[ 21 ] Edmonsond, S., Dyer, B., 2026. Timing and magnitude of the Lomagundi-Jatuli carbon isotope excursion. Proceedings of the National Academy of Sciences, 123 (2) e2512767123.
[ 20 ] van Wieren, C. S., Dyer, B., Husson, J. M., 2026. Correlative isotope excursions driven by transport, not global environmental change. Earth and Planetary Science Letters, 673, p. 119745.
[ 19 ] Edmonsond, S., Dyer, B., 2025. A Bayesian framework for inferring regional and global change from stratigraphic proxy records (StratMC v1. 0). Geoscientific Model Development, 18, 15, p. 4759-4788.
[ 18 ] Jasper, C.E., Dyer, B., Reilly, B.T., Williams, T., Hemming, S., Raymo, M.E., 2024. A 3.3-million-year record of Antarctic iceberg rafted debris and ice sheet evolution quantified by machine learning. Paleoceanography and Paleoclimatology, 39, e2024PA004897.
[ 17 ] van Wieren, C., Husson, J.M., Dyer, B., 2024. Chemostratigraphy of the Ediacaran Old Fort Point Formation in the southern Canadian Cordillera. Precambrian Research. 411.
[ 16 ] Edmonsond, S., Nadeau, M.D., Turner, A.C., Wu, Z., Geyman, E.C., Ahm, A.C., Dyer, B., Oleynik, S., McGee, D., Stolper, D.A., Higgins, J.A., Maloof, A.C, 2025. Shallow carbonate geochemistry in the Bahamas since the last interglacial period. Earth and Planetary Science Letters, 627, p. 118566.
[ 15 ] Richards, F. D., Coulson, S. L., Hoggard, M. J., Austermann, J., Dyer, B., Mitro- vica, J. X., 2023. Geodynamically corrected Pliocene shoreline elevations in Australia consistent with midrange projections of Antarctic ice loss. Science Advances, 9(46), eadg3035.
[ 14 ] Dumitru, O. A., Dyer, B., Austermann, J., Sandstrom, M. R., Goldstein, S. L., D'Andrea, W. J., Cashman, M., Creel, R., Bolge, L., Raymo, M. E., 2023. Last interglacial global mean sea level from high-precision U-series ages of Bahamian fossil coral reefs. Quaternary Science Reviews, 318, p. 108287.
[ 13 ] Barnett, R. L., Austermann, J., Dyer, B., Telfer, M. W., Barlow, N. L., Boulton, S. J., Carr, A.S., Creel, R. C. Constraining the contribution of the Antarctic Ice Sheet to Last Interglacial sea level. Science Advances, 9(27), eadf0198.
[ 12 ] Geyman, E.C., Wu, Z., Nadeau M.D., *Edmonsond, S., Turner, A.C., Purkis, S., Howes, B., Dyer, B., Ahm, A.C., Yao, N., Deutsch, C., Higgins, J.A., Stolper, D.A., Maloof, A.C., 2022. The origin of carbonate mud and implications for global climate. Proceedings of the National Academy of Sciences, 119 (43), e2210617119.
[ 11 ] Tawil-Morsink K., Austermann J., Dyer B., Dumitru O.A., Precht W.F., Cashman M., Goldstein S.L., Raymo M.E., 2022. Probabilistic investigation of global mean sea level during MIS 5a based on observations from Cave Hill, Barbados. Quaternary Science Reviews, 295, p.107783.
[ 10 ] Creel, R.C., Austermann, J., Khan, N.S., D'Andrea, W.J., Balascio, N., Dyer, B., Ashe, E. and Menke, W., 2022. Postglacial relative sea level change in Norway. Quaternary Science Reviews, 282, p.107422.
[ 9 ] Dyer, B. , Austermann, J., D'Andrea, W.J., Creel, R.C., W.J., Sandstrom, M.R., Cashman, M., Rovere, A., Raymo, M.E., 2021. Sea level trends across the Bahamas constrain peak Last Interglacial ice melt. Proceedings of the National Academy of Sciences, Aug 2021, 118 (33); DOI: 10.1073/pnas.2026839118.
[ 8 ] Geyman, E. C., Maloof, A. C., Dyer, B. 2021. How is sea level change encoded in carbonate stratigraphy? Earth and Planetary Science Letters, 560, 11670.
[ 7 ] Dyer, B., Maloof, A.C., Purkis, S.J., and Harris, P.M. 2018. Quantifying the Relationship Between Water Depth and Carbonate Facies, Sedimentary Geology, 373, 1-10.
[ 6 ] Rovere, A., Casella, E., Harris, D.L., Lorscheid, T., Nandasena, N.A.K., Dyer, B., Sandstrom, M.R., Stocchi, P., D'Andrea, W.J., Raymo, M.E. 2017. Giant boulders and Last Interglacial storm intensity in the North Atlantic, Proceedings of the National Academy of Sciences, 114(46), pp.12144 - 12149.
[ 5 ] Lee, C.T. A., Caves, J., Jiang, H., Cao, W., Lenardic, A., McKenzie, N.R., Shorttle, O., Yin, Q.Z., and Dyer, B. 2017. Deep mantle roots and continental emergence: implications for whole-Earth elemental cycling, long-term climate, and the Cambrian explosion. International Geology Review, 1-18.
[ 4 ] Dyer, B., Higgins, J.A., Maloof, A.C. 2016. A probabilistic analysis of meteorically altered δ-13C chemostratigraphy from Late Paleozoic Ice Age carbonate platforms, Geology, 45.2 (2017): 135-138.
[ 3 ] Dyer, B., Maloof, A.C., Higgins, J.A. 2015. Glacioeustasy, meteoric diagenesis, and the carbon cycle during the Middle Carboniferous, Geochemistry, Geophysics, Geosystems, 16, doi:10.1002/2015GC006002.
[ 2 ] Dyer, B., Maloof, A.C. 2015. Physical and chemical stratigraphy suggest small or absent glacioeustatic variation during formation of the Paradox Basin cyclothems, Earth and Planetary Science Letters, 419: 63-70
[ 1 ] Dyer, B., Lee, C. T. A., Leeman, W. P., Tice, M. 2011. Open-system behavior during pluton-wall-rock interaction as constrained from a study of endoskarns in the Sierra Nevada Batholith, California, J. Petrology 52 (10): 1987-2008.