Peer Reviewed Publications
*advised student
(22) Hu, F., Liu, S., Ducea, M.N., Zhang, W., Chapman, J.B., Fu, J., and Wang, M., 2018, Interaction Among Magmas from Various Sources and Crustal Melting Processes During Continental Collision: Insights from the Huayang Intrusive Complex of the South Qinling Belt, China: Journal of Petrology, v. 59, p. 735-770. [pdf]
(21) Chapman, J.B., *Dafov, M.N., Gehrels, G., Ducea, M.N., Valley, J.W., Ishida, A., 2018, Lithospheric architecture and tectonic evolution of the southwestern U.S. Cordillera: Constraints from zircon Hf and O isotopic data: Geologic Society of America Bulletin, doi: 10.1130/B31937.1 [pdf]
(20) Chapman, J.B., Robinson, A.C., Carrapa, B., Villarreal, D., Worthington, J., DeCelles, P.G., Kapp, P., Gadoev, M., Oimahmadaov, I., and Gehrels, G., 2018, Cretaceous shortening and exhumation in the South Pamir terrane: Lithosphere, doi: 10.1130/L691.1. [pdf]
(19) Chapman, J.B., *Scoggin, S., Kapp, P., Carrapa, B., Ducea, M.N., Worthington, J., Oimahmadov, I., Gadoev, M., 2018, Mesozoic to Cenozoic magmatic history of the Pamir: Earth and Planetary Science Letters, v. 482, p. 181-192. [pdf]
(18) Chapman, J.B., Kapp, P., 2017, Tibetan Magmatism Database, Geochemistry, Geophysics, Geosystems, doi: 10.1002/2017GC007217. [pdf]
(17) Hu , F., Ducea, M.N., Liu, S., and Chapman, J.B., 2017, Quantifying crustal thickness in continental collisional belts: global perspective and a geologic application: Scientific Reports, 7058. doi: 10.1038/s41598-017-07849-7. [pdf]
(16) Chapman, J.B., Carrapa, B.C., Ballato, P., DeCelles, P.G., Worthington, J., 2017, Oimahmadov, I., Gadoev, M., and Ketcham, R., 2017, Intracontinental subduction beneath the Pamir Mountains: Constraints from thermokinematic modeling of shortening in the Tajik fold-and-thrust belt: Geologic Society of American Bulletin, doi: 10.1130/B31730.1. [pdf]
(15) Worthington, J.R., Kapp, P., Minaev, V., Chapman, J.B., Mazdab, F.K., Ducea, M.N., Oimahmadov, I. and Gadoev, M., 2017, Birth, life, and demise of the Andean–syn‐collisional Gissar arc: Late Paleozoic tectono‐magmatic‐metamorphic evolution of the southwestern Tian Shan, Tajikistan: Tectonics, 10.1002/2016TC004285.
(14) Chapman, J.B., Ducea, M.N., Kapp, P., Gehrels, G.E., and DeCelles, P.G., 2017, Spatial and temporal radiogenic isotopic trends of magmatism in
Cordilleran orogens: Gondwana Research, v. 48, p. 189-204. [pdf]
(13) Chapman, J.B., Gehrels, G.E., Ducea, M.N., Giesler, N., Pullen, A., 2016, A new method for estimating parent rock trace element concentration from zircon: Chemical Geology, v. 439, p.59-70. [pdf]
(12) Profeta, L., Ducea, M.N., Chapman, J.B., Paterson, S.R., Henriquez-Gonzales, S.M., Kirsch, M., Petrescu, L., and DeCelles, P.G., 2015, Quantifying crustal thickness over time in magmatic arcs: Scientific Reports, v.5, article # 17786. [pdf]
(11) Chapman, J. B., Ducea, M. N., DeCelles, P. G., and Profeta, L., 2015, Tracking changes in crustal thickness during orogenic evolution with Sr/Y: An example from the North American Cordillera: Geology, v.43, p. 919-922. [pdf]
(10) Chapman, J.B., and DeCelles, P.G., 2015, Foreland Basin Stratigraphic Control on Thrust Belt Evolution: Geology, v.43, p. 579-582. [pdf]
(9) Chapman, J.B., Elliott, J., Doser, D.I., and Pavlis, T.L., 2014, Slip on the Suckling Hills splay fault during the 1964 Alaska earthquake: Tectonophysics, v.637, p.191-197. [pdf]
(8) Chapman, J.B., and McCarty, R.S., 2013, Detachment levels in the Marathon Fold and Thrust Belt, West Texas: Journal of Structural Geology, v. 49, p.23-34. [pdf]
(7) Pavlis, T.L., Chapman, J.B., Bruhn, R.L., Ridgway, K., Worthington, L.L., Gulick, S.P.S., and Spotila, J., 2012, Structure of the actively deforming fold-thrust belt of the St. Elias orogen with implications for glacial exhumation and three-dimensional tectonic processes: Geosphere, v.8, p.991-1019.
