ライフサイエンスコーパス: ecological system

1 stropod) within the natural complexity of an 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 ighs (PSHs) have major impacts on social and ecological systems.

5 d transformations of energy and materials in ecological systems.

6 advance our understanding of biological and ecological systems.

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

8 oles and traits that characterize species in ecological systems.

9 nce of finite metapopulations for two common ecological systems.

10 empirical trophic and nontrophic webs in two ecological systems.

11 derstanding of how catalytic loops appear in ecological systems.

12 wledges the interconnectedness of social and ecological systems.

13 the links between structure and function in ecological systems.

14 redict dynamics within these types of purely ecological systems.

15 iscern the underlying processes operating in ecological systems.

16 the inherent limitations in the response of ecological systems.

17 stigations into its consequences for various ecological systems.

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

19 relationships in complex and dynamic social-ecological systems.

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

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

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

23 an interdisciplinary program based on social-ecological systems.

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

25 esigning synergies between technological and ecological systems.

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

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

28 ts is crucial for understanding variation in ecological systems.

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

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

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

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

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

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

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

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

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

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

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

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

41 Localized ecological systems are known to shift abruptly and irrev

42 Ecological systems are often characterized as stable ent

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

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

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

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

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

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

49 Ecological systems can exhibit contrasting dynamics depe

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

72 Resilient social-ecological systems incorporate diverse mechanisms for li

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

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

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

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

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

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

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

80 Transitions in ecological systems often occur without apparent warning,

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

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

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

84 The complexity of ecological systems presents considerable challenges for

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

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

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

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

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

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

91 Ecological systems sensitive to climatic extremes may be

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

112 Identifying vulnerable ecological systems to drought stress and climate thresho

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

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

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

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

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

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

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

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