Morrongiello, JR, Thresher, RE & Smith, DC Aquatic biochronologies and climate change. Nat. Air conditioning Change 2849 (2012).
Pracheil, BM, Hogan, JD, Lyons, J. & McIntyre, PB Using hard-part microchemistry to advance the conservation and management of North American freshwater fishes. Peach 39451–465 (2014).
Starrs, D., Ebner, BC & Fulton, CJ All in the Ears: Unlocking Fish Biology and Spatial Ecology. Biol. Tower. 9186-105 (2016).
Limburg, KE Otolith strontium traces environmental history of American shad less than a year old Alosa sapidissima. Tue. School. Prog. Ser. 11925–35 (1995).
Kennedy, BP, Klaue, A., Blum, JD, Folt, CL & Nislow, KH Reconstructing fish life using Sr isotopes in otoliths. Can. J. Fish. Aquat. Science. 59925–929 (2002).
Hogan, JD, Blum, MJ, Gilliam, JF, Bickford, N. & McIntyre, PB Consequences of alternative dispersal strategies in a putatively amphidromous fish. Ecology 952397-2408 (2014).
Carlson, AK, Phelps, QE & Graeb, BDS From chemistry to conservation: using otoliths to advance recreational and commercial fisheries management. J. Fish Biol. 90505–527 (2017).
Campana, SE Chemistry and composition of fish otoliths: pathways, mechanisms and applications. Tue. School. Program. Ser. 188263–297 (1999).
Pracheil, BC et al. The sagittal otoliths of sturgeons and paddlefish (Acipenseridae) are composed of the calcium carbonate polymorphs vaterite and calcite. J. Fish Biol. 90549-558 (2017).
Pracheil, BM, George, R. & Chakoumakos, BC Importance of calcium carbonate crystal structure diversity in otoliths for microchemistry studies. Rev. Fish Biol. Fish. 29569-588 (2019).
Nehrke, G., Poigner, H., Wilhelms-Dick, D., Brey, T. & Abele, D. Coexistence of three polymorphs of calcium carbonate in the shell of the Antarctic clam Laternula elliptica. Geochemistry. Geophys. Geosyst. 13(5), 15. https://doi.org/10.1029/2011GC003996 (2012).
Wassenburg, JA et al. Determination of aragonite trace element distribution coefficients from calcite–aragonite speleothem transitions. Geochem. Cosmochim. Act 190347-367 (2016).
Tzeng, WN et al. Erroneous identification of eel migration history by Sr/Ca ratios of vaterite otoliths. Tue. School. Program. Ser. 348285-295 (2007).
Gauldie, RW Effects of temperature and vaterite replacement on metal ion chemistry in otoliths from Oncorhynchus tshawytscha. Can. J. Fish. Aquat. Science. 532015-2026 (1996).
Remer, T. et al. Rapid growth causes the abnormal formation of vaterite in the otoliths of farmed fish. J. Exp. Biol. 2202965-2969 (2017).
Coll-Lladó, C., Giebichenstein, J., Webb, PB & Bridges, CR Ocean acidification promotes otolith growth and calcite deposition in gilthead seabream (Sparus aura) larvae. Science. representing 88384 (2018).
Loeppky, AR et al. Influence of ontogenetic development, temperature and pCO2 on the polymorphic composition of calcium carbonate of otoliths in sturgeons. Science. representing 11(1), 1–10 (2021).
Melancon, S., Fryer, BJ, Ludsin, SA, Gagnon, JE, and Yang, Z. Effects of crystal structure on metal uptake by lake trout (Salvelinus namaycush) otoliths. Can. J. Fish. Aquat. Science. 622609-2619 (2005).
Veinott, GI, Porter, TR, and Nasdala, L. Use of Mg as an indicator of crystal structure and Sr as an indicator of marine growth in vaterite and aragonite otoliths of aquacultured rainbow trout . Trans. A m. Fish. Soc. 1381157-1165 (2009).
Loeppky, AR, Chakoumakos, BC, Pracheil, BM & Anderson, WG Otoliths from subadult lake sturgeon Acipenser fulvescens contain calcium carbonate polymorphs of aragonite and vaterite. J. Fish Biol. 94810–814 (2019).
