Dormancy affects copepods in their anatomy, physiology, genetics, population biology, community ecology, evolution and local and geographic distribution . It is known from freeliving representatives of three copepod taxa, namely the Harpacticoida, Cyclopoida and Calanoida . Species showing dormancy occur in various realms and habitats, both freshwater and marine, being benthic, planktic or ice-dwelling . Depending on the taxon, dormancy occurs at various times of the year, prevailing in higher and temperate latitudes . Copepod dormancy is expressed in various ontogenetic stages, such as resting eggs, arrested larval development, juvenile and adult encystment, or arrested development of nonencysted copepodids or adults . Ecologically, dormancy is an energy saving trait, allowing the individual to bridge periods of environmental harshness . Adverse environmental conditions could be abiotic (e .g . desiccation, temperature, oxygen availability) or biotic in nature (e .g . food availability, predation) . Diapause s . str. i s initiated, maintained and terminated by triggering factors (e .g . photoperiod, temperature, chemical cues, population density/physiological factors) . The dormant state and emergence patterns directly affect reproduction, population dynamics, community composition, coexistence and distribution of copepods, as well as the phenology of their predators and living food items . Populations having dormancy, in most cases belong to and affect communities of two realms : the water column and the bottom . Dormant stages may provide means for dispersal as well as for staying in special localities . The variability of dormancy permits flexible and complex life histories. Dormancy is subjected to and on the other hand affects copepod evolution .
