ライフサイエンスコーパス: climate change

1 nd associated impacts on ozone depletion and climate change.

2 enhouse gas emission that exacerbates global climate change.

3 burst - false springs - which may shift with climate change.

4 construct operators able to flexibly predict climate change.

5 source of CO(2) emissions and contribute to climate change.

6 vulnerability of species in these regions to climate change.

7 ecies can occur and how they will respond to climate change.

8 tral tools for understanding past and future climate change.

9 enon predicted to increase in magnitude with climate change.

10 s in floral pigmentation linked to ozone and climate change.

11 e advantage of the existing attention toward climate change.

12 a low-cost, nature-based tool for mitigating climate change.

13 emissions and uptake will respond to ongoing climate change.

14 mer and less saline waters, both outcomes of climate change.

15 entrations, generating negative feedbacks to climate change.

16 dity, land degradation, and vulnerability to climate change.

17 institutions that will most need to adapt to climate change.

18 ng and are in turn substantially affected by climate change.

19 potentially substantial positive feedback to climate change.

20 ong five scenarios of future development and climate change.

21 the management of fish stocks in the face of climate change.

22 ct land-atmosphere interactions under future climate change.

23 on gymnosperm-dominated forests under future climate change.

24 rbon (SOC) stabilization and SOC response to climate change.

25 ina may have significant negative impacts on climate change.

26 habitat degradation and long-term forces of climate change.

27 for understanding species' vulnerability to climate change.

28 rease in both frequency and intensity due to climate change.

29 oil organic carbon (SOC) and mitigate global climate change.

30 rization of ecosystem responses to sustained climate change.

31 promote species range shifts in response to climate change.

32 ove our knowledge about forest resilience to climate change.

33 in the face of mounting stresses from global climate change.

34 hemistry and metal concentrations because of climate change.

35 seful to delay harvest to counter effects of climate change.

36 xisting and future MPA networks to continued climate change.

37 e are threatened by thermal stress caused by climate change.

38 nges, ranging from local fisheries to global climate change.

39 studying the response of organisms to rapid climate change.

40 mmunities on novel reef ecosystems shaped by climate change.

41 e mobility is crucial in dealing with global climate change.

42 hallenges the global community faces through climate change.

43 selected animals for enhanced resilience to climate change.

44 , impacted by fishing, and will decline with climate change.

45 er as they shift their ranges in response to climate change.

46 ressures, poor land management practices and climate change.

47 ances than animals but are more sensitive to climate change.

48 tial to obscure and distort the influence of climate change.

49 importance, especially in the face of global climate change.

50 spread of crop pests, agrochemical use, and climate change.

51 on shifts (i.e. biome shifts) in response to climate change.

52 des water and air quality and contributes to climate change.

53 rategy for geoengineering to mitigate global climate change.

54 ate and manage future range shifts driven by climate change.

55 e the responsiveness of arctic ecosystems to climate change.

56 r coastal wetlands under future scenarios of climate change.

57 s sites in community dynamics in response to climate change.

58 rucial interactions between nanoplastics and climate change.

59 rld are shifting their ranges in response to climate change.

60 rately predict tree mortality under on-going climate change.

61 stems are highly vulnerable to pollution and climate change.

62 ses generate a valuable negative feedback on climate change.

63 the vulnerability of groundwater aquifers to climate change.

64 nder pressure from resource exploitation and climate change(1,2).

65 n, attribution, prediction and projection of climate change(1-3).

66 n Greenland were associated with synchronous climate changes across the Asian Monsoon, South American

67 revealed that 82% of real-world examples of climate change adaptation in MPA planning derive from tr

68 and challenges of climate change mitigation, climate change adaptation, combatting land degradation a

69 ties) with high diversity in a key trait for climate change adaptation-phenology.

70 cur worldwide driven by altered land-use and climate change, affecting landscape function, biodiversi

71 tal hazards as declining sediment supply and climate change alter their sediment budget, affecting de

72 The Amazon Basin is experiencing climate change, altered hydrological cycles, and forest

73 ility is fundamental to predicting near-term climate change and changing extremes, and to attributing

74 m will be exacerbated by shortages caused by climate change and COVID-19's impact.

