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References
Branney MJ, Kokelaar P (1992) A reappraisal of ignimbrite emplacement: progressive aggradation and particulate to nonparticulate flow transitions during emplacement of high-grade ignimbrite. Bull Volcanol 54: 504–520
Carmichael ISE, Turner FJ, Verhoogen J (1974) Igneous petrology. McGraw-Hill: 739 pp
Fisher RV (1966) Mechanism of deposition from pyroclastic flows. Am J Sci 264: 350–363
Fisher RV, Orsi G, Ort M, Heiken G (1993) Mobility of a large-volume pyroclastic flow — emplacement of the Campanian Ignimbrite, Italy. J Volcanol Geotherm Res 56: 205–220
Henry CD, Price JG, Parker DF, Wolff JA (1989) Mid-Tertiary silicic alkalic magmatism of Trans-Pecos Texas: rheomorphic tuffs and extensive silicic lavas. In: Chapin CE, Zidek J (eds) Field excursions to volcanic terranes in the western United States, Vol I: Southern Rocky Mountains region. New Mexico Bur Mines Mineral Resources Mem 46: 231–274
Hillhouse, JW, Wells RE (1991) Magnetic fabric, flow directions, and source area of the Lower Miocene Peach Springs Tuff in Arizona, California, and Nevada. J Geophys Res 96: 12443–12460
Kamata H, Mimura K (1983) Flow directions inferred from imbrication in the Handa pyroclastic flow deposit in Japan. Bull Volcanol 46: 277–282
Leat PT, Schmincke H-U (1993) Large-scale rheomorphic deformation on detachment surfaces in Miocene peralkaline ignimbrite E, Gran Canaria. Bull Volcanol 55: 155–165
Lipman PW (1984) The roots of ash flow calderas in western North America: windows into the tops of granitic batholiths. J Geophys Res 89: 8801–8841
Manley CR (1992) Extended cooling and viscous flow of large, hot rhyolite lavas: implications of numerical modeling results. J Volcanol Geotherm Res 53: 27–46
Mimura K (1984) Imbrication, flow direction and possible source areas of the pumice-flow tuffs near Bend, Oregon, USA. J Volcanol Geotherm Res 21: 45–60
Pinkerton H, Stevenson RJ (1992) Methods of determining the rheological properties of magmas at sub-liquidus temperatures. J Volcanol Geotherm Res 53: 47–66
Rees AI (1968) The production of preferred orientation in a concentrated dispersion of elongated and flattened grains. J Geol 76: 457–465
Rusnak GA (1957) The orientation of sand grains under conditions of ‘unidirectional’ fluid flow 1. Theory and experiment. J Geol 65: 385–409
Turbeville BN (1992) Tephra fountaining, rheomorphism, and spatter flow during emplacement of the Pitigliano Tuffs, Latera caldera, Italy. J Volcanol Geotherm Res 53: 309–327
Wilson CJN (1985) The Taupo eruption, New Zealand. II The Taupo ignimbrite. Phil Trans R Soc London 314: 229–310
Wolff JA, Wright JV (1981) Rheomorphism of welded tuffs. J Volcanol Geotherm Res 10: 13–34
Wolff JA, Wright JV (1983) Agglutination of low-viscosity airfall tephra, and development of a thermal facies scheme for plinian deposits. EOS Trans Am Geophys Union 64: 895
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Wolff, J.A., Turbeville, B.N. Comment on ‘A reappraisal of ignimbrite emplacement: progressive aggradation and particulate to non-particulate flow transitions during emplacement of high-grade ignimbrite’ by MJ Branney and P Kokelaar . Bull Volcanol 56, 134–137 (1994). https://doi.org/10.1007/BF00304109
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DOI: https://doi.org/10.1007/BF00304109