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Glaciological Literature

Published online by Cambridge University Press:  30 January 2017

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Copyright © International Glaciological Society 1954

This bi-annual list of glaciological literature aims to cover the scientific aspects of snow and ice in all parts of the world. Attention is drawn to the bibliographies in each number of the Polar Record (Cambridge), which aim to cover the significant work dealing with expeditions, research, equipment and conditions of living in the Polar regions. Both journals, however, deal with Polar literature having specific glaciological interest and with general matters of a practical nature such as snowcraft.

Readers will greatly assist the Editor by notifying him of their own, or any other, publication of glaciological interest.

References

Arakawa, K. Higuchi, K. Studies on the freezing of water. (I.) Journal of the Faculty of Science, Hokkaido University, Ser. 2, Vol. 4, No. 3, 1952, p. 20108. [Growth of stellar crystals from disc crystals.]Google Scholar
Auty, R. P. Cole, R. H. Dielectric properties of ice and solid D2O. Journal of Chemical Physics, Vol. 20, No. 8, 1952, p. 1309 –14. [Complex dielectric constants measured from melting point to –65° C. (H2O) and –35° C. (D2O).]Google Scholar
Avery, E. C. Grossweiner, L. I. Thermoluminescence of ice. Journal of Chemical Physics, Vol. 21, No. 2, 1953,. p. 37273. [Ice, irradiated with X-rays at –183° C., glows when subsequently warmed.]Google Scholar
Bader, H., and others. Preliminary investigations of some physical properties of snow, by Bader, H. Hansen, B. L. Joseph, J. A. Sandgren, M. A.. U.S. S[now,] I [ce and] P[ermafrost] R[esearch] E[stablishment]. Report 7, 1951, viii, 48 p. [+14 sheets diagrs.] [Mechanics of snow compaction; description of instruments for its investigation.]Google Scholar
Barrére, P. Équilibre glaciaire actuel et quaternaire dans louest des Pyrénées centrales. Revue Géographique des Pyrénées et du Sud-Ouest, Tome 24, Fasc. 2, 1953, p. 11634.Google Scholar
Berg, H. Temperaturmessungen in der schneenahen Luftschicht. Wetter und Leben, Jahrg. 5, Ht. 1/2, 1953, p. 3435. [Temperature of air layer above snow.]Google Scholar
Berger, C. Saffer, C. M. Jr. The existence of “beta” ice. Science, Vol. 118, No. 3070, 1953, p. 5222. [Seljakov’s report of rhombohedral ice formed by freezing supercooled water at ordinary pressure almost certainly fallacious.]Google Scholar
Biays, P. Les îles de glace arctiques. Annales de Géographie, 62 An., No. 333, 1953, p. 37780. [Form, origin, movement.]CrossRefGoogle Scholar
Bigg, E. K. The supercooling of water. Proceedings of the Physical Society of London, Series B, Vol. 66, No. 404, 1953, p. 68894. [Drops suspended at the interface of two insoluble liquids were used to find dependence of supercooling on volume and cooling rate.]Google Scholar
Blue, R. W. The librational heat capacity of ice and of heavy ice. Journal of Chemical Physics, Vol. 22, No. 2, 1954, p. 28083. [Heat capacity of ice can be split into translational and rotational parts by studying the difference in heavy ice.]CrossRefGoogle Scholar
Bossolasco, M. Sulla micrometeorologia del manto nevoso. Geofisica e Meteorologia, Vol. 2, No. 1/2, 1954, p. 12. [Micro-climate of the snow cover.]Google Scholar
Bout, P. Études de géomorphologie dynamique en Islande. Paris, Hermann, 1953 219 p. (Actualités scientifiques et industrielles, 1197. Expéditions Polaires Françaises [travaux], III.) [Includes chapters on soil polygons and periglacial erosion.]Google Scholar
Brunner, T. Einige Beobachtungen über das Haften von Eis an Oberflächen. Zeitschrift für angewandte Mathematik und Physik, Vol. 3, Fasc. 6, 1952, p. 46066. [Shear tests on adhesion of ice to clean and greased surfaces.]Google Scholar
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Capello, C. Gli apparati morenici di diversione. Bollettino del Comitato Glaciologico Italiano, 2 Ser., No. 3, 1952, p. 2544. [Effect of morainic obstructions on flow of the Macunaga and Miage glaciers.]Google Scholar