75 to be dynamic and shifting north because of climate change and ecologic competition from IFA.

76 s were exacerbated by drought, anthropogenic climate change and existing land-use management.

77 ogical and paleoecological evidence for past climate change and human response and argue that these c

78 es due to latitudinal range shifts driven by climate change and increased artificial light at night (

79 Climate change and increasing world population will dire

80 We found that the projected climate change and intensive land use decreased their to

81 re we test whether biodiversity responses to climate change and land-use change differ among biomes (

82 d study assessing the interactive effects of climate change and land-use intensification on body size

83 rsity to secure adequate financing, plan for climate change and make biodiversity conservation a far

84 is available to help separate the effects of climate change and other anthropogenic activities on car

85 rts to predict how consumers will respond to climate change and other environmental perturbations.

86 With climate change and other forms of environmental degradat

87 Climate change and population growth have increased dema

88 xplore their role in mitigating degradation, climate change and poverty.

89 eabirds on St Kilda, UK, have been linked to climate change and predation from great skuas Stercorari

90 f sudden and severe biodiversity losses from climate change and provide a framework for predicting bo

91 able potential to help mitigate human-caused climate change and provide society with many cobenefits.

92 e promise of mitigating the worst effects of climate change and providing a means to engineer crops f

93 wable energy production is necessary to halt climate change and reverse associated biodiversity losse

94 y complex interactions between landscape and climate change and species-specific sensitivities.

95 maladaptive in the context of anthropogenic climate change and that selection now promotes thermal c

96 wheat improvement to address challenges from climate change and the growing human population.

97 unlikely.(1-3) Eutrophication, overfishing, climate change, and disease have fueled the supremacy of

98 is expected to increase under anthropogenic climate change, and drought-induced mortality and commun

99 future states and functioning of trees under climate change, and has the potential to be incorporable

100 distributed globally, improve predictions of climate change, and mitigate effects.

101 ions (NO) lead to increased smog, acid rain, climate change, and respiratory inflammation within the

102 body size reduction is a general response to climate change, and reveal a similarly consistent and un

103 esponse of caribou reproductive phenology to climate change, and species-specific changes in terrestr

104 communities exhibit a range of responses to climate change, and that improving passage and fluvial c

105 as a result of declining natural resources, climate change, and the growing world population.

106 he most dramatic damage due to anthropogenic climate change, and the situation is predicted to worsen

107 at press releases opposing action to address climate change are about twice as likely to be cited in

108 large-scale crop growth and its responses to climate change are critical for yield estimation and pre

109 Predator loss and climate change are hallmarks of the Anthropocene yet the

110 Increasing temperatures associated with climate change are predicted to cause reductions in body

111 Land-use and climate change are significantly affecting stream ecosys

112 ng the widely held assumption that long-term climate changes are the primary drivers of biodiversity

113 ng the United States today, but they do view climate change as an important issue for the world today

114 tion policies and the relative importance of climate change as an issue.

115 rate species vulnerability assessments under climate change, as priorities for protecting, connecting

116 mpounding the ecophysiological risk posed by climate change, as the combined effects are more severe

117 These results suggest that future climate change at the Kerguelen Islands will further ass

118 ose that these communities were resilient to climate change because molluscs are better adapted to hi

119 se in many cases, thus tending to offset the climate change benefit from increased SOC storage.

120 Interlocked challenges of climate change, biodiversity loss, and land degradation

121 Rising atmospheric CO(2) is intensifying climate change but it is also driving global and particu

122 ed as a response to human influence, such as climate change, but could also be a non-negligible drive

123 resented in studies demonstrating effects of climate change, but depending on their thermal tolerance

124 nge are governed by ecosystem sensitivity to climate change, but ecosystem model projections are unde

125 and biomes to shift poleward and upward with climate change, but non-climatic factors complicate thes

126 environments may provide some refuge through climate change, but these reefs will need high conservat

127 l protection to Andean frog communities from climate change by enabling tracking of suitable climates

