ライフサイエンスコーパス: water scarcity

1 sable in future water management to mitigate water scarcity.

2 t through a local production without land or water scarcity.

3 use (DPR) is a promising solution to address water scarcity.

4 water sources are needed to address growing water scarcity.

5 ritize to enhance their preparedness against water scarcity.

6 quantity and quality management to cope with water scarcity.

7 spatial variability such as biodiversity and water scarcity.

8 uring national food security and alleviating water scarcity.

9 ining pistachio production in regions facing water scarcity.

10 influence estimates of impact when assessing water scarcity.

11 Water reuse is expanding due to increased water scarcity.

12 ting some of the most extreme adaptations to water scarcity.

13 le reuse to address the challenges of global water scarcity.

14 available freshwater resources and increases water scarcity.

15 ng food security and alleviating problems of water scarcity.

16 toward increased eutrophication and greater water scarcity.

17 ch and infrastructure, as well as increasing water scarcity.

18 e clearing forests and exacerbating regional water scarcities.

19 llution is a key driver to pollution induced water scarcity across China.

20 dings highlight the risk of increased future water scarcity across MLE caused by large-scale climatic

21 ties is therefore crucial for the success of water scarcity adaptation by HI.

22 Water scarcity afflicts societies worldwide.

23 rastically change the critical dimensions of water scarcity, aggravating water scarcity for 8.8% (7.4

24 d 2017, which allows the economic impacts of water scarcity along supply chains to be comprehensively

25 potential economic cost of and resilience to water scarcity along the supply chain is critical for ma

26 While conditions of blue water scarcity already existed prior to land acquisition

27 Today, they are under increasing stress as water scarcity and a growing recognition of the importan

28 Dryland expansion causes widespread water scarcity and biodiversity loss.

29 Driven by growing global water scarcity and by energy cost and negative environme

30 Soil degradation due to global warming, water scarcity and diminishing natural resources negativ

31 Water scarcity and drought were largely unassociated wit

32 In this study, we incorporate water scarcity and ecosystem impacts into multiregional

33 ofiltration, play a vital role in addressing water scarcity and enabling resource recovery.

34 of China, thereby mitigating the effects of water scarcity and facilitating sustainable agricultural

35 es such as food security, biodiversity loss, water scarcity and human health are affected by referenc

36 eet water demands in Egypt during periods of water scarcity and increase hydropower generation and st

37 Growing water scarcity and increasing food demand are driving in

38 the arid and semi-arid regions stressed with water scarcity and natural resource constraints.

39 ion in US remains particularly vulnerable to water scarcity and rising stream temperatures under clim

40 uth East Australia are faced with escalating water scarcity and security challenges.

41 The critical link between water scarcity and sustainability is adaptation.

42 Water scarcity and the increasing severity of water defi

43 lows better understanding of what is causing water scarcity and which regions are suffering from it.

44 lenges including salinization, soil erosion, water scarcity, and anthropogenic pollution.

45 environmental factors such as air pollution, water scarcity, and climate change, have fueled the cont

46 utcomes, including increased fire incidents, water scarcity, and higher mortality of pine trees.

47 ity, mainly because of lower global warming, water scarcity, and metal contamination impacts.

48 the extensive clearing of forestland, fresh water scarcity, and sharp rises in the price of food hav

49 illustrates that estimates of the impacts of water scarcity are an artifact of how water scarcity is

50 Key determinants of water scarcity are found to be the cost of transporting

51 s and hydropower, and their contributions to water scarcity, are poorly understood.

52 -18.8 MPa), and was significantly related to water scarcity, as was tracheid diameter.

53 We highlight the necessity of incorporating water scarcity assessment at multiple temporal and geogr

54 Here we report a comprehensive nationwide water scarcity assessment in China, which explicitly inc

55 Previous large-scale water scarcity assessments mostly focused on the availab

56 es and aquifers which have been neglected in water scarcity assessments so far.

57 proach for farmers facing drought events and water scarcity associated with climate change in semiari

58 transnational LSLAs to evaluate emergence of water scarcity associated with LSLAs.

59 We show that water scarcity at ammonia production sites represents no

60 timation of the global population exposed to water scarcity based on 7 water scarcity indicators and

61 shows great potential in response to global water scarcity because of its high solar-to-vapor effici

62 .g., East Africa); the peak time of emerging water scarcity began around the 1980s.

63 in new infrastructure to overcome increasing water scarcity, better guidance is needed to facilitate

64 Water scarcity brings tremendous challenges to achieving

65 Here we expand the debate on water scarcity by considering green water scarcity (WS(g

66 wo thirds of water-scarce cities can relieve water scarcity by infrastructure investment, but the pot

67 strategy to address the global challenge of water scarcity by tapping into the vast reserves of atmo

68 Physical water scarcities can be described by water stress indice

69 Water scarcity caused by climate change and population g

70 Rising temperatures and water scarcity caused by climate change are increasingly

71 rategies are needed to tackle the escalating water scarcity caused by global warming.