Chalmers, J. A. Electric charges from ice friction. Journal of Atmospheric and Terrestrial Physics, Vol. 2, No. 6, 1952, p. 33739. [Experiments showing that when ice is rubbed the large fragments carry a negative charge.]CrossRefGoogle Scholar
Cumming, W. A. The dielectric properties of ice and snow at 32 cm. Journal of Applied Physics, Vol. 23, No. 7, 1952, p. 76872. [Data of use in studying radar echoes from snow-covered terrain and snowstorms.]Google Scholar
Dessens, H. Sur la microstructure et la précipitation artificielle dun brouillard surfondu. Comptes Rendus Hebdomadaires des Séances de l’Académie des Sciences, Tome 235, No. 25, 1952, p. 167578. [Examination of a supercooled town fog with ultramicroscope showed presence of rare, asymmetric ice crystals.]Google Scholar
Diamond, M. Lowry, W. P. Correlation of density of new snow with 700 mb temperature. U.S. Snow, Ice and Permafrost Research Establishment. Research Paper 1, 1953, 3 p.Google Scholar
Dibner, V. D. Nekotoryye osobennosti zamerzaniya rek i ozer v zapolyarye [Some features of the freezing of rivers and lakes in the polar regions]. Priroda [Nature] (Moscow), 1953, No. 10, p. 11920. [Characteristics of new freshwater ice.]Google Scholar
Dreimanis, A. Studies of friction cracks along shores of Cirrus Lake and Kasakokwog Lake, Ontario. American, Journal of Science, Vol. 251, No. 11, 1953, p. 76983. [Friction cracks do not always dip in direction of ice flow.]Google Scholar
Epstein, S. Mayeda, T. Variation of O18 content of waters from natural sources. Geochimica et Cosmochimica Acta, Vol. 4, No. 5, 1953, p 21324. [Low O18:O16 ratios obtained from marine waters contaminated with melt water from ice fields.]Google Scholar
Finsterwalder, R. Die zahlenmässige Erfassung des Gletscherrückgangs an Ostalpengletschem. Zeitschrift für Gletscherkunde und Glazialgeologie, Bd. 2, Ht. 2, 1953, p. 189239. [Data on glacier retreat for eight glaciers in the Eastern Alps.]Google Scholar
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Friedrich, W. Die Ursachen der Lawinenkatastrophen im Jänner 1951. Anzeiger der Österreichischen Akademie der Wissenschaften. Mathematisch-naturwissenschaftliche Klasse, Jahrg. 88, Nr. 6, 1951, p. 11725. [Analysis of the causes of the Austrian avalanches, January 1951.]Google Scholar
Friedrich, W. Schneerollen. Wetter und Leben, Jahrg. 5, Ht. 1/2, 1953, p. 8283. [“Snow rollers.”)Google Scholar
Fuchs, Alfred. Die Scherfestigkeit von Schnee und Eis in Abhängigkeit von der Temperatur. Veröffentlichungen des Museum Ferdinandeum (Innsbruck), Bd. 26/29, Jahrg. 1946/49,[pub.] 1949, p. 10105. [Shear strength of snow and ice in relation to temperature.]Google Scholar
Fuchs, Alfred. Raümliche Abbildungen von Schneegefügen als Dauerpräparate. Zeitschrift für Gletscherkunde und Glazialgeologie, Bd. 2, Ht. 2, 1953, p. 299301. [New method of making permanent snow replicas.]Google Scholar
Fuchs, Alfred. Über eine Verbesserung des Rotations-Zerreissapparates für Schneeproben. Zeitschrift für Gletscherkunde und Glazialgeologie, Bd. 2, Ht. 2, 1953, p. 30203. [Improved “tearing” apparatus for testing strength of snow samples.]Google Scholar
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Garrigue, H. Observations sur les impuretés dans lair libre. Comptes Rendus Hebdomadaires des Séances de l’Académie des Sciences, Tome 236, No. 24, 1953, p. 2309 –11. [Radioactivity in snow probably of distant origin, e.g. atomic bombs; the dust and soot are of local origin.]Google Scholar
Gill, E. W. B. Electrification by freezing. British Journal of Applied Physics. Supplement No. 2, 1953, p. S16–S19. [Potentials of order 100 volts found when ice formed from dilute solutions. A theory is suggested.]Google Scholar
Gourley, Mary G. Crozier, W. D. Persistent residues from ice particles. Physical Review, Ser. 2, Vol. 92, No. 2, 1953, p. 526. [Ice particles formed and evaporated at –75° C. leave residue capable of nucleating further ice particles.]Google Scholar