128 gle field of research that could help combat climate change by generating better heat pumps for both

129 y polarization in beliefs about human-caused climate change can threaten global cooperation agreement

130 Climate change can trigger shifts in community structure

131 Climate change causes changes in the timing of life cycl

132 As anthropogenic climate change continues the risks to biodiversity will

133 We describe how climate change could affect larval survival in rivers, g

134 For example, climate change could exacerbate the impacts of biologica

135 Climate change could increase species' extinction risk a

136 ver the long-term, evolutionary responses to climate change could potentially increase inter-annual v

137 lying that a change in forcing (e.g., due to climate change) could cause a delta to switch from predi

138 hypothesized to help or hinder adaptation to climate change depending on the circumstances.

139 In the context of climate change, determining the physiological mechanisms

140 rbate the impacts of biological invasions if climate change differentially affects invasive and nativ

141 titudes, with several displaying substantial climate change-driven intensification over the last cent

142 As climate change drives increased drought in many forested

143 lly be constrained, rather than promoted, by climate change due to decreases in their primary trophic

144 ees that is hypothesized to be vulnerable to climate change due to its correlation with variability i

145 eries of foliar PRI may provide insight into climate change effects on carbon cycling.

146 anticipate, manage, and potentially mitigate climate-change effects on ecosystems.

147 s considered were freshwater eutrophication, climate change, energy demand, land use, and dependency

148 actice, to promote their adaptation to a new climate-changing environment.

149 f each ecotype may be shifted due to ongoing climate change, especially in traits associated with wat

150 l conditions could increase vulnerability to climate change, even for geographically widespread speci

151 nly 5 out of 236 genes that responded to the climate change experiment.

152 echanistic insights into the consequences of climate change for Arctic herbivores, highlighting the p

153 udies have not addressed the consequences of climate change for the metabolism of these organisms in

154 Given the prospect of ongoing climate change for the next several decades to centuries

155 With climate change forecasted to increase SSTs and the frequ

156 If these processes continue during modern climate change, future loss of summer Arctic sea ice wil

157 e controls plant growth and development, and climate change has already altered the phenology of wild

158 Recent studies show that although climate change has an impact on the carbon fluxes of the

159 y in understanding biodiversity responses to climate change has been hampered by substantial variatio

160 Climate change has intensified the hydrologic cycle glob

161 As climate change has reduced precipitation and increased t

162 Rapid climate change has wide-ranging implications for the Arc

163 Changes in plant phenology associated with climate change have been observed globally.

164 While humans and climate change have been proposed as potential causes of

165 sh abundance and distribution in response to climate change have been simulated using both statistica

166 transportation demand while urbanization and climate change have intensified urban floods.

167 wth and the uncertain hazards that accompany climate change have put increasing pressure on the manag

168 Longer term responses to climate change, however, may include individual plastici

169 tinction due to human land use, hunting, and climate change; (ii) loss of megabiota has a negative im

170 bal vegetation models is vital for assessing climate change impacts on the forest carbon stock.

171 heric and oceanic transport, and forecasting climate change impacts through modeling.

172 Understanding how climate change impacts trailing-edge populations require

173 system-is a set of technologies for reducing climate-change impacts and risks.

174 Our findings point to adaptation to climate change in agriculture and reveal diverse implica

175 plastics will affect species in concert with climate change in freshwater ecosystems.

176 elevation, as well as microbial responses to climate change in montane ecosystems.

177 Climate change in the Arctic is occurring rapidly, and p

178 es are cited in all articles published about climate change in The New York Times, The Wall Street Jo

179 on data also suggest an accelerating role of climate change in the range expansion of M. soledadinus,

180 hifting of cultivars to adapt agriculture to climate change-including in major winegrowing regions-as

181 We find that anthropogenic climate change increased the likelihood of the 2015-2017

182 to multiple factors including habitat loss, climate change, increased vulnerability to disease and p

183 Through NBP, climate change increases SCA at MLO before the 1980s and

184 As climate change increases the probability and intensity o

185 The urgency to address global climate change induced by greenhouse gas emissions is in

186 As climate change-induced droughts intensify, tall trees wi

187 Climate change-induced extinctions are estimated to elim

188 We review how climate change influences physiology, behavior, and demo

189 current understanding of, and evidence for, climate (change) influences on migration still remains r

190 for 21st-century Intergovernmental Panel on Climate Change (IPCC) projections that suggest SA will e

191 dicting how organisms will respond to future climate change is a challenging task for biologists.

