ライフサイエンスコーパス: ecological system

1 critical feedbacks in a transitioning social-ecological system.

2 discipline-bound sectors of the full social-ecological system.

3 Max(G) should not necessarily co-occur in an ecological system.

4 fer LUCA to have been part of an established ecological system.

5 ure of the variation of lifeforms in a given ecological system.

6 of health security hazards across the social-ecological system.

7 twork, we quantified the energy landscape of ecological system.

8 stropod) within the natural complexity of an ecological system.

9 relationships in complex and dynamic social-ecological systems.

10 racterize the structure of most species-rich ecological systems.

11 wo fundamental axes - space and time - shape ecological systems.

12 an interdisciplinary program based on social-ecological systems.

13 t may pose risks to public health and native ecological systems.

14 esigning synergies between technological and ecological systems.

15 te change have wide-ranging consequences for ecological systems.

16 g points, or critical transitions, in social-ecological systems.

17 ts is crucial for understanding variation in ecological systems.

18 ng direct, indirect, and boundary effects in ecological systems.

19 d transformations of energy and materials in ecological systems.

20 Wide Web, as well as political, social, and ecological systems.

21 oles and traits that characterize species in ecological systems.

22 nce of finite metapopulations for two common ecological systems.

23 , at least approximately, though not for all ecological systems.

24 ial markets to cancer cells to predator-prey ecological systems.

25 to expose the mechanisms structuring complex ecological systems.

26 re they capture the dynamics of contemporary ecological systems.

27 on complex computer simulations to forecast ecological systems.

28 aves (HWs) pose a severe threat to human and ecological systems.

29 past and future evolution of mountain social-ecological systems.

30 managing dynamic systems, such as threatened ecological systems.

31 for achieving large-scale predictability of ecological systems.

32 erence to estimate climate change effects on ecological systems.

33 the understanding of extinction dynamics in ecological systems.

34 risk assessments for other nanomaterials in ecological systems.

35 intrinsically linked to the health of global ecological systems.

36 sion remains about how they affect different ecological systems.

37 isms of stochastic dynamical transitions for ecological systems.

38 t and critical threat to the environment and ecological systems.

39 k of severe drought for vulnerable human and ecological systems.

40 gar fluxes in environmental, biomedical, and ecological systems.

41 nsights into the resilience and stability of ecological systems.

42 lative rarity and the multi-causal nature of ecological systems.

43 that anticipate transitions in physical and ecological systems.

44 ses (VBDs) are embedded within complex socio-ecological systems.

45 to increase our understanding about risk in ecological systems.

46 AAA pathway orchestrates and impacts social-ecological systems.

47 have multiscale and interrelated effects on ecological systems.

48 ved in data can predict the future states of ecological systems.

49 include attempts to adaptively manage social-ecological systems.

50 n scaling from controlled laboratory to open ecological systems.

51 tative methods employed to study mutualistic ecological systems.

52 ination with the workings of self-supporting ecological systems.

53 ronments is still poorly understood for many ecological systems.

54 ting laws for fostering resilience in social-ecological systems.

55 riability that bring unique hazards to socio-ecological systems.

56 ts of local coexistence in a narrow range of ecological systems.

57 ighs (PSHs) have major impacts on social and ecological systems.

58 stigations into its consequences for various ecological systems.

59 ause of water's indispensable role in social-ecological systems.

60 by global commerce, travel and disruption of ecological systems.

61 advance our understanding of biological and ecological systems.

62 tentially extensive changes in vegetation or ecological systems.

63 empirical trophic and nontrophic webs in two ecological systems.

64 derstanding of how catalytic loops appear in ecological systems.

65 wledges the interconnectedness of social and ecological systems.

66 the links between structure and function in ecological systems.

67 redict dynamics within these types of purely ecological systems.

68 iscern the underlying processes operating in ecological systems.

69 the inherent limitations in the response of ecological systems.

70 ant uncertainty with regard to their risk to ecological systems.

71 is important for the maintenance of natural ecological systems(1,2).

72 ism determines the structure and dynamics of ecological systems across many different scales.

73 as a minimal null model of noisy competitive ecological systems, against which more complex models th

74 ment by organisms is a ubiquitous feature of ecological systems, allowing spatial structure to develo

75 These features of the social-ecological system also would have limited the effectiven

76 the public since it poses serious threats to ecological system and human health.

77 of a well-defined tipping point in a complex ecological system and provide insight into the fundament

78 y provide new insights into the structure of ecological systems and be key in evaluating fire managem

79 itation', is likely to be widespread in real ecological systems and can dictate both the rates of eco

80 ronmental change can impact the stability of ecological systems and cause rapid declines in populatio

81 can generate simple models of linked social-ecological systems and deduce general solutions to the o

82 s critical for understanding their impact on ecological systems and developing management solutions.