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Haefeli, R. Kriechprobleme im Boden, Schnee und Eis. Wasser und Energiewirtschaft, 1954, Nr. 3, 19 p. [Problems of creep in soils, snow and ice; includes sections on creep in causing avalanches, apparent viscosity and extrusion flow in glaciers.]Google Scholar
Hast, N. Observations regarding resistant surface films of crystals. Arkiv for Fysik, Bd. 4, Ht. 6, 1952, p. 53539. [Ice from distilled water leaves surface film as a veil-like structure visible in electron microscope.]Google Scholar
Hawice, E. L. Bonacina, L. C. W. The Snow Survey of Great Britain. Quarterly Journal of the Royal Meteorological Society, Vol. 79, No. 339, 1953, p. 16871. [Correspondence on a review of the 1949–50 and 1950–51 Snow Survey, ibid., Vol. 78, together with reply by reviewer.]Google Scholar
Heaps, H. S. An analysis of downpunching. Transactions of the Royal Society of Canada, Third Ser., Vol. 47, Section 4, 1953, p. 1721. [Mathematical discussion of stress pattern in crust of the Earth due to surface load of an ice sheet.]Google Scholar
Heinsheimer, G. J. Schwund der Staubschichten in einem Gletscher; nach Beobachtungen am Glaciar Derecho in der Cordillera von San Juan (Argentinien). Zeitschrift für Gletscherkunde und Glazialgeologie, ***Bd. z, Ht. z, 1953, p. 18388. [Suggests mechanism by which one side of the glacier is dirt-laden, other side dirt-free.]Google Scholar
Helk, J. V. Dunbar, Moira. Ice islands: evidence from north Greenland. Arctic, Vol. 6, No. 4, 1953, p. 26371. [Photographs of only areas in north Greenland where ice of this nature is found.]Google Scholar
Heusser, C. J. Palynology of the Taku Glacier snow cover, Alaska, and its significance in the determination of glacier regimen. American Journal of Science, Vol. 252, No. 5, 1954, p. 291308. [Investigation of the pollen and spore stratigraphy of the glacier as a help in determining its regime.]Google Scholar
Heusser, C. J., and others. Geobotanical studies on the Taku Glacier anomaly, by Heusser, C. J. Schuster, R. L. Gilkey, A. K.. Geographical Review, Vol. 44, No. 2, 1954, p. 22439. [Botanical evidence on why this glacier is advancing.]Google Scholar
Higucm, K. A method for observation of falling snow particles. Journal of the Meteorological Society of Japan, Ser. 2, Vol. 32, No. 3, 1954, p. 1924. [Shadow photography of snow crystals to obtain shape, size and mass.]Google Scholar
Hoinkes, H. Wärmeumsatz und Ablation auf Alpengletschem. II. Hornkees (Zillertaler Alpen), September 1951. Geografiska Annaler, Arg. 35, Ht. 2, 1953, p. 11640. [Studies of ablation on alpine glaciers, 1950–51]Google Scholar
Hoinkes, H. Zur Frage der Schutzbänder auf den Gletscherzungen. Zeitschrift für Gletscherkunde und Glazialgeologie, Bd. 2, Ht. 2, 1953 p. 17784. [Suggests cause of non-sedimentary “dirt-bands” (ogives) to be as proposed by Tyndall.]Google Scholar
Hoinkes, H. Zur Mikrometeorologie der eisnahen Luftschicht. Wetter und Leben, Jahrg. 5, Ht. 1/2, 1953, p. 3334. [Micrometeorology of air layer above ice.]Google Scholar
Hoppe, G. Nägra iakttagelser vid isländska jöklar sommaren 1952. Ymer, Arg. 73, Ht. 4, 1953, p. 24165. [Observations of 12 of Vatnajökull’s lobes and tongues. Superficial moraines uncommon on Icelandic glaciers. English summary.]Google Scholar
Hoppe, G. Schytt, V. Some observations on fluted moraine surfaces. Geografiska Annaler, Arg. 35, Ht. 2, 1953, p. 10515. [Ground moraine surfaces recently exposed by retreating ice are often strikingly “fluted”, the ridges consisting of fine material.]Google Scholar
Howell, W. E. Some measurements of ablation, melting and solar absorption on a glacief in Peru. Transactions. American Geophysical Union, Vol. 34, No. 6, 1953, p. 88388.Google Scholar
Humbel, F., and others. Anisotropie der Dielektrizitätskonstante des Eises, von F. Humbel, F. Jona und P. Scherrer. Helvetica Physica Acta, Vol. 26, Fasc. 1, 1953, p. 1732. [Measurement of the dielectric constant of ice for various orientations of a single crystal at temperatures from –5° to –40° C.]Google Scholar
