Variability in recruitment of coral reef fishes: the importance of habitat at two spatial scales. Ecology. :2488–2504.. 1996.
Toward Establishing Patterns of Connectivity for Kelp Rockfish: Geographic Structure in Elemental Signatures in Larval Otoliths and a Review of Potential Proxies for Natal Signatures. of North Pacific Rockfishes: Ecological Genetics and Stock Structure. :22.. 2004.
Temporal and spatial scales of influence on nearshore fish settlement in the Southern California Bight. Bulletin of Marine Science. 86:355–385.. 2010.
Supplementary data to Caselle et al. 2010. Bulletin of Marine Science. 86:355–385.. 2010.
Recovery trajectories of kelp forest animals are rapid yet spatially variable across a network of temperate marine protected areas. Scientific reports. 5. 2015.
Natal trace-elemental signatures in the otoliths of an open-coast fish. Limnology and Oceanography. 50:1529–1542.. 2005.
Larval retention and recruitment in an island population of a coral-reef fish. Nature. 402:799–802.. 1999.
Larval accumulation and retention: implications for the design of marine reserves and essential habitat. Bulletin of Marine Science. 66:821–830.. 2000.
The interaction of retention, recruitment, and density-dependent mortality in the spatial placement of marine reserves. Gulf and Caribbean Research. 14:107–117.. 2003.
Geographic variation in natal and early larval trace-elemental signatures in the statoliths of the market squid Doryteuthis (formerly Loligo) opalescens. Marine Ecology Progress Series. 379:109–121.. 2009.
Current shifts and kin aggregation explain genetic patchiness in fish recruits. Ecology. 87:3082–3094.. 2006.
Consistent long-term spatial gradients in replenishment for an island population of a coral reef fish. Marine Ecology-Progress Series. 306. 2006.