Vignon, M. When the presence of a vateritic otolith has a morphological effect on its aragonitic partner: translateral compensation induces a bias in microecological patterns in a unilateral vateritic otolith. Can. J. Fish. Aquat. Science. 77285–294 (2020).
Clarke, AD, Telmer, KH & Mark Shrimpton, J. Elemental analysis of otoliths, fin rays, and scales: a comparison of bony structures to provide population and life history information for arctic grayling (arctic thymallus). School. Freshw. Fish 16354–361 (2007).
Campana, SE, Chouinard, GA, Hanson, JM, Frechet, A. & Brattey, J. Elementary otolith fingerprints as biological tracers of fish stocks. Fish. Res. 46343–357 (2000).
Gauldie, RW Continuous and discontinuous growth in the otolith of Macruronus novaezelandiae (Merlucciidae: Teleostei). J. Morphol. 216(3), 271-294 (1993).
Long, JM, Snow, RA, Pracheil, BM & Chakoumakos, BC Morphology and composition of otoliths from Goldeye (Hiodontidae; Hiodon alosoides). J. Morphol. 282(4), 511–519 (2021).
Chakoumakos, BC, Pracheil, BM, Koenigs, RP, Bruch, RM & Feygenson, M. Empirical testing of structural models of vaterite using neutron diffraction and thermal analysis. Science. representing 636799 (2016).
David, AW, Grimes, CB, and Isely, JJ Sagittal otoliths of Vaterite in hatchery-reared juvenile reddrums. Progress. Cult fish. 56(4), 301–303 (1994).
Tomás, J. & Geffen, AJ Morphometry and composition of aragonite and vaterite otoliths from deformed laboratory-reared juvenile herrings from two populations. J. Fish Biol. 63(6), 1383-1401 (2003).
Kamhi, SR On the structure of CaCO3 vaterite. Acta Crystallogr. A 16(8), 770–772 (1963).
Kartnaller, V., Ribeiro, EM, Venancio, F., Rosariob, F., and Cajaiba, J. Preferential sulfate incorporation into calcite polymorphs during calcium carbonate precipitation: an experimental approach. CristEngComm 202241-2244 (2018).
Paquette, J. & Reeder, RJ Relationship between surface structure, growth mechanism and trace element incorporation in calcite. Geochem. Cosmochim. Act 59(4), 735–749 (1995).
Hüssy, K. & Mosegaard, H. Otolith growth and accretion characteristics of Atlantic cod (Gadus morhua) modeled in a bioenergetic context. Can. J. Fish. Aquat. Science. 61(6), 1021-1031 (2004).
Fablet, R. et al. Shedding light on the biomineralization of fish otoliths through a bioenergetic approach. PLOS ONE 6(11), e27055 (2011).
Naslund, AW, Davis, BE, Hobbs, JA, Fangue, NA & Todgham, AE Warming, not CO2-acidified seawater, alters otolith development of juvenile Antarctic rockcod (Trematomus bernacchii). Biol Fleece. 44(9), 1917-1923 (2021).
Coll-Llado, C. et al. Pilot study to investigate the effect of long-term exposure to elevated pCO2 on adult cod (Gadus Morhua) otolith morphology and calcium carbonate deposition. Physiol fish. Biochemistry. 481879–1891 (2021).
Solner, C. et al. Control of crystal size and lattice formation by starmaker in otolith biomineralization. Science 302(5643), 282–286 (2003).
Rodriguez-Carvajal, J. FULLPROF: A program for Rietveld refinement and pattern matching analysis. In Powder Diffraction Satellite Meeting of the XV IUCr Congress (Vol.127) (1990).
Roisnel, T. & Rodríquez-Carvajal, J. WinPLOTR: A Windows tool for powder diffraction pattern analysis. Mater. Science. 378(1), 118–123 (2001).
Momma, K. & Izumi, F. VESTA: A three-dimensional visualization system for electronic and structural analysis. J.Appl. Crystallologist. 41(3), 653–658 (2008).
Slater, JC Atomic rays in crystals. J. Chem. Phys. 41(10), 3199-3205 (1964).