Note: Intro -- Preface -- Acknowledgements -- Contents -- Contributors -- An Overview of Conservation Paleobiology -- 1 Defining and Establishing Conservation Paleobiologyas a Discipline -- 2 Data in Conservation Paleobiology -- 3 Looking Forward -- References -- Should Conservation Paleobiologists Save the World on Their Own Time? -- 1 Always Academicize? -- 2 To Advocate, or Not to Advocate -- 3 Speaking Honestly to Power -- 4 From Pure Scientist to Honest Broker -- 5 Keeping It Real -- 6 Overcoming the Fear Factor -- 7 Later Is Too Late -- References -- Conceptions of Long-Term Data Among Marine Conservation Biologists and What Conservation Paleobiologists Need to Know -- 1 What is "Long Term"? -- 2 Survey Implementation -- 3 Survey Responses and What They Mean for Conservation Paleobiologists -- Conservation Goals -- Long-Term Data -- Environmental Stressors -- Baselines -- Challenges -- 4 Takeaways for Conservation Paleobiologists -- 5 Moving Forward -- Appendix 1: Survey Questions -- Appendix 2: Survey Population Selection -- Appendix 3: Categorization of Responses -- References -- Effectively Connecting Conservation Paleobiological Research to Environmental Management: Examples from Greater Everglades' Restoration of Southwest Florida -- 1 Introduction -- 2 Defining the Problem -- 3 Ensuring Success as a Conservation Paleobiologist -- Developing Partnerships and Collaborative Teams -- Becoming or Engaging a Liaison -- Participate in "Management Collaboratives" -- Compose Technical Reports in Addition to Peer-Reviewed Journal Articles -- Present Your Findings to Stake Holder Groups -- Attend and Present at Environmental Science and Restoration Conferences -- Train our Students -- Reward Faculty for Conducting Community-Engaged Scholarship -- Promote and Reward Community Service for Work with Environmental Agencies and NGOs. , 4 Case Studies from Greater Everglades' Restoration -- Case Study 1: Water Management of the Caloosahatchee River -- Case Study 2: Picayune Strand Restoration Project -- 5 Conclusions -- References -- Using the Fossil Record to Establish a Baseline and Recommendations for Oyster Mitigation in the Mid-Atlantic U.S. -- 1 Introduction -- 2 Methods -- Pleistocene Localities -- Field and Museum Sampling -- Oyster Size and Abundance Data -- Reconstructing Paleotemperature and Salinity -- Modern and Colonial Data -- 3 Results -- Paleoenvironmental Reconstruction of Holland Point -- Paleotemperature -- Paleosalinity -- Shell Height -- Growth Rate -- 4 Discussion -- Comparing Pleistocene to Modern Oysters -- Environmental Controls on Oyster Size -- Human Factors Influencing Oyster Size -- Implications for Restoration -- A Role for Conservation Paleobiology -- 5 Conclusion -- References -- Coral Reefs in Crisis: The Reliability of Deep-Time Food Web Reconstructions as Analogs for the Present -- 1 Introduction -- Preserving the Past -- Endangered Coral Reefs -- 2 Fossilizing a Coral Reef -- Dietary Breadth -- Trophic Chains and Levels -- Modularity -- 3 Guild Structure and Diversity -- Identifying Guilds in a Food Web -- 4 Reconstructing the Community -- Diversity and Evenness -- Simulated Food Webs -- 5 Summary -- Appendix 1 -- Hypergeometric Variance -- Appendix 2 -- References -- Exploring the Species -Area Relationship Within a Paleontological Context, and the Implications for Modern Conservation Biology -- 1 Introduction -- 2 Geological Setting -- 3 Methods -- 4 Results -- 5 Discussion -- 6 Conclusion -- References -- Marine Refugia Past, Present, and Future: Lessons from Ancient Geologic Crises for Modern Marine Ecosystem Conservation -- 1 Introduction -- 2 Defining Refugium. , A Species Must Have a Range Contraction, Range Shift, or Migration in Order to Escape the Onset of Global Environmental Degradation That Would Otherwise Cause Extinction of That Species -- Range Shifts -- Habitat Shifts -- Isolated Geographic Refugia -- Life History Refugia -- Cryptic Refugia -- Harvest Refugia -- The Environmental Conditions of a Refugium Are Sufficiently Habitable Such That the Species' Population Remains Viable During Its Time in the Refugium -- A Species' Population Is Smaller in the Refugium Than Its Pre-environmental Perturbation Size -- The Species Remains in the Refugium for Many Generations -- After the Environmental Crisis Ends, the Species Recovers by Inhabiting Newly Re-opened Habitats, Either Through Population Expansion or Through Adaptive Radiation -- Otherwise, the Refugium Became a Trap -- 3 Identifying Ancient Refugia -- Fossil Data -- Phylogeographic Studies -- Species Distribution Models -- 4 Lessons from the Past for Identifying Future Refugia -- As the Marine Environment Continues to Change, Refugia May Need to Shift -- Refugial Size and Connectivity Can Enhance Survivorship, But Can Also Have Evolutionary Consequences -- Conditions Inside Refugia May Not Necessarily Remain Pristine, But Will Need to Be of Sufficiently Lower Magnitude of Total Stress to Maintain Viable Populations -- Beware the Refugial Trap -- 5 Future Directions for Investigating Ancient Refugia -- 6 Conclusions -- Appendix -- References -- Training Tomorrow's Conservation Paleobiologists -- 1 Business As Usual Is Not Enough -- 2 A Call to Action -- 3 Bridging the Gap -- Recommendation 1 -- Recommendation 2 -- Recommendation 3 -- Recommendation 4 -- Recommendation 5 -- Recommendation 6 -- 4 Okay, But… -- 5 In the Meantime… -- 6 A Bright Future -- References -- A Conceptual Map of Conservation Paleobiology: Visualizinga Discipline. , 1 Determining the Current State and Structure of Conservation Paleobiology -- 2 Mapping a Discipline -- Bibliographic Co-Authorship Visualizations -- Text Co-Occurrence Visualizations -- Bibliographic Co-Citation Visualizations -- Bibliographic Coupling Visualizations -- 3 Bibliometric Networks -- Bibliographic Co-Authorship Networks -- Text Co-Occurrence Networks -- Bibliographic Co-Citation Networks -- Bibliometric Coupling Networks -- 4 The Intellectual Landscape -- 5 Emerging Frontiers -- 6 Conclusions -- References -- Index.