Imbert, B. Sondages séismiques en Terre Adélie: rapports scientifiques des Expéditions Polaires Françaises S. III. 2. Annales de Géophysique, Tome 9, No. 1, 1953, p. 8592. [Results of 4 series of observations made south of Port-Martin, Dec. 1951 and Jan. 1952.]Google Scholar
Itoo, K. Mass, size and cristallizing [sic] velocity of skeleton-shaped depth hoar. Papers in Meteorology and Geophysics (Tokyo), Vol.2, No. 2, 1951, p. 18990. [Description and growth of depth hoar.]Google Scholar
Itoo, K. Forms of ice crystals in the air: on small ice crystals (II). Papers in Meteorology and Geophysics (Tokyo), Vol. 3, No. 3, 1953, p. 20716.Google Scholar
Itoo, K. Size, mass and some other properties of ice crystals in the air: on small ice crystals (III). Papers in Meteorology and Geophysics (Tokyo), Vol. 3, No. 4, 1953, p. 297306.Google Scholar
Ivanov, K. YE Lavrov, V. V. Ob odnoy osobennosti mekhanizma plasticheskoy deformatsii lda [A peculiarity in the mechanism of plastic deformation of ice]. Zhurnal Tekhnicheskoy Fiziki [Journal of Technical Physics], Tom 20, Vyp. 2, 1950, p. 23031. [Plastic deformation curve of ice is stepped, like that of some metals. English translation by J. A. Bender, U.S. S[now,] I[ce and] P[ermafrost] R[esearch] Ejstablishment]. Translation 10.]Google Scholar
Ivanovskiy, A. D. Snegovoy rezhim tsentralnoy lesostepi [Snow regime in the central forest-steppe region]. Gidrotekhnika i Melioratsiya [Hydraulic Engineering and Reclamation] (Moscow), No. 12, 1952, p. 1322. [Effect of variation of relief and shelter-belts on snow fall, melting and runoff.]Google Scholar
Jaeger, F. Der Rückgang der Gletscher des Kilimandjaro. Zeitschrfft für Gletscherkunde und Glazialgeologie, Bd. 2, Ht. 2, 1953, p. 30611. [Retreat of Kilimanjaro glaciers.]Google Scholar
Jobert, N. Dispersion des ondes de Rayleigh en milieu hétérogène; application au névé du Groenland. Annales de Géophysique, Tome 9, Fasc. 1, 1953, p. 2832. [Theoretical study.]Google Scholar
Kampe, H. J. Aufm and others. The influence of temperature on the shape of ice crystals growing at water saturation, by Kampe, H. J. Aufm Weickmann, H. K. Kelly, J. J.. Journal of Meteorology, Vol. 8, No. 3, 1951, p. 16874. [Laboratory experiments on crystals formed at various temperatures.]Google Scholar
Kampe, H. J. Aufm and others. Remarks on “Electron-microscope study of snow-crystal nuclei”, by Kampe, H. J. Aufm Weickmann, H. K. Aufm Kedesdy, H. H.. Journal of Meteorology, Vol. 9, No. 5, 1952, p. 37475. [Criticism of paper by M. Kumai, ibid., Vol. 8, No. 3, 1951, p. 151–56, with reply by Kumai, ibid., p. 375–76.]Google Scholar
Kautsky, G. Eine von einem Gletscher gefurchte Moräne. Geologiska Föreningens i Stockholm Förhandlingar, Bd. 75, Ht. 4, 1953, p. 49092. [Moraine furrowed by glacier.]Google Scholar
Keller, J. B. Weitz, M. Reflection and transmission coefficients for waves entering or leaving an icefield . Communications on Pure and Applied Mathematics, Vol. 6, No. 3, 1953, P- 41517.: Equations for the reflection and transmission of water waves are derived.]Google Scholar
Klebelsberg, R. Von. Ergebnisse der Gletschermessungen des Österreichischen Alpenvereins in den Österreichischen Alpen 1951 und 5952. Zeitschrift für Gletscherkunde und Glazialgeologie, Bd. 2, Ht. 2, 1953, p. 33343. [Detailed account of glacier fluctuation in Austrian Alps.]Google Scholar
Klebelsberg, R. Von. Die Gletscher der Österreichischen Alpen 1952–53. Mittelungen des Österreichischen Alpenvereins, Jahrg. 9 (79), Ht. 1/2, 1954, p. 57. [55 of the principal Austrian glaciers in retreat in 1953, 2 in advance.]Google Scholar
Kramers, H. Stemerding, S. The sublimation of ice in vacuum. Applied Scientific Research, Vol. A3, No 1, 1951, p. 7382. [Results show gas kinetic accommodation is nearly unity from –40° to –60° C. and confirm theory.]Google Scholar
Kumai, M. Itagaki, K. Cinematographic study of ice crystal formation in water. Journal of the Faculty of Science, Hokkaidô University, Ser. 2, Vol. 4, No. 4, 1953, p. 23546. [Disc crystals are formed at higher temperature and grow more slowly than needle crystals.]Google Scholar
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