72 tand as energy-efficient alternatives to the water scarcity challenge and various wastewater treatmen

73 Increasing water scarcity challenges crop sustainability in many re

74 Attribution of water scarcity changes to HI components is complex and v

75 To address water scarcity, cities are pursuing options for augmenti

76 n pine systems as a nature-based solution to water scarcity concerns.

77 strate that this technology can help monitor water scarcity conditions and emerging food insecurity,

78 is likely to exacerbate regional and global water scarcity considerably.

79 for water and food, thereby exacerbating the water scarcity crisis.

80 mostly occur upstream, whereas HI aggravate water scarcity downstream; HI cause water scarcity to tr

81 pport growing populations and buffer against water scarcity due to changing climate, this work is imp

82 sufficient quantities, experiences seasonal water scarcity due to inadequate quality.

83 thern lowlands of Central America dealt with water scarcity during annual dry seasons and periods of

84 In regions of the world affected by water scarcity economic activities can be constrained by

85 ater scarcity (FirstWS) and disappearance of water scarcity (EndWS), by using ensembles of simulation

86 With worsening global water scarcity, especially in some developing countries,

87 However, considering monthly average water scarcity estimates spatially aggregated at the bas

88 assess the timing of the first emergence of water scarcity (FirstWS) and disappearance of water scar

89 ould explicitly be part of any assessment of water scarcity, food security, or bioenergy potential.

90 on quantifying the water footprint (WF) and water scarcity footprint (WSF) of renewable diesel deriv

91 ions (GHGE), cumulative energy demand (CED), water scarcity footprint (WSF), land, fertilizer nutrien

92 otential biodiversity damage but the largest water scarcity footprint following respective sourcing p

93 to reduce water-stress impact, quantified as water scarcity footprint, through the choice of algae si

94 ms with poultry or pork, the mean carbon and water scarcity footprints among those with substitutions

95 Impacts were summed to create carbon and water scarcity footprints for diets (n = 16,800) of adul

96 ingle dietary substitution on the carbon and water scarcity footprints of self-selected diets in the

97 ets to substantially reduce their carbon and water scarcity footprints without sacrificing dietary qu

98 fore quantifying damage to biodiversity, and water scarcity footprints.

99 al dimensions of water scarcity, aggravating water scarcity for 8.8% (7.4-16.5%) of the global popula

100 timates temporally disaggregated to consider water scarcity for at least one month a year found 50% (

101 of ammonia production, evaluate exposure to water scarcity for each of the 406 global plants, and tr

102 evolution of blue (i.e., surface and ground) water scarcity for the world's three most populous count

103 Water scarcity has become a critical problem in many sem

104 hand, several Mediterranean countries, where water scarcity has been a problem for years, have decrea

105 Water scarcity has driven the demand for water productio

106 The worsening water scarcity has imposed a significant stress on food

107 Fresh water scarcity has led to increased use of reclaimed was

108 Aging water infrastructure and increased water scarcity have resulted in higher interest in water

109 Past assessments of water scarcity (i.e., water demand in exceedance of avai

110 conventional technologies on average, while water scarcity impacts are doubled on average.

111 asin-scale exploratory analysis of potential water scarcity impacts by linking a global human-Earth s

112 We quantify global urban water scarcity in 2016 and 2050 under four socioeconomic

113 strial, domestic and agricultural WFs caused water scarcity in 6 of the 10 major Chinese river basins

114 attention and effort to adapt to the looming water scarcity in Africa.

115 itions, tomato can be negatively affected by water scarcity in arid and semiarid regions.

116 Water scarcity in arid regions is a significant factor c

117 ing, are being used to counteract increasing water scarcity in arid regions.

118 for water saving in maize systems exist, but water scarcity in China remains a serious problem.

119 Water scarcity in combination with prevalent soil degrad

120 he U.S., and India are indirectly exposed to water scarcity in distant basins, with the largest trade

121 In addition, fresh water scarcity in dry regions or during periods of droug

122 Yet the timing of water scarcity in its onset and possible relief in diffe

123 Water scarcity in semi-arid/arid regions is driving the

124 Water scarcity in the mid-latitude Eurasia (MLE) has bee

125 e important both for the characterization of water scarcity in the Mississippi watershed and for wate

126 d fuel concerns that global warming enhances water scarcity in the semi-arid regions of interior Eura

127 olia, thus significantly contributing to the water scarcity in these regions.

128 an incredible array of mechanisms to address water scarcity, including modulation of root system arch

129 assessed in water-related LCIA methods using water scarcity indicators (e.g., withdrawal-to-availabil

130 ulation exposed to water scarcity based on 7 water scarcity indicators and 11 Environmental Flow Requ

131 Water scarcity, intensified by climate change, poses a m

132 As water scarcity intensifies, point-of-use and point-of-en

133 Incorporating water scarcity into water consumption allows better unde

134 Water scarcity is a global challenge affecting billions

135 Water scarcity is a global problem that can be compounde

136 Water scarcity is a major challenge in the Sahel region

137 Where water scarcity is a major limitation now or under future

138 Water scarcity is a pressing global issue, requiring inn

139 Water scarcity is a pressing issue in California.

140 Water scarcity is a threat for food production because,

141 Alleviating water scarcity is at the core of Sustainable Development

142 rid and semi-arid regions such as Iran where water scarcity is compounded by quality degradation.

143 cts of water scarcity are an artifact of how water scarcity is defined and calculated.

144 First, water scarcity is defined at the sub-river basin scale w

145 Water scarcity is determined by relating annual water co

146 Water scarcity is dynamic and complex, emerging from the

147 Water scarcity is intensified by drought, a phenomenon t

148 Water scarcity is one of the most pressing issues of con

149 Fresh water scarcity is one of the most threatening issues for

150 Irrigation water scarcity is particularly large in parts of souther

151 The number of large cities exposed to water scarcity is projected to increase from 193 to 193-

152 e we show the global urban population facing water scarcity is projected to increase from 933 million

153 Water scarcity is rapidly increasing in many regions.

154 Economic water scarcity is severe in the developing countries; th

155 alleviate water shortage may only work when water scarcity is taken into account and virtual water f

156 irtual water reveal additional insights when water scarcity is taken into account.

157 potential to not only mitigate the existing water scarcity issue but also remediate MPs pollution in

158 ers have expressed concern over the emerging water scarcity issues around the globe.

159 ered to be an attractive approach to address water scarcity issues globally.

160 atment technology, helping to relieve global water scarcity issues.

161 ments is of importance for better addressing water scarcity issues.

162 e the number of people living under absolute water scarcity (<500 m(3) per capita per year) by anothe

163 With increasing water scarcity, many utilities are considering the potab

164 Escalating global water scarcity necessitates high-performance desalinatio

165 ed to grow worse in the coming decades, with water scarcity occurring globally, even in regions curre

166 ions, including regions already experiencing water scarcity or excess.

167 ffected monthly river water availability and water scarcity over the period 1971-2010.

168 Over half of the population are affected by water scarcity, pointing to an urgent need for improving

169 ique for eliminating pollutants to alleviate water scarcity pressure but is severely hindered by poor

170 eparations are increasingly needed to combat water scarcity, recover resources from wastewater, and e

171 g to the importance of water conservation in water scarcity regions, estimating the exact amount of r

172 proach tracing the location of water use and water scarcity related to feed production, transport, an

173 which demonstrates its potential for global water scarcity relief.

174 Water scarcity, resulting from climate change, poses a s

175 We quantified water scarcity risks and resilience at the city level, s

176 erent cities and is negatively correlated to water scarcity risks.

177 Water scarcity severely impairs food security and econom

178 All indicators show an increase in water scarcity since 1901.

179 ental trade-offs associated with large-scale water scarcity solutions must be guarded against.

180 Chile), to determine their ability to reduce water scarcity stress on tomato seedlings.

181 onsistent with a decreasing response time to water scarcity, suggesting a stronger susceptibility of

182 The resilience to water scarcity, taking into account multiple dimensions

183 Based on local blue water scarcity, the water depletion index (WDI) denotes

184 With global climate change, water scarcity threatens whole agro/ecosystems.

185 s, these deals substantially exacerbate blue water scarcity through both the adoption of water-intens

186 echnology to address the global challenge of water scarcity through desalination and potable reuse of

187 North China often suffers water scarcity throughout the year, whereas South China,

188 inoculated seeds and seedlings subjected to water scarcity; thus, the use of these consortia can rep

189 The significance of water scarcity to crop production and food security has

190 ggravate water scarcity downstream; HI cause water scarcity to travel downstream.

191 h large GW level declines resulting in urban water scarcity, unsustainable agricultural production, a

192 Results demonstrate how water scarcity varies greatly across small distances and

193 and climate change are together exacerbating water scarcity-where water demand exceeds availability-f

194 conflict and sudden migrations triggered by water scarcity, which is already associated with the lar

195 ontrolled population migrations triggered by water scarcity, which is already associated with the lar

196 inadequate water quality exacerbates China's water scarcity, which is unevenly distributed across the

197 ands will be rendered infertile by salt, and water scarcity will pit growing desert cities against ag

198 ebate on water scarcity by considering green water scarcity (WS(g)).

199 alination is essential for mitigating global water scarcity; yet, the process is energy-intensive and