The Evolution of the Lunar Crust

[1] Alexander C.M.O.D., Bowden R., Fogel M.L., Howard K.T., Herd C.D.K., Nittler L.R., The provenances of asteroids, and their contributions to the volatile inventories of the terrestrial planets, Science, 337, pp. 721-723, (2012)

[2] Anand M., Taylor L.A., Floss C., Neal C.R., Terada K., Tanikawa S., Petrology and geochemistry of LaPaz Icefield 02205: A new unique low-Ti mare-basalt meteorite, Geochim Cosmochim Acta, 70, pp. 246-264, (2006)

[3] Arai T., Takeda H., Yamaguchi A., Ohtake M., A new model of lunar crust: Asymmetry in crustal composition and evolution, Earth, Planets and Space, 60, pp. 433-444, (2008)

[4] Arai T., Hawke B.R., Giguere T.A., Misawa K., Miyamoto M., Kojima H., Antarctic lunar meteoritesYamato-793169, Asuka-881757, MIL 05035, and MET 01210 (YAMM): Launch pairing and possible cryptomare origin, Geochim Cosmochim Acta, 74, pp. 2231-2248, (2010)

[5] Armytage R., Georg R., Williams H., Halliday A., Silicon isotopes in lunar rocks: Implications for the Moon’s formation and the early history of the Earth, Geochim Cosmochim Acta, 77, pp. 504-514, (2012)

[6] Arnold J., Glotch T., Lucey P., Song E., Thomas I., Bowles N., Greenhagen B., Constraints on olivine-rich rock types on the Moon as observed by Diviner and M³: Implications for the formation of the lunar crust, J Geophys Res: Planets, 121, pp. 1342-1361, (2016)

[7] Ashley J., Robinson M., Stopar J., Glotch T., Hawke B.R., van der Bogert C., Hiesinger H., Lawrence S., Jolliff B., Greenhagen B., The Lassell massif—A silicic lunar volcano, Icarus, 273, pp. 248-261, (2016)

[8] Aubaud C., Hauri E.H., Hirschmann M.M., Hydrogen partition coefficients between nominally anhydrous minerals and basaltic melts, Geophys Res Lett, 31, (2004)

[9] Baker D.R., The fidelity of melt inclusions as records of melt composition, Cont Min Petrol, 156, pp. 377-395, (2008)

[10] Baker D.M., Head J.W., Constraints on the depths of origin of peak rings on the Moon from Moon Mineralogy Mapper data, Icarus, 258, pp. 164-180, (2015)

[1] Alexander C.M.O.D., Bowden R., Fogel M.L., Howard K.T., Herd C.D.K., Nittler L.R., The provenances of asteroids, and their contributions to the volatile inventories of the terrestrial planets, Science, 337, pp. 721-723, (2012)

[2] Anand M., Taylor L.A., Floss C., Neal C.R., Terada K., Tanikawa S., Petrology and geochemistry of LaPaz Icefield 02205: A new unique low-Ti mare-basalt meteorite, Geochim Cosmochim Acta, 70, pp. 246-264, (2006)

[3] Arai T., Takeda H., Yamaguchi A., Ohtake M., A new model of lunar crust: Asymmetry in crustal composition and evolution, Earth, Planets and Space, 60, pp. 433-444, (2008)

[4] Arai T., Hawke B.R., Giguere T.A., Misawa K., Miyamoto M., Kojima H., Antarctic lunar meteoritesYamato-793169, Asuka-881757, MIL 05035, and MET 01210 (YAMM): Launch pairing and possible cryptomare origin, Geochim Cosmochim Acta, 74, pp. 2231-2248, (2010)

[5] Armytage R., Georg R., Williams H., Halliday A., Silicon isotopes in lunar rocks: Implications for the Moon’s formation and the early history of the Earth, Geochim Cosmochim Acta, 77, pp. 504-514, (2012)

[6] Arnold J., Glotch T., Lucey P., Song E., Thomas I., Bowles N., Greenhagen B., Constraints on olivine-rich rock types on the Moon as observed by Diviner and M³: Implications for the formation of the lunar crust, J Geophys Res: Planets, 121, pp. 1342-1361, (2016)

[7] Ashley J., Robinson M., Stopar J., Glotch T., Hawke B.R., van der Bogert C., Hiesinger H., Lawrence S., Jolliff B., Greenhagen B., The Lassell massif—A silicic lunar volcano, Icarus, 273, pp. 248-261, (2016)

[8] Aubaud C., Hauri E.H., Hirschmann M.M., Hydrogen partition coefficients between nominally anhydrous minerals and basaltic melts, Geophys Res Lett, 31, (2004)

[9] Baker D.R., The fidelity of melt inclusions as records of melt composition, Cont Min Petrol, 156, pp. 377-395, (2008)

[10] Baker D.M., Head J.W., Constraints on the depths of origin of peak rings on the Moon from Moon Mineralogy Mapper data, Icarus, 258, pp. 164-180, (2015)