TY - JOUR
T1 - Assimilation and fractional crystallization controlled by transport process of crustal melt
T2 - Implications from an alkali basalt-dacite suite from Rishiri Volcano, Japan
AU - Kuritani, Takeshi
AU - Kitagawa, Hiroshi
AU - Nakamura, Eizo
N1 - Funding Information:
We are grateful to Kazuhito Ozawa and Ryoji Tanaka for useful discussions throughout this study. We would like to express our thanks to Ian Campbell, Ross Kerr and Stewart Turner for valuable discussions, fruitful comments on this manuscript and encouragement. We thank J. Davidson and N. Green for constructive reviews and comments. R. Arculus is also thanked for editorial handling and encouragement. We thank all the members of the Pheasant Memorial Laboratory at ISEI for useful discussions. This work was supported by the Japanese Society for the Promotion of Science for Japan Junior Scientists (T.K.) and the program for the Center of Excellence for the 21st Century in Japan.
Copyright:
Copyright 2008 Elsevier B.V., All rights reserved.
PY - 2005/7
Y1 - 2005/7
N2 - Mechanisms of fractional crystallization with simultaneous crustal assimilation (AFC) are examined for the Kutsugata and Tanetomi lavas, an alkali basalt - dacite suite erupted sequentially from Rishiri Volcano, northern Japan. The major element variations within the suite can be explained by boundary layer fractionation; that is, mixing of a magma in the main part of the magma body with a fractionated interstitial melt transported from the mushy boundary layer at the floor. Systematic variations in SiO2 correlate with variations in the Pb, Sr and Ad isotopic compositions of the lavas. The geochemical variations of the lavas are explained by a constant and relatively low ratio of assimilated mass to crystallized mass ('r value'). In the magma chamber in which the Kutsugata and Tanetomi magmas evolved, a strong thermal gradient was present and it is suggested that the marginal part of the reservoir was completely solidified. The assimilant was transported by crack flow from the partially fused floor crust to the partially crystallized floor mush zone through fractures in the solidified margin, formed mainly thermal stresses resulting from cooling of the solidified margin and heating of the crust. The crustal melt was then mixed with the fractionated interstitial melt in the mushy zone, and the mixed melt was further transported by compositional convection to the main magma, causing its geochemical evolution to be characteristic of AFC. The volume flux of the assimilant from the crust to the magma chamber is suggested to have decreased progressively with time (proportional to t -1/2), and was about 3 × 10-2 m/year at t = 10 years and 1 × 10-2 m/year at t = 100 years. It has been commonly considered that the heat balance between magmas and the surrounding crust controls the coupling of assimilation and fractional crystallization processes (i.e. absolute value of r). However, it is inferred from this study that the ratio of assimilated mass to crystallized mass can be controlled bv the transport process of the assimilant from the crust to magma chambers.
AB - Mechanisms of fractional crystallization with simultaneous crustal assimilation (AFC) are examined for the Kutsugata and Tanetomi lavas, an alkali basalt - dacite suite erupted sequentially from Rishiri Volcano, northern Japan. The major element variations within the suite can be explained by boundary layer fractionation; that is, mixing of a magma in the main part of the magma body with a fractionated interstitial melt transported from the mushy boundary layer at the floor. Systematic variations in SiO2 correlate with variations in the Pb, Sr and Ad isotopic compositions of the lavas. The geochemical variations of the lavas are explained by a constant and relatively low ratio of assimilated mass to crystallized mass ('r value'). In the magma chamber in which the Kutsugata and Tanetomi magmas evolved, a strong thermal gradient was present and it is suggested that the marginal part of the reservoir was completely solidified. The assimilant was transported by crack flow from the partially fused floor crust to the partially crystallized floor mush zone through fractures in the solidified margin, formed mainly thermal stresses resulting from cooling of the solidified margin and heating of the crust. The crustal melt was then mixed with the fractionated interstitial melt in the mushy zone, and the mixed melt was further transported by compositional convection to the main magma, causing its geochemical evolution to be characteristic of AFC. The volume flux of the assimilant from the crust to the magma chamber is suggested to have decreased progressively with time (proportional to t -1/2), and was about 3 × 10-2 m/year at t = 10 years and 1 × 10-2 m/year at t = 100 years. It has been commonly considered that the heat balance between magmas and the surrounding crust controls the coupling of assimilation and fractional crystallization processes (i.e. absolute value of r). However, it is inferred from this study that the ratio of assimilated mass to crystallized mass can be controlled bv the transport process of the assimilant from the crust to magma chambers.
KW - Assimilation and fractional crystallization
KW - Magma chamber
KW - Mass balance model
KW - Melt transport
KW - Pb isotope
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U2 - 10.1093/petrology/egi021
DO - 10.1093/petrology/egi021
M3 - Article
AN - SCOPUS:21444436374
SN - 0022-3530
VL - 46
SP - 1421
EP - 1442
JO - Journal of Petrology
JF - Journal of Petrology
IS - 7
ER -