(6) Chapman, J.B., Pavlis, T.L., Bruhn, R.L., Worthington, L.L., Gulick, S.P.S., and Berger, A.L., 2012, Structural relationships in the eastern syntaxis of the St. Elias orogen, Alaska: Geosphere, v.8, p.105-126. [pdf]
(5) Chapman, J.B., Worthington, L.L., Pavlis, T.L., Bruhn, R.L., and Gulick, S.P.S., 2011, The Suckling Hills fault, Kayak Island zone, and accretion of the Yakutat microplate, Alaska: Tectonics, v.30. [pdf]
(4) Chapman, J.B., Haeussler, P.J., and Pavlis, T.L., 2009, Quaternary uplift history of Wingham Island, south-central Alaska: U.S. Geological Survey Professional Paper 1760-B, 13p. [pdf]
(3) Berger, A.L., Gulick, S.P.S., Spotila, J.A., Upton, P., Jaeger, J.M., Chapman, J.B., and McAleer, R.J., 2008, Quaternary tectonic response to intensified glacial erosion in an orogenic wedge: Nature Geoscience, v.1, p.793-799.
(2) Chapman, J.B., Pavlis, T.L., Gulick, S.P.S., Berger, A.L., Lowe, L., Spotila, J.A., and McCalpin, J., 2008, Neotectonics of the Yakutat collision; changes in deformation driven by mass redistribution: AGU Geophysical Monograph 179, p. 65-81. [pdf]
(1) Berger, A.L., Spotila, J.A., Chapman, J.B., Pavlis, T.L., Enkelmann, E., Ruppert, N. A., and Buscher, J.T., 2008, Architecture, kinematics, and exhumation of a convergent orogenic wedge; a thermochronological investigation of tectonic – climatic interactions within the central St. Elias orogen, Alaska: Earth and Planetary Science Letters, v.270, p.13-24.
(21) Chapman, J.B., *Dafov, M.N., Gehrels, G., Ducea, M.N., Valley, J.W., Ishida, A., 2018, Lithospheric architecture and tectonic evolution of the southwestern U.S. Cordillera: Constraints from zircon Hf and O isotopic data: Geologic Society of America Bulletin, doi: 10.1130/B31937.1 [pdf]
(20) Chapman, J.B., Robinson, A.C., Carrapa, B., Villarreal, D., Worthington, J., DeCelles, P.G., Kapp, P., Gadoev, M., Oimahmadaov, I., and Gehrels, G., 2018, Cretaceous shortening and exhumation in the South Pamir terrane: Lithosphere, doi: 10.1130/L691.1. [pdf]
(19) Chapman, J.B., *Scoggin, S., Kapp, P., Carrapa, B., Ducea, M.N., Worthington, J., Oimahmadov, I., Gadoev, M., 2018, Mesozoic to Cenozoic magmatic history of the Pamir: Earth and Planetary Science Letters, v. 482, p. 181-192. [pdf]
(18) Chapman, J.B., Kapp, P., 2017, Tibetan Magmatism Database, Geochemistry, Geophysics, Geosystems, doi: 10.1002/2017GC007217. [pdf]
(17) Hu , F., Ducea, M.N., Liu, S., and Chapman, J.B., 2017, Quantifying crustal thickness in continental collisional belts: global perspective and a geologic application: Scientific Reports, 7058. doi: 10.1038/s41598-017-07849-7. [pdf]
(16) Chapman, J.B., Carrapa, B.C., Ballato, P., DeCelles, P.G., Worthington, J., 2017, Oimahmadov, I., Gadoev, M., and Ketcham, R., 2017, Intracontinental subduction beneath the Pamir Mountains: Constraints from thermokinematic modeling of shortening in the Tajik fold-and-thrust belt: Geologic Society of American Bulletin, doi: 10.1130/B31730.1. [pdf]
(15) Worthington, J.R., Kapp, P., Minaev, V., Chapman, J.B., Mazdab, F.K., Ducea, M.N., Oimahmadov, I. and Gadoev, M., 2017, Birth, life, and demise of the Andean–syn‐collisional Gissar arc: Late Paleozoic tectono‐magmatic‐metamorphic evolution of the southwestern Tian Shan, Tajikistan: Tectonics, 10.1002/2016TC004285.
