Insect eggs protected from high temperatures by limited homeothermy of plant leaves.
about
A scenario for the evolution of selective egg coloration: the roles of enemy-free space, camouflage, thermoregulation and pigment limitationPredicting organismal vulnerability to climate warming: roles of behaviour, physiology and adaptationMicroclimatic challenges in global change biology.Impact of hot events at different developmental stages of a moth: the closer to adult stage, the less reproductive output.Heat resistance throughout ontogeny: body size constrains thermal tolerance.Heat stress impedes development and lowers fecundity of the brown planthopper Nilaparvata lugens (Stål).Photorespiratory compensation: a driver for biological diversity.Insecticide Effect of Zeolites on the Tomato Leafminer Tuta absoluta (Lepidoptera: Gelechiidae).Carried over: Heat stress in the egg stage reduces subsequent performance in a butterfly.The energetic and carbon economic origins of leaf thermoregulation.Joint Effect of Solar UVB and Heat Stress on the Seasonal Change of Egg Hatching Success in the Herbivorous False Spider Mite (Acari: Tenuipalpidae).Effects of Self-Superparasitism and Temperature on Biological Traits of Two Neotropical Trichogramma (Hymenoptera: Trichogrammatidae) Species.Geographic divergence in upper thermal limits across insect life stages: does behavior matter?Protection via parasitism: Datura odors attract parasitoid flies, which inhibit Manduca larvae from feeding and growing but may not help plants.Effects of developmental change in body size on ectotherm body temperature and behavioral thermoregulation: caterpillars in a heat-stressed environment.Multiple generation effects of high temperature on the development and fecundity of Bemisia tabaci (Gennadius) (Hemiptera: Aleyrodidae) biotype B.Effects of temperature and drought on early life stages in three species of butterflies: Mortality of early life stages as a key determinant of vulnerability to climate change?Gradual plasticity alters population dynamics in variable environments: thermal acclimation in the green alga Chlamydomonas reinhartdii.The development of a foliar fungal pathogen does react to leaf temperature!Complex life cycles and the responses of insects to climate change.Trichogramma parasitoids alter the metabolic physiology of Manduca eggs.Do Aphids Alter Leaf Surface Temperature Patterns During Early Infestation?Structure is more important than physiology for estimating intracanopy distributions of leaf temperatures.Vulnerability of riparian ecosystems to elevated CO2 and climate change in arid and semiarid western North AmericaPerformance of Agasicles hygrophila (Coleoptera: Chrysomelidae), a biological control agent of invasive alligator weed, at low non-freezing temperaturesGeographic mosaics of phenology, host preference, adult size and microhabitat choice predict butterfly resilience to climate warmingWarming decreases thermal heterogeneity of leaf surfaces: implications for behavioural thermoregulation by arthropodsClimate uncertainty on leaf surfaces: the biophysics of leaf microclimates and their consequences for leaf-dwelling organisms
P2860
Q28603461-7ADC3D2E-F08B-4062-B988-34A421DCE50DQ28730012-E26C7AA5-52C3-412A-943F-00194101E203Q30627623-E1B70C99-9BB7-40D7-9F6D-D7FAA29E8080Q30956874-4A2A2A9C-E5F5-4CEF-A93D-5D67B1281F04Q31111945-269CA278-F7C9-42AA-99A9-BAC2AF62638EQ34448248-12E41ABB-E03D-4FB5-A76F-7F514ABCD034Q34710646-08E082F4-F242-480D-B53A-C8A51787D1BDQ37542773-73E569BF-6233-44EF-8329-55730F762338Q38369269-17F7D158-2F76-4DCB-9B93-BE4F7CA52C49Q39249585-3A7634C9-8A06-4718-A85E-B1BD9D04242BQ40600132-EE731678-80D1-4302-A39B-EBC5786374F2Q41991277-56765476-E4BF-4ED8-A2DA-190BBB104D59Q41993414-7678EB5A-F471-4DDB-9C4D-1A52E782FF17Q41996607-7D7686FC-5289-42ED-BB49-0C425259A2FDQ42000970-89012C6B-B688-46BB-8421-843AC1C1CD6DQ45964170-B89707FC-A2F6-4876-B058-1F881A9DA152Q47123159-0FB30B0C-81A1-4B93-847F-9564A0F23D06Q51158684-5372F791-8B96-46C1-B826-0E21A18AE221Q51538821-EF8E81C1-AB3C-4911-8E28-08E8628B2377Q51594154-D3CA5FC9-D55E-43C7-9460-E6A87857BD35Q52739453-C14C4737-EBD9-4CDE-8993-CAFB839F1F7BQ52879562-D0808405-CCAA-4378-889A-AED024DD8E7CQ55031413-B1C07747-C3DB-4F69-8FB3-A02572CD329BQ56094172-2EF0FA0D-19FC-4009-A1F4-EC2BC84465F1Q56552031-9AE6FACE-1D44-49E9-A4A6-E8E1AD714153Q57005935-986187D6-FF2D-4568-9ECD-A380F2D8ED48Q57246351-56D73B66-C261-419B-ABB6-020C5329B61CQ57246357-C00AEC40-6ECB-4FB0-8F54-34A117ED8FF4
P2860
Insect eggs protected from high temperatures by limited homeothermy of plant leaves.
description
2009 nî lūn-bûn
@nan
2009年の論文
@ja
2009年論文
@yue
2009年論文
@zh-hant
2009年論文
@zh-hk
2009年論文
@zh-mo
2009年論文
@zh-tw
2009年论文
@wuu
2009年论文
@zh
2009年论文
@zh-cn
name
Insect eggs protected from high temperatures by limited homeothermy of plant leaves.
@en
Insect eggs protected from high temperatures by limited homeothermy of plant leaves.
@nl
type
label
Insect eggs protected from high temperatures by limited homeothermy of plant leaves.
@en
Insect eggs protected from high temperatures by limited homeothermy of plant leaves.
@nl
prefLabel
Insect eggs protected from high temperatures by limited homeothermy of plant leaves.
@en
Insect eggs protected from high temperatures by limited homeothermy of plant leaves.
@nl
P2093
P356
P1476
Insect eggs protected from high temperatures by limited homeothermy of plant leaves.
@en
P2093
Goggy Davidowitz
H Arthur Woods
Kristen Potter
P304
P356
10.1242/JEB.033365
P577
2009-11-01T00:00:00Z