ライフサイエンスコーパス: water resource

1 f from an environmental threat to a valuable water resource.

2 nvironment is a threat to the quality of our water resources.

3 tainably manage future human needs for clean water resources.

4 ng-related chemicals were to impact drinking water resources.

5 drologic response and manage our terrestrial water resources.

6 how these dams will operate to manage scarce water resources.

7 uture total precipitation as an indicator of water resources.

8 of its using in various food items and other water resources.

9 the challenges for sustainable management of water resources.

10 lly leading to the contamination of drinking water resources.

11 ainty in quality and quantity of traditional water resources.

12 rtant controls on Tibetan Plateau (TP) fresh water resources.

13 n used as target for monitoring of the fresh water resources.

14 eing sought as an alternative to traditional water resources.

15 globally, increase the pressure on available water resources.

16 nt knowledge about climate change impacts on water resources.

17 s well as increasing the industry's need for water resources.

18 ry with significant but unevenly distributed water resources.

19 lic fracturing (HF) of hydrocarbon assets on water resources.

20 ectively manage and control the treatment of water resources.

21 tion, which in turn depends on the access to water resources.

22 r energy costs, and reduce energy impacts on water resources.

23 use gas emissions, but also impacts land and water resources.

24 endent on an effective storage and supply of water resources.

25 s maintain their barrier function to protect water resources.

26 years, which would negatively impact Andean water resources.

27 gainst agribusiness in the face of dwindling water resources.

28 he potential loss of fisheries, forests, and water resources.

29 in hair provide a weekly record of diet and water resources.

30 fundamental to the sustainable regulation of water resources.

31 and energy sectors amidst dwindling, quality water resources.

32 the industrial sectors, and contamination of water resources.

33 al demands are increasing pressure on global water resources.

34 oms (CyanoHABs) pose serious risks to inland water resources.

35 gy to optimize crop production under limited water resources.

36 biomass industrialization and management of water resources.

37 understanding and sustainable management of water resources.

38 ortant in regions where snow is critical for water resources.

39 systems may negatively affect the quality of water resources.

40 tor the effects of climate change on surface water resources.

41 orting the preservation and effective use of water resources.

42 practices for the sustainable management of water resources.

43 rucial for future projections of climate and water resources.

44 infrastructure designs and management of the water resources.

45 ow depth observations are critical to assess water resources.

46 that drives intense competition for land and water resources.

47 d to considerable reductions in mid-latitude water resources.

48 d reuse facilities to abate nitrate in local water resources.

49 ss water ecosystem health and the quality of water resources.

50 n water usage may significantly impact local water resources.

51 fecal pollution to protect public health and water resources.

52 detection of ciprofloxacin (CPX) molecule in water resources.

53 will depend on a plant's capacity to exploit water resources.

54 e globe attempt to better-manage their fresh water resources.

55 ive analytical method for virus detection in water resources.

56 t face increased conflicts and tensions over water resources.

57 the overall human appropriation of land and water resources.

58 aps with the intention to better protect our water resources.

59 osystems(1), greenhouse gas emissions(2) and water resources(3), yet their surface-extent dynamics, p

60 gh certainty' consensus regarding decreasing water resources(4) in such regions of sub-Saharan Africa

61 d climate change continue to pressure global water resources(4), our approach provides a useful basel

62 We searched the MEDLINE, EMBASE, Water Resources Abstracts, and TOXNET databases through

63 or excessive nutrient enrichment, threatens water resources across the globe.

64 es and bottlenecks in the sustainable use of water resources across the six continents, pointing at p

65 iability and availability of inputs to fresh water resources across the tropics.

66 Optimal technical schemes for water resources allocation among different users are obt

67 ve programming model is proposed for optimal water resources allocation management.

68 onmental factors for optimal reallocation of water resources among different industry users.

69 critical to the management of this important water resource and ecosystem relies primarily on a syste

70 astewater treatment has to become a valuable water resource and its reuse is an important issue that

71 s on aquatic ecosystem functioning, drinking water resources and carbon cycling between land and sea.

72 uel refineries, transportation, agriculture, water resources and crop/ethanol markets.

73 improving irrigation efficiency to preserve water resources and decelerate escalating exposure to dr

74 As water resources and demands are spatially variable, it i

75 udy in observation scarce mountainous areas, water resources and ecosystem managements in the region.

76 e and median snow year changes, could impact water resources and ecosystems.

77 to crops is a serious cause of pollution of water resources and environment.

78 how an important imbalance between origin of water resources and final destination, with significant

79 at-related human mortality, while impacts on water resources and hydropower are overestimated in some

80 rease seasonal snowpack and provide critical water resources and hydropower for the state.

81 s and thus could help to remediated polluted water resources and prevents eutrophication.

82 r quality monitoring is crucial for managing water resources and protecting public health.

83 passed, which has profound implications for water resources and riverine habitats.

84 e public to address increasing challenges of water resources and security in China.

85 implications of such increased production on water resources and stream quality at regional and local

86 at several countries heavily rely on foreign water resources and that many countries have significant

87 erica has implications for the allocation of water resources and the course of regional development.

88 change is critical to the sustainability of water resources and the survival of glaciers.

89 decade due to their widespread detection in water resources and their potential to affect ecosystem

90 the participants' views and knowledge about water resources and wastewater reuse.

91 global population with a severe decrease in water resources and will increase the number of people l

92 lls has led to considerable controversy over water-resource and environmental impacts.

93 g-term rainfall variability is essential for water-resource and land-use management in sub-humid regi

94 egative impacts on downstream ecosystems and water resources, and complications created for the estab

95 ater-stressed countries to augment available water resources, and construction of new desalination pl

96 huge impacts on renewable energy production, water resources, and economic development, particularly

97 significant impacts on agriculture, energy, water resources, and ecosystems.

98 screpancy among fossil fuel resources, fresh water resources, and energy demand.

99 eparate the governance of mineral expansion, water resources, and local development, and of relations

100 Glacier mass loss affects sea level rise, water resources, and natural hazards.

101 y to forecast extreme weather events, manage water resources, and optimize agricultural practices