Energy equivalents of oxygen consumption in animal energetics.
about
Feet, heat and scallops: what is the cost of anthropogenic disturbance in bivalve aquaculture?Seasonal reproductive endothermy in tegu lizardsImproving consumption rate estimates by incorporating wild activity into a bioenergetics model.Contrasting physiological responses of two populations of the razor clam Tagelus dombeii with different histories of exposure to paralytic shellfish poisoning (PSP).Combined Effects of Temperature and Seston Concentration on the Physiological Energetics of the Manila Clam Ruditapes philippinarum.Speed and incline during thoroughbred horse racing: racehorse speed supports a metabolic power constraint to incline running but not to decline running.CO2-induced pH reduction increases physiological toxicity of nano-TiO2 in the mussel Mytilus coruscus.Metabolic costs of capital energy storage in a small-bodied ectothermGENETICS OF PHYSIOLOGICAL DIFFERENTIATION WITHIN THE MARINE MUSSEL GENUS MYTILUS.Spatiotemporal drivers of energy expenditure in a coastal marine fish.Towards an energetic landscape: broad-scale accelerometry in woodland caribou.Comparative metabolic rates of common western North Atlantic Ocean sciaenid fishes.Water temperature, body mass and fasting heat production of pacu (Piaractus mesopotamicus).Heatwaves diminish the survival of a subtidal gastropod through reduction in energy budget and depletion of energy reserves.Bioenergetics modeling of the annual consumption of zooplankton by pelagic fish feeding in the Northeast Atlantic.Behavior, metabolism and swimming physiology in juvenile Spinibarbus sinensis exposed to PFOS under different temperatures.L-Arginine but not L-glutamine likely increases exogenous carbohydrate oxidation during endurance exercise.The effect of diet, temperature and intermittent low oxygen on the metabolism of rainbow trout.Energy balance of juvenile Cyprinus carpio after a short-term exposure to sublethal water-borne cadmium.Synergistic Effects of Nano-ZnO and Low pH of Sea Water on the Physiological Energetics of the Thick Shell Mussel Mytilus coruscus.The interactive effects of temperature, trophic status, and the presence of an exotic clam on the performance of a native freshwater musselComparison of the physiological energetics betweenMytilus chilensis,Mytilus galloprovincialisand their hybrids, under laboratory conditionsEffect of starvation on the energy budget of two Asian horseshoe crab species: Tachypleus tridentatus and Carcinoscorpius rotundicauda (Chelicerata: Xiphosura)Long-term effects of altered pH and temperature on the feeding energetics of the Antarctic sea urchin,Sterechinus neumayeriPhysiological processes and gross energy budget of the submerged longline-cultured Pacific oyster Crassostrea gigas in a temperate bay of KoreaBioenergetics and Trophic Impacts of the Invasive Indo-Pacific LionfishPhysiological energetics of the estuarine crab Hemigrapsus crenulatus (Crustacea: Decapoda: Varunidae): responses to different salinity levelsRole of bacteria in decomposition of faecal pellets egested by the epiphyte-grazing gastropod Gibbula umbilicarisGrowth Rate Potential of Juvenile Sockeye Salmon in Warmer and Cooler Years on the Eastern Bering Sea ShelfDead tired: evaluating the physiological status and survival of neonatal reef sharks under stressEel fat stores are enough to reach the Sargasso
P2860
Q27334545-E438CA66-CBAB-4732-9792-54DDB6F2D23DQ29307324-DCCC35B5-F40F-4422-BD61-B9809DEB22A5Q30386036-B381205C-C9E2-417A-B86F-B3A031E5610DQ35230891-F428418D-9472-4588-A0F1-D5BD1AF74555Q35972376-ADD5EF7F-0FF5-40B6-9719-07CD5DA30F76Q36178761-3CD2515B-EEE4-489C-B046-0219605E25E7Q37561517-637BDEAD-B14E-411A-8A1E-77361DC14EF8Q37740300-B69836F2-29F4-4231-B8D0-6B3266E53AA2Q38751922-97D48E5F-C796-42AA-93B4-02EF7BBE4AF6Q38923480-CA96F458-B26E-49C2-B8A9-7EBEDCE582A2Q39125032-AC79E0C0-2671-47A5-A5A9-654AA3A232C5Q44006464-18150E41-0910-44BF-B2BD-CB577B7D987EQ46368411-30CA6F7B-DC2D-4774-9A6F-25C4DB7C50A1Q47139848-36203A1B-E581-4342-8589-B22C057B18A4Q47223929-F4130A8C-4D6C-47A8-9848-3104E7F02ACEQ49031682-1F401966-9FD8-4197-8404-D621775AB055Q50508592-6E7C2088-E3CD-4973-8CAB-F246F40EEE61Q50749719-27B1BA40-E872-4F83-9FA1-E24FEB78B79AQ51602555-3C523737-8941-4B6D-B0EB-C997486BAED4Q55429969-0B0877F5-AA8C-4D2E-A87A-AB82F97D56F0Q56330620-EBF60DEF-BE60-4E0D-98AE-92FA17F80F44Q56463073-94579A95-0345-47C4-8880-59A5D7E668BEQ56998087-EB1C4FE3-B8FD-43F7-B86C-243B9B319DDFQ57011863-EE1DC698-8548-41FD-83BF-EBB8229C9D64Q57214872-2475446A-2665-49F1-BAE8-F67171E56984Q57425127-41B9FD3A-B7D7-41EB-AEF6-0380EA30FFDBQ57947019-6DF67C25-B248-47AB-85D5-2C0411790891Q58002315-F713C701-6EB6-4239-8BE9-DB83FC9D18C3Q58648199-667AF54A-C698-42A5-91F3-A2B1FC137A6AQ58727625-FB282B33-00B4-4F10-BD22-3E0B070D4DDFQ59057982-3AE67833-2243-4567-B68A-8915F053C14B
P2860
Energy equivalents of oxygen consumption in animal energetics.
description
1975 nî lūn-bûn
@nan
1975年の論文
@ja
1975年学术文章
@wuu
1975年学术文章
@zh-cn
1975年学术文章
@zh-hans
1975年学术文章
@zh-my
1975年学术文章
@zh-sg
1975年學術文章
@yue
1975年學術文章
@zh
1975年學術文章
@zh-hant
name
Energy equivalents of oxygen consumption in animal energetics.
@en
Energy equivalents of oxygen consumption in animal energetics.
@nl
type
label
Energy equivalents of oxygen consumption in animal energetics.
@en
Energy equivalents of oxygen consumption in animal energetics.
@nl
prefLabel
Energy equivalents of oxygen consumption in animal energetics.
@en
Energy equivalents of oxygen consumption in animal energetics.
@nl
P356
P1433
P1476
Energy equivalents of oxygen consumption in animal energetics.
@en
P2093
J M Elliott
P2888
P304
P356
10.1007/BF00345305
P407
P577
1975-09-01T00:00:00Z