(14) Chapman, J.B., Ducea, M.N., Kapp, P., Gehrels, G.E., and DeCelles, P.G., 2017, Spatial and temporal radiogenic isotopic trends of magmatism in
Cordilleran orogens: Gondwana Research, v. 48, p. 189-204. [pdf]
(13) Chapman, J.B., Gehrels, G.E., Ducea, M.N., Giesler, N., Pullen, A., 2016, A new method for estimating parent rock trace element concentration from zircon: Chemical Geology, v. 439, p.59-70. [pdf]
(12) Profeta, L., Ducea, M.N., Chapman, J.B., Paterson, S.R., Henriquez-Gonzales, S.M., Kirsch, M., Petrescu, L., and DeCelles, P.G., 2015, Quantifying crustal thickness over time in magmatic arcs: Scientific Reports, v.5, article # 17786. [pdf]
(11) Chapman, J. B., Ducea, M. N., DeCelles, P. G., and Profeta, L., 2015, Tracking changes in crustal thickness during orogenic evolution with Sr/Y: An example from the North American Cordillera: Geology, v.43, p. 919-922. [pdf]
(10) Chapman, J.B., and DeCelles, P.G., 2015, Foreland Basin Stratigraphic Control on Thrust Belt Evolution: Geology, v.43, p. 579-582. [pdf]
(9) Chapman, J.B., Elliott, J., Doser, D.I., and Pavlis, T.L., 2014, Slip on the Suckling Hills splay fault during the 1964 Alaska earthquake: Tectonophysics, v.637, p.191-197. [pdf]
(8) Chapman, J.B., and McCarty, R.S., 2013, Detachment levels in the Marathon Fold and Thrust Belt, West Texas: Journal of Structural Geology, v. 49, p.23-34. [pdf]
(7) Pavlis, T.L., Chapman, J.B., Bruhn, R.L., Ridgway, K., Worthington, L.L., Gulick, S.P.S., and Spotila, J., 2012, Structure of the actively deforming fold-thrust belt of the St. Elias orogen with implications for glacial exhumation and three-dimensional tectonic processes: Geosphere, v.8, p.991-1019.
(6) Chapman, J.B., Pavlis, T.L., Bruhn, R.L., Worthington, L.L., Gulick, S.P.S., and Berger, A.L., 2012, Structural relationships in the eastern syntaxis of the St. Elias orogen, Alaska: Geosphere, v.8, p.105-126. [pdf]
(5) Chapman, J.B., Worthington, L.L., Pavlis, T.L., Bruhn, R.L., and Gulick, S.P.S., 2011, The Suckling Hills fault, Kayak Island zone, and accretion of the Yakutat microplate, Alaska: Tectonics, v.30. [pdf]
(4) Chapman, J.B., Haeussler, P.J., and Pavlis, T.L., 2009, Quaternary uplift history of Wingham Island, south-central Alaska: U.S. Geological Survey Professional Paper 1760-B, 13p. [pdf]
(3) Berger, A.L., Gulick, S.P.S., Spotila, J.A., Upton, P., Jaeger, J.M., Chapman, J.B., and McAleer, R.J., 2008, Quaternary tectonic response to intensified glacial erosion in an orogenic wedge: Nature Geoscience, v.1, p.793-799.
(2) Chapman, J.B., Pavlis, T.L., Gulick, S.P.S., Berger, A.L., Lowe, L., Spotila, J.A., and McCalpin, J., 2008, Neotectonics of the Yakutat collision; changes in deformation driven by mass redistribution: AGU Geophysical Monograph 179, p. 65-81. [pdf]
(1) Berger, A.L., Spotila, J.A., Chapman, J.B., Pavlis, T.L., Enkelmann, E., Ruppert, N. A., and Buscher, J.T., 2008, Architecture, kinematics, and exhumation of a convergent orogenic wedge; a thermochronological investigation of tectonic – climatic interactions within the central St. Elias orogen, Alaska: Earth and Planetary Science Letters, v.270, p.13-24.