83 ncy, respond to disturbances like many macro-ecological systems and exhibit path-dependent, autogenic

84 onmental standards is essential to safeguard ecological systems and human societies.

85 ory also reveals deep human imprints on many ecological systems and indicates that secular climate ch

86 ions about the impact of invasive species in ecological systems and new competitors in economic syste

87 pairwise relationships that may be found in ecological systems and real data from a previous study o

88 researchers to study the connections between ecological systems and their molecular processes in prev

89 n in social-ecological systems, evolutionary-ecological systems, and even psychological-economic syst

90 Numerous challenges to agriculture, ecological systems, and human health could be mitigated

91 metrics are used to assess the stability of ecological systems, and the choice of one metric over an

92 sity in European Seas, its importance within ecological systems, and the implications for human use.

93 tainability in directionally changing social-ecological systems, apply this framework to climate-warm

94 An integrated social-ecological systems approach to collective action in plan

95 , combined with novel appropriation using an ecological systems approach, elemental carbon-nitrogen s

96 Employing an ecological-systems approach we analyse associations betw

97 Interactions between the social and the ecological system are based on a perception-exploitation

98 Ecological systems are a challenge to fully and holistic

99 However, if the fates of ecological systems are better predicted by past response

100 Moreover, ecological systems are dynamic and ever-evolving, which

101 impacts of hydrological change on social and ecological systems are infrequently evaluated together a

102 Localized ecological systems are known to shift abruptly and irrev

103 Ecological systems are made up of complex and often unkn

104 Ecological systems are no longer at equilibrium, but ove

105 Ecological systems are often characterized as stable ent

106 Ecological systems are quintessentially complex systems.

107 However, examples of such patterns in ecological systems are scarce.

108 Many ecological systems are subject critical transitions, whi

109 Population-level scaling in ecological systems arises from individual growth and dea

110 A variety of ecological systems around the world have been damaged in

111 Considering an ecological system as a reverse auction broadens our view

112 tworks to predict the long-term behaviors of ecological systems as characterized by their attractors.

113 How are ecological systems assembled?

114 nt processes contribute to the assemblage of ecological systems at different levels of organization,

115 ns and life cycles, along with corresponding ecological systems at multiple spatial scales ranging fr

116 population, is not a fundamental property of ecological systems, at least in the context of spatial h

117 omous units; rather, they function within an ecological system, both actively remodeling the microenv

118 hanges of information are also widespread in ecological systems, but their effects on ecosystem-level

119 would cause transformative changes in social-ecological systems by jeopardizing climate stability and

120 table example of how collective phenomena in ecological systems can arise from the individual respons

121 apidly changing climates, rates of change of ecological systems can be described as fast, slow or abr

122 rlying biological processes that govern many ecological systems can create very long periods of trans

123 Ecological systems can exhibit contrasting dynamics depe

124 Ecological systems can often be characterised by changes

125 n-intuitive ways, the high-dimensionality in ecological systems can profoundly influence cycling, and

126 Ecological systems can undergo sudden, catastrophic chan

127 Much like in ecological systems, catastrophic failures of SM networks

128 f large-scale private sector actors in socio-ecological systems change.

129 ng these issues through the lens of a social-ecological system, combining remote and in-situ earth ob

130 led that malignant brain cancers are complex ecological systems composed of distinct cellular and ace

131 tasis will predominantly emerge whenever the ecological system contains only symmetric ecological int

132 es are reviewed: individualism-collectivism; ecological systems; cultural-ecological; social identity

133 thinking runs counter to evidence that many ecological systems damaged by severe natural environment

134 Urban areas are dynamic ecological systems defined by interdependent biological,

135 nested structures akin to those observed in ecological systems, demonstrating that the platform's us

136 We review features of ecological systems described within CSS and conduct bibl

137 aches in understanding and addressing social-ecological system dynamics.

138 lobal problem that can greatly affect marine ecological systems, especially free-living bacteria, whi

139 den changes in populations are ubiquitous in ecological systems, especially under perturbations.

140 ies and the environment are common in social-ecological systems, evolutionary-ecological systems, and

141 Many drivers of ecological systems exhibit regular scaling relationships

142 Human societies and ecological systems face increasingly severe risks, stemm

143 f all, to the viability and existence of the ecological systems for its human settlements.

144 enge in developing data-driven approaches to ecological systems for tasks such as state estimation an

145 xtraintestinal infections and competition in ecological systems for this organism are discussed.

146 Drawing upon the social-ecological systems framework and associated design princ

147 xplore Nobel Laureate Elinor Ostrom's social-ecological systems framework as an approach for identify

148 Here, we develop a version of the social-ecological systems framework modified for the specific c

149 We use a social-ecological systems framework to develop four recommendat

150 ling to infer past or future trajectories of ecological systems from contemporary spatial patterns.

