Robert Konik, Neil Robinson, Alex Altland, Reinhold Egger, Niklas Gergs, Wei Li, Dirk Schuricht, Alexei Tsvelik, Andreas WeichselbaumĬ01.00012: Symmetry-protected exceptional rings in two-dimensional correlated systems Jorn W F Venderbos, Yichen Hu, Charles KaneĬ01.00010: Real-space recipes for interacting topological crystalline statesĬ01.00011: Non-Topological Majorana Zero Modes in Inhomogeneous Spin Ladders Hu Miao, Tiantian Zhang, Le Wang, Derek Meyers, Ayman Said, Yilin Wang, Youguo Shi, Hongming Weng, Zhong Fang, Mark DeanĬ01.00008: Berryogenesis: self-induced Berry flux and spontaneous non-equilibrium magnetismĬ01.00009: Higher angular momentum band inversions in two dimensions Geremia Massarelli, Bryce Wu, Arun ParamekantiĬ01.00007: Observation of Double Weyl Phonons in Parity-Breaking FeSi Mallika Randeria, Kartiek Agarwal, Benjamin Ezekiel Feldman, Hao Ding, Huiwen Ji, Robert Cava, Shivaji Sondhi, Siddharth A Parameswaran, Ali YazdaniĬ01.00005: Interesting behavior of magnetoresistance in single crystals of CeBiīrinda Kuthanazhi, Na Hyun Jo, Li Xiang, Yun Wu, Sergey Budko, Adam Kaminski, Paul CanfieldĬ01.00006: Orbital Edelstein effect from spontaneous symmetry breaking Patrick LaBarre, Lianyang Dong, Jennifer Trinh, Theo Siegrist, Arthur P RamirezĬ01.00002: Higher-Order Symmetry Enriched Topological PhasesĬiarán Hickey, Vatsal Dwivedi, Tim Eschmann, Simon TrebstĬ01.00003: Topological Phases of the Interacting SSH and Kitaev Models on the Bethe LatticeĬ01.00004: Interacting multi-channel topological boundary modes in a quantum Hall valley system Session Index Session C01: Electronic Correlations in Topological Materials Sponsoring Units: DCMPĬhair: Mark Dean, Brookhaven National LaboratoryĬ01.00001: Temperature Dependence of Charge Transport in an Undoped Weyl Semimetal – Y 2Ir 2O 7 The effects of climate change are, however, being compounded by a range of anthropogenic disturbances, which may undermine the capacity of coral reef organisms to acclimate and/or adapt to specific changes in environmental conditions.Please enable JavaScript in your browser. For coral reef fishes, current evidence indicates increasing seawater temperature will be a major determinant of future assemblages, through both habitat degradation and direct effects on physiology and behaviour.
Recent evidence of increases in coral bleaching thresholds, local genetic adaptation and inheritance of heat tolerance suggest that coral populations may have some capacity to respond to warming, although the extent to which these changes can keep pace with changing environmental conditions is unknown. Although there is considerable among-species variability in responses to increasing temperature and seawater chemistry, changing temperature regimes are likely to have the greatest influence on the structure of coral and fish assemblages, at least over short–medium timeframes. Here, we summarise recent advances in our understanding of the effects of climate change on scleractinian corals and reef fish. Sustained and ongoing increases in ocean temperatures and acidification are altering the structure and function of reefs globally.
Climate change is one of the greatest threats to the persistence of coral reefs.
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