192 Climate change is altering the intensity and variability

193 Climate change is an impressive factor with effects on c

194 Climate change is drastically changing the timing of bio

195 Climate change is expected to accelerate the microbial d

196 Climate change is expected to affect crop production wor

197 sk [10-12], so understanding its response to climate change is important.

198 Climate change is increasing global temperatures and int

199 Climate change is leading to widespread elevational shif

200 On average, our participants think that climate change is not the most important problem facing

201 Climate change is predicted to result in warmer and drie

202 Ongoing climate change is predicted to trigger major shifts in t

203 Climate change is reshaping global biodiversity as speci

204 One of the most robust signals of climate change is the relentless rise in global mean sur

205 n artefacts may become further endangered if climate change leads to more favorable growth conditions

206 ncertain how the global processes of WPE and climate change may combine to impact water availability

207 antic, OMZ expansion in the course of global climate change may detrimentally impact taxa that avoid

208 uced species are one mechanism through which climate change may exacerbate negative impacts of biolog

209 rstanding how species have responded to past climate change may help refine projections of how specie

210 providing a regional baseline to monitor how climate change may impact the largest habitat on the pla

211 These findings demonstrate how climate change may increase habitat connectivity and alt

212 Addressing climate change may require rapid global diffusion of Car

213 rimary productivity are key to determine how climate change might impact marine ecosystems and fisher

214 Modeling suggests that climate change mitigation actions can have substantial h

215 of the potential contributions of forests in climate change mitigation associated with tree planting.

216 In all cases, there are climate change mitigation benefits compared to fossil fu

217 impacts and broader ecological, social, and climate change mitigation outcomes.

218 We find that the diffusion of CCS in climate change mitigation pathways, when normalised for

219 estimation can help prioritize the case for climate change mitigation policies.

220 ered to determine whether planting trees for climate change mitigation results in increased C storage

221 of perennial crops as a useful component of climate change mitigation strategies.

222 n (the Master Plan) on population health and climate change mitigation, assuming primary, sustained u

223 organic matter and sequester soil carbon for climate change mitigation, but a renewal of high methane

224 ors to address the global land challenges of climate change mitigation, climate change adaptation, co

225 been proposed as a means to sequester C for climate change mitigation, yet little is known about how

226 c carbon will enable its potential to aid in climate change mitigation.

227 se net ecosystem C storage and contribute to climate change mitigation.

228 form conservation and management efforts for climate change mitigation.

229 resent contributions and future potential to climate change mitigation.

230 Brazil and the rest of the world in terms of climate change mitigation.

231 e United Nation's Intergovernmental Panel on Climate Change, most often assess POC (particulate organ

232 advocacy organizations' press releases about climate change (n = 1,768), examining which messages are

233 tudies have estimated the adverse effects of climate change on crop yields, however, this literature

234 e, a crucial step in assessing the impact of climate change on imperiled turtle species.

235 mate variation when predicting the impact of climate change on keystone species, such as the Baltic b

236 Despite concerns about the effects of climate change on migratory species and the critical rol

237 potential drastic and rapid consequences of climate change on multitrophic-level community structure

238 Understanding and predicting the impact of climate change on soil microbiomes and the ecosystem ser

239 te imagery (NDVI) to evaluate the impacts of climate change on Spain's forests.