151 with anthropogenic activities are impacting ecological systems globally, giving rise to the Anthropo

152 Modelling of complex natural ecological systems has allowed for new findings, but the

153 The stability of ecological systems has been a long-standing focus of eco

154 The origin of regular spatial patterns in ecological systems has long fascinated researchers.

155 tudies of small-scale, self-organized social-ecological systems have contributed to our understanding

156 Moreover, ecological systems have emergent and resilient behaviors

157 Such signals for transitions in social-ecological systems have rarely been observed, not the le

158 Mangroves exist in complex social-ecological systems, hence identifying socioeconomic cond

159 icrobiome research shed light on this unique ecological system, highlighting the need for innovative

160 o with increasing degree of asymmetry in the ecological system (i.e., the more trophic interactions,

161 pplying our approach across different social-ecological systems, illustrating the approach for crop p

162 temperature on the structure and dynamics of ecological systems in a world where regional and global

163 gmentation is a complex process that affects ecological systems in diverse ways, altering everything

164 functional strategies that can help sustain ecological systems in the face of disturbances.

165 he diversity, and the long-term stability of ecological systems in the presence of noise and fluctuat

166 onomies are sometimes viewed as analogous to ecological systems in which "everything is connected to

167 climate-adaptive decisions in complex social-ecological systems in which both climate change and adap

168 n dynamics and community interactions within ecological systems, including infectious diseases.

169 Human management of ecological systems, including issues like fisheries, inv

170 ty of our method) and by application to real ecological systems, including the controversial sardine-

171 Anthropogenic noise threatens ecological systems, including the cultural and biodivers

172 Resilient social-ecological systems incorporate diverse mechanisms for li

173 We present our efforts at developing an ecological system index using information theory.

174 We also show how characteristics of an ecological system influence the optimal investment strat

175 Identifying the climatic drivers of an ecological system is a key step in assessing its vulnera

176 he Amazon River Basin's extraordinary social-ecological system is sustained by various water phases,

177 dying interactions of microplastics with our ecological system is to identify plastics within environ

178 uggests that the assembly and disassembly of ecological systems is a discontinuous process that tends

179 Governance of social-ecological systems is a major policy problem of the cont

180 he potential for forecasting the dynamics of ecological systems is currently unclear, with contrastin

181 derstanding long-term dynamics of past socio-ecological systems is essential for their future managem

182 A ubiquitous pattern in ecological systems is that more abundant species tend to

183 ea pallasii), a foundation of coastal social-ecological systems, is in decline throughout much of its

184 such as power grids, financial networks, and ecological systems, is to understand their response to d

185 Therefore, as in other ecological systems, it is important to identify quantita

186 Here, we show that, in mutualistic ecological systems, it is possible to identify species t

187 Applied to ecological systems, it results in discrete multispecies

188 While experiments and data from simple ecological systems lend support, large-scale evidence fr

189 Hadal trenches are unique geological and ecological systems located along subduction zones.

190 ning signals of transitions in modern social-ecological systems may be stronger, and hence easier to

191 t integrating microbiota science with social-ecological systems modeling is essential for advancing o

192 We share examples of how challenges in ecological systems modeling would benefit from advances

193 ect basis for computational enzyme kinetics, ecological systems models, and models for the spread of

194 reproduction have shorter lifespans; and in ecological systems, more frequent reproduction can incre

195 cal evidence that the developmental order of ecological systems moves along the paths of least enviro

196 Transitions in ecological systems often occur without apparent warning,

197 als and populations to ecosystems and social-ecological systems, often exhibit abrupt reorganizations

198 ortance in facilitating our understanding of ecological systems, only three molecules thus far have b

199 easures that will exclude a pathogen from an ecological system or, if the system is already disease-f

200 sed relationships that have supported social-ecological systems over the long term.

201 untries, creating shocks to fisheries social-ecological systems particularly in climate-vulnerable ar

202 trend in the developmental order of diverse ecological systems paves the way to an enhanced understa

203 Predicting how disturbance to these ecological systems places people and animals at risk fro

204 The complexity of ecological systems presents considerable challenges for

205 ution, isocyanides carved out a niche in the ecological systems probably thanks to their metal coordi

206 Connectivity of social-ecological systems promotes resilience across urban land

207 casts can be made, and about how features of ecological systems relate to these distances.

208 l theoretical concepts and tools to specific ecological systems remains a challenge.

209 Building resilient social-ecological systems requires approaches that are robust t

210 wledge coproduction approach based on social-ecological systems research and assess its utility in ge

211 e, such as populations, ecosystems and socio-ecological systems, respond to small perturbations with

212 tails may limit a model's ability to predict ecological systems' responses to management.

213 The dynamics of large ecological systems result from vast numbers of interacti

214 southern African woodlands and savannas, an ecological system rife with disturbance from fire, herbi

215 asis on the management of human, social, and ecological systems seen primarily from an engineering an

216 Ecological systems sensitive to climatic extremes may be

217 re determined within a coupled socioeconomic-ecological system (SES) where human choices, including t

218 the transient dynamics of interlinked social-ecological systems (SES) is imperative for assessing sus

219 or sustainable transition pathways of social-ecological systems (SES).

220 can make simple, predictive models of social-ecological systems (SESs) and deduce universal solutions

221 infrastructure affect the dynamics of social-ecological systems (SESs) and the capacity of groups to

222 The social-ecological systems (SESs) framework provides guidance on

223 Effective management of social-ecological systems (SESs) requires an understanding of h

224 uages to describe and explain complex social-ecological systems (SESs).

225 of adaptive learning and decision for social-ecological systems (SESs).

226 y consistent with Lotka's conjecture that an ecological system should evolve towards a state of maxim

227 change, the theory and practice of managing ecological systems should shift attention from target st

228 's oceans.(1-9) As intricately linked social-ecological systems, small-scale fisheries require manage

229 ted with participatory assessments of social-ecological system structure and stakeholders' well-being

230 to determine the evolutionary properties of ecological systems subject to trade-offs.

231 sembly model reproduces many key features of ecological systems, such as the role of generalists duri

232 rk to assess the impact of integrated Techno-Ecological Systems (TES), comprising relevant ecosystems

233 rgence, these pathogens exist within complex ecological systems that are characterized by trophic int

234 and extinction are fundamental processes in ecological systems that are difficult to accurately meas

235 ortant in many epidemics in agricultural and ecological systems that are prone to regular disturbance

236 mportance of understanding dimensionality in ecological systems that are undergoing diversity loss in

237 rder to gain an insight into the features of ecological systems that determine the evolutionary outco

238 roduced a new framework for analyzing social-ecological systems that has had wide influence in the po

239 We provide several examples of ecological systems that may have reverse auctions as und

240 Microbiomes are complex ecological systems that play crucial roles in understand

241 Community gardens are social-ecological systems that support food production, social

242 tion or management to change the state of an ecological system, that timescales need explicit conside

243 nciples that characterize the development of ecological systems (the appearance of a group of taxa),

244 Yet, for most ecological systems, the number of experiments required t

245 Despite the ubiquity of pathogens in ecological systems, their roles in influencing ecosystem

246 Using the Ecological Systems Theory (EST) as a model, we sought to

247 Application of adversity to Bronfenbrenner's ecological systems theory provides a strategic approach

248 The framework builds on Bronfenbrenner's ecological systems theory to conceptualize adversities a

249 n turn its metabolic wastes can overload the ecological system, threatening the long-term survivabili

250 the necessary delays in the response of the ecological system to management.

251 e is broadly understood as the ability of an ecological system to resist and recover from perturbatio

252 ence and by using those laws to allow social-ecological systems to adapt and transform.

253 ing on the natural restorative tendencies of ecological systems to build a science of repairing the h

254 Identifying vulnerable ecological systems to drought stress and climate thresho

255 esigning synergies between technological and ecological systems to encourage greater harmony between

256 Forecasting the response of ecological systems to environmental change is a critical

257 g envision informed management of social and ecological systems to sustain delivery of ecosystem serv

258 Resilience-the ability of socio-ecological systems to withstand and recover from shocks-

259 Most network studies of social-ecological systems use simple, undirected, unweighted ne

260 Recognizing that pandemics originate in ecological systems, we advocate for integrating ecologic

261 t of periodic forcing on epidemiological and ecological systems when that forcing acts on just one pa

262 covery efforts are embedded in marine social-ecological systems where large-scale dynamics can inhibi

263 ropical wetlands are highly threatened socio-ecological systems, where local communities rely heavily

264 ver, to predict reliably the future state of ecological systems, which inherently could consist of mu

265 ompetition is one of the most common form in ecological systems, which plays important roles in popul

266 s fundamental questions about complex social-ecological systems while evaluating assumptions of polic

267 echnological interventions in complex social-ecological systems will generate new risks, benefits, an

268 econstructing the "dynamical climate" of the ecological system with limited data.

269 rts requires guiding the recovery of complex ecological systems with many interdependent species at a

270 fortunately, this procedure tends to produce ecological systems with no underlying equilibrium soluti

271 forecasts than simple model-free methods for ecological systems with noisy nonlinear dynamics.

272 antages of each approach for applications to ecological systems with particular features, with the go

273 s are pervasive among foragers across social-ecological systems yet neglected in research and policym