen, O., 1977 Thermal Conductivity of Soils Hanover, New Hampshire, USA U.S. Army Corps of Engineers, Cold Regions Research and Engineering Laboratory.CrossRefGoogle Scholar
Juen, M. Mayer, C. Lambrecht, A. Wirbel, A., and Kueppers, U., 2013 Thermal properties of a supraglacial debris layer with respect to lithology and grain size Geografiska Annaler: Series A PhysicalGeography 95, 197209.CrossRefGoogle Scholar
Karpachevskii, L. Alyabina, I. and Zakharikhina, L., 2009.Pochvy Kamchatki (Soils of Kamchatka)Google Scholar
Kasubuchi, T., 1975 The effect of soil moisture on thermal properties in some typical Japanese upland soils Soil Science and Plant Nutrition 21 107112.CrossRefGoogle Scholar
Kellerer-Pirklbauer, A. Farbrot, H., and Etzelmüller, B., 2007 Permafrost aggradation caused by tephra accumulation over snow covered surfaces: Examples from the Hekla 2000 eruption in Iceland Permafrost and Periglacial Processes 18 269284.CrossRefGoogle Scholar
Kersten, M.S., 1949 Thermal properties of soils Minneapolis Engineering Experiment Station, University of Minnesota.Google Scholar
Kirkbride, M.P., and Dugmore, A.J., 2003 Glaciological response to distal tephra fallout from the 1947 eruption of Hekla, South Iceland Journal of Glaciology 49 420428.CrossRefGoogle Scholar
Kiryanov, V., 1981 About the possibility of correlation of ash horizons in the Pleistocene deposits of the Central Kamchatka Depression Volcanology and Seismology 6 3038.Google Scholar
Kiryukhin, A. Polyakov, A.Y., and Mushinskii, A., 2013 Measurements of thermal conductivity and specific heat in volcanogenic rocks Journal of Volcanology and Seismology 8 283293.CrossRefGoogle Scholar
Kuprina, N., 1970 Stratigraphy and history of Pleistocene sedimentation in Central Kamchatka Moscow, Russia (in Russian) Nauka.Google Scholar
Kuznetsova, E., 2011 Thermal Properties and Phase Composition of Water in Frozen Volcanic Ash and Scoria (Kamchatka) Moscow, Russia Ph.D monograph. Moscow State University (MSU).Google Scholar
Kuznetsova, E. Motenko, R., Hinkel, K.M., 2012 Impact of mineral composition on heat-conducting properties of frozen volcanic ashes in Kamchatka Proceedings of 10th International Conference on Permafrost (TICOP 2012) 225230.Google Scholar
Kuznetsova, E., and Motenko, R., 2014 Weathering of volcanic ash in the cryogenic zone of Kamchatka, Eastern Russia Clay Minerals 49 195212.CrossRefGoogle Scholar
Kuznetsova, E. Danielsen, S. and Motenko, R., 2012.Features of thermal properties for frozen volcanic deposits In: Proceedings of the Canadian Geothechnical conference GeoManitoba, 2012Google Scholar
Kuznetsova, E. Motenko, R., and Danielsen, S.W., 2013 Thermal properties of volcanic ash and pumice Proceedings of the Mineral Deposit Research for a High-tech World 18061809.Google Scholar
Kuznetsova, E. Motenko, R. Vigasina, M., and Mel’chakova, L., 2011 The study of unfrozen water in volcanic ashes (Kamchatka) Moscow University Geology Bulletin 66 6571.CrossRefGoogle Scholar
Kyle, P.R. Ponomareva, V.V., and Rourke Schluep, R., 2011 Geochemical characterization of marker tephra layers from major Holocene eruptions, Kamchatka Peninsula, Russia International Geology Review 53 10591097.CrossRefGoogle Scholar
Langmann, B., 2014.On the role of climate forcing by volcanic sulphate and volcanic ash Advances in MeteorologyCrossRefGoogle Scholar
Liaudat, D.T. Penas, P., and Aloy, G., 2014 Impact of volcanic processes on the cryospheric system of the Peteroa Volcano, Andes of Southern Mendoza, Argentina Geomorphology 208 7487.CrossRefGoogle Scholar
Low, P.F. Anderson, D.M. and Hoekstra, P., 1968a Some thermodynamic relationships for soils at or below the freezing point: 1 Freezing point depression and heat capacity. Water Resources Research 4 379394.Google Scholar
Low, P.F. Hoekstra, P. and Anderson, D.M., 1968b Some thermodynamic relationships for soils at or below the freezing point: 2 Effects of temperature and pressure on unfrozen soil water. Water Resources Research 4 541544.Google Scholar
Lowe, D.J., Lowe, D.J. Neall, V.E. Hedley, M. Clothier, B., and Mackay, A., 2010 Quaternary volcanism, tephras, and tephraderived soils in New Zealand: An introductory review Guidebook for Pre-conference North Island, New Zealand’ Volcanoes to Oceans’ field tour (27-30 July) Palmerston North, New Zealand. 19th World Soils Congress, International Union of Soil Sciences, Brisbane. Soil and Earth Sciences Occasional Publications No. 3, Massey University 729.Google Scholar
Lowe, D.J., 2011 Tephrochronology and its application: A review Quaternary Geochronology 6 107153.CrossRefGoogle Scholar
Lunardini, V.J., 1981 Heat Transfer in Cold Climates New York Van Nostrand Reinhold Company.Google Scholar
Maeda, T. Takenaka, H., and Warkentin, B., 1977 Physical properties of allophane soils Advances in Agronomy 29 229264.CrossRefGoogle Scholar
Major, J.J., and Newhall, C.G., 1989 Snow and ice perturbation during historical volcanic eruptions and the formation of lahars and floods Bulletin of Volcanology 52 127.CrossRefGoogle Scholar
Manville, V. Hodgson, K. Houghton, B., and White, J., 2000 Tephra, snow and water: Complex sedimentary responses at an active snow-capped stratovolcano, Ruapehu, New Zealand Bulletin of Volcanology 62 278293.CrossRefGoogle Scholar
Marchant, D.R., and Denton, G.H., 1996 Miocene and Pliocene paleoclimate of the dry valleys region, Southern Victoria Land: A geomorphological approach Marine Micropaleontology 27 253271.CrossRefGoogle Scholar
Marchant, D.R. Denton, G.H. Swisher, C.C., and Potter, N., 1996 Late Cenozoic Antarctic paleoclimate reconstructed from volcanic ashes in the dry valleys region of Southern Victoria Land Geological Society of America Bulletin 108 181194.2.3.CO;2>CrossRefGoogle Scholar
Marchant, D.R. Swisher, C.C. Lux, D.R. West, D.P., and Denton, G.H., 1993 Pliocene paleoclimate and east Antarctic ice-sheet history from surficial ash deposits Science 260 667670.CrossRefGoogle Scholar
Markin, B.P., 1980 Prosadki v peplovykh tolshchakh Kamchatki (Subsidence in ash masses of Kamchatka) Engineering Geology 6175.Google Scholar
McCord, T.B. Clark, R.N., and Singer, R.B., 1982 Mars: Near infrared spectral reflectance of surface regions and compositional implications Journal of Geophysical Research: Solid Earth 87 30213032.CrossRefGoogle Scholar
Moore, P.L., 2014 Deformation of debris ice mixtures Reviews of Geophysics 52 435467.CrossRefGoogle Scholar
Motenko, R., and Kuznetsova, E., 2011 The role of ice content and unfrozen water in the heat conductivity assessment of volcanic ash (Kamchatka) Ice and Snow 114 99104.Google Scholar
Möller, R. Möller, M. Kukla, P., and Schneider, C., 2016 Impact of supraglacial deposits of tephra from Grímsvötn Volcano, Iceland, on glacier ablation Journal of Glaciology 62 933943.CrossRefGoogle Scholar
Nagasawa, K., 1978 Weathering of volcanic ash and other pyroclastic materials Developments in Sedimentology 26 105125.CrossRefGoogle Scholar
Nakano, Y., and Brown, J., 1971 Effect of a freezing zone of finite width on the thermal regime of soils Water Resources Research 7 12261233.CrossRefGoogle Scholar
Nanzyo, M., 2002 Unique properties of volcanic ash soils Global Environmental Research - English Edition 6 99112.Google Scholar
Nasedkin, V. Solovieva, T. Garaev, A. and Mager, A., 1987.Volcanic Slags and Pumices: Deposits and GenesisGoogle Scholar
Neall, V., 2006 Volcanic soils. Encyclopedia of Life Support Systems (EOLSS) Land use and land cover VII 124.Google Scholar
Nersesova, Z., and Tsytovich, N., 1963 Unfrozen water in frozen soils Proceedings of the Permafrost: Proceedings of 1st International Conference 1115.Google Scholar
Osterkamp, T., and Romanovsky, V., 1999 Evidence for warming and thawing of discontinuous permafrost in Alaska Permafrost and Periglacial Processes 10 1737.3.0.CO;2-4>CrossRefGoogle Scholar
Palacios, D. Zamorano, J. and Andrés, N., 2007.Permafrost distribution in tropical stratovolcanoes: Popocatépetl and Iztaccíhuatl volcanoes (Mexico) Proceedings of the Geophysical Research AbstractsGoogle Scholar
Parfitt, R., 1990 Allophane in New Zealand - A review Soil Research 28 343360.CrossRefGoogle Scholar
Parfitt, R. Russell, M., and Orbell, G., 1983 Weathering sequence of soils from volcanic ash involving allophane and halloysite, New Zealand Geoderma 29 4157.CrossRefGoogle Scholar
Parfitt, R.L., and Wilson, A., 1985 Estimation of allophane and halloysite in three sequences of volcanic soils, New Zealand Volcanic Soils. Catena Suppl 7 18.Google Scholar
Pellicciotti, F. Carenzo, M. Helbing, J. Rimkus, S., and Burlando, P., 2009 On the role of subsurface heat conduction in glacier energy-balance modelling Annals of Glaciology 50 1624.CrossRefGoogle Scholar
Ponomareva, V. Melekestsev, I. Braitseva, O. Churikova, T. Pevzner, M., and Sulerzhitsky, L., 2007 Late Pleistocene Holocene volcanism on the Kamchatka Peninsula, Northwest Pacific Region Volcanism and Subduction: The Kamchatka Region 165198.CrossRefGoogle Scholar
Reid, T.D., and Brock, B.W., 2010 An energy-balance model for debris-covered glaciers including heat conduction through the debris layer Journal of Glaciology 56 903916.CrossRefGoogle Scholar
Rengarten, N.V., and Kuprina, N.P., 1968 Some features of Pleistocene lithogenesis in the Central Kamchatka Depression Lithology and Mineral Resources 3 1724.Google Scholar
Richardson, J.M., and Brook, M.S., 2010 Ablation of debriscovered ice: Some effects of the 25 September 2007 Mt Ruapehu eruption Journal of the Royal Society of New Zealand 40 4555.CrossRefGoogle Scholar
Robinson, S., and Moore, T., 2000 The influence of permafrost and fire upon carbon accumulation in high boreal peatlands, Northwest Territories, Canada Arctic Antarctic and Alpine Research, 32, 155166.CrossRefGoogle Scholar
Schoeberl, M.R. Doiron, S.D. Lait, L.R. Newman, P.A. and Krueger, A.J., 1993 A simulation of the Cerro Hudson SO2 cloud Journal of Geophysical Research: Atmospheres 98 29492955.CrossRefGoogle Scholar
Shoba, S., and Ivanov, A., 2011 The characteristics of cold humid soil formation on the Commander Islands Moscow University Soil Science Bulletin 66 135143.CrossRefGoogle Scholar
Shoji, S. Dahlgren, R., and Nanzyo, M., 1993 Terminology, concepts and geographic distribution of volcanic ash soils Developments in Soil Science 21 15.CrossRefGoogle Scholar
Shoji, S., and Masui, J.-I., 1971 Opaline silica of recent volcanic ash soils in Japan Journal of Soil Science 22 101108.CrossRefGoogle Scholar
Sigfusson, B. Gislason, S.R., and Paton, G.I., 2008 Pedogenesis and weathering rates of a Histic Andosol in Iceland: Field and experimental soil solution study Geoderma 144 572592.CrossRefGoogle Scholar
Singer, R.B., 1982 Spectral evidence for the mineralogy of high albedo soils and dust on Mars Journal of Geophysical Research: Solid Earth 87 1015910168.CrossRefGoogle Scholar
Smith, C. Ping, C. Fox, C., and Kodama, H., 1999 Weathering characteristics of some soils formed in White River tephra, Yukon Territory, Canada Canadian Journal of Soil Science 79 603613.CrossRefGoogle Scholar
Smith, M.W., and Tice, A.R., 1988 Measurement of the unfrozen water content of soils: Comparison of NMR and TDR methods CRREL Report Springfield, Virginia, USA. Army Cold Regions Research and Engineering Laboratory. 88–18.Google Scholar
Squyres, S. Knoll, A. Arvidson, R. Clark, B. Grotzinger, J. Jolliff, B. McLennan, S. Tosca, N. Bell, J., and Calvin, W., 2006 Two years at Meridiani Planum: Results from the Opportunity rover Science 313 14031407.CrossRefGoogle ScholarPubMed
Stoops, G. Gérard, M. Arnalds, O., Kapur, S. Mermut, A., and Stoops, G., 2008 A micromorphological study of Andosol genesis in Iceland New Trends in Soil Micromorphology 6789.CrossRefGoogle Scholar
Theng, B. Russell, M. Churchman, G., and Parfitt, R., 1982 Surface properties of allophane, halloysite, and imogolite Clays and Clay Minerals 30 143149.CrossRefGoogle Scholar
Tice, A. Burrous, C., and Anderson, D., 1978 Determination of unfrozen water in frozen soil by pulsed nuclear magnetic resonance Proceedings of the Third International Conference on Permafrost 149155.Google Scholar
Tice, A.R. Anderson, D.M., and Sterrett, K.F., 1981 Unfrozen water contents of submarine permafrost determined by nuclear magnetic resonance Engineering Geology 18 135146.CrossRefGoogle Scholar
Trofimov, V. Korolev, V. Vasil’chuk, Y.K. Zingazurov, R., Trofimov, V.T., 2005 Indicators of the quantitative content of the liquid component in the soils Soil Science 135136.Google Scholar
Ugolini, F.C., and Dahlgren, R.A., 1991 Weathering environments and occurrence of imogolite/allophane in selected Andisols and Spodosols Soil Science Society of America Journal 55 11661171.CrossRefGoogle Scholar
van Rooyen, M., and Winterkorn, H.F., 1957 Theoretical and practical aspects of the thermal conductivity of soils and similar granular systems Highway Research Board Bulletin 168 143205.Google Scholar
Wada, K., 1987 Minerals formed and mineral formation from volcanic ash by weathering Chemical Geology 60 1728.CrossRefGoogle Scholar
Williams, P.J., 1964 Unfrozen water content of frozen soils and soil moisture suction Geotechnique 14 231246.CrossRefGoogle Scholar
Woodcock, A.H., 1974 Permafrost and climatology of a Hawaii volcano crater Arctic and Alpine Research 6 4962.CrossRefGoogle Scholar
Yershov, E.D. and Williams, P.J., 2004.General GeocryologyGoogle Scholar
Yoshikawa, K., and Overduin, P.P., 2005 Comparing unfrozen water content measurements of frozen soil using recently developed commercial sensors Cold Regions Science and Technology 42 250256.CrossRefGoogle Scholar
Yun, T.S., and Santamarina, J.C., 2005 Decementation, softening, and collapse: Changes in small-strain shear stiffness in k0 loading Journal of Geotechnical and Geoenvironmental Engineering 131 350358.CrossRefGoogle Scholar
Zehetner, F. Miller, W., and West, L., 2003 Pedogenesis of volcanic ash soils in Andean Ecuador Soil Science Society of America Journal 67 17971809.CrossRefGoogle Scholar
Zehetner, F., and Miller, W.P., 2006 Erodibility and runoffinfiltration characteristics of volcanic ash soils along an altitudinal climosequence in the Ecuadorian Andes Catena 65 201213.CrossRefGoogle Scholar