240 ive, whereas the likely outcome of continued climate change on summer survival was generally positive

241 The effect of climate change on the slowing-down of SCA at MLO is main

242 ict the spatially explicit effects of future climate change on the wintering energetics of a freeze-t

243 The impacts of global climate changes on FNP availability in the environment a

244 We find impacts of climate changes on global GDP-per-capita by the end of t

245 remaining knowledge gaps on the influence of climate (change) on bat migration and abundance can be a

246 s expanding into new habitats as a result of climate change or human introductions will frequently en

247 n examining how these factors are altered by climate change (or vice versa), this framework will allo

248 with an increase in drought frequency due to climate change, pose a threat to plant growth and produc

249 For migratory herbivores, climate change poses a new and growing threat by alterin

250 Climate change poses significant emerging risks to biodi

251 Anthropogenic climate change precipitates the need to understand plant

252 However, under projections of climate change, predator plasticity was insufficient to

253 e of incorporating trophic interactions into climate change predictions.

254 ce of uncertainty in carbon cycle models and climate change projections.

255 a basis for interpreting recently published climate change projections.

256 ) ) in global agriculture is important given climate change projections.

257 on was realized via two dissimilar pathways: climate change reduced mean body size and intensive land

258 , we assess the likely effects of four major climate change-related abiotic factors on the spatiotemp

259 dy permits spatially explicit predictions of climate change-related population extinction-colonizatio

260 netic diversity and adaptive potential under climate-change-related range change.

261 Our results suggest that climate change scenarios considered here could result in

262 Combined land-use and climate change scenarios highlighted their interaction a

263 in (Aptenodytes forsteri) colonies under new climate change scenarios meeting the Paris Agreement obj

264 Climate change scenarios showed enhanced soil CO(2) due

265 ted CO(2) and warmer temperatures reflecting climate change scenarios somewhat attenuated nanoplastic

266 tes of change to body condition under future climate change scenarios within the next 50 years sugges

267 tivity and soil carbon dynamics under future climate change scenarios.

268 tribution of, vector species under projected climate change scenarios.

269 environmental conditions, particularly under climate change scenarios.

270 n the range of this freshwater fish based on climate change scenarios.

271 eading to similar SOC stocks under different climate change scenarios.

272 tical role of coastal wetlands in mitigating climate change, sea-level rise, and salinity increase, s

273 Fast ecological responses closely track climate change, slow responses substantively lag climate

274 tperformed local populations under simulated climate change (snow removal) across all five experiment

275 e eco-chemosphere of seaweeds in response to climate change stressors and other environmental stresso

276 become aware that responses of holobionts to climate change stressors may be driven by shifts in the

277 Based upon these concerns associated with climate change, the International Society for Children's

278 With climate change, the median annualized impact exceeds pou

279 mportant roles on coral reefs in the face of climate change, the species and functional groups they b

280 ave the ability to adapt to near-term future climate-change thermal anomalies.

281 Owing to the climate change, those indigenous varieties' substantial

282 indirect effects, we used the simulations of climate change to assess the distribution of P. smintheu

283 As climate change transforms seasonal patterns of temperatu

284 capacity to predict terrestrial feedback to climate change under projected warming scenarios.

285 While MREDs undoubtedly can help mitigate climate change, variability in the sensitivity of differ

286 mate trends, and whether advance rates match climate change velocities (CCVs).

287 capacity all contribute to heterogeneity in climate change vulnerability, predicting these features

288 preceding summer and the effect of continued climate change was likely to be mainly negative, whereas

289 erent driving processes, land use change and climate change were found to be the major drivers of tur

290 ability to adapt to the challenges posed by climate change, which hampers the implementation of miti

291 to fundamentally change in structure due to climate change, which leads to questioning of whether de

292 vity have distorted the public debate around climate change, while providing evidence that the struct

293 Climate change will affect peatland GEP especially throu

294 l effort has gone into predicting how global climate change will impact biodiversity patterns, the sc

295 To gain insight into how these projected 'climate change winners' evolve, we grew populations of m

296 se ecosystems are increasingly threatened by climate change with seasonal implications for photosynth

297 diversity necessary to evolve in response to climate change within populations of black cottonwood (P

298 To build resilience to climate change worldwide, it is imperative that we prote

299 n Arabia is one of resilience in the face of climate change, yet future challenges include rising tem

300 ten discussed as "co-benefits" of mitigating climate change, yet they are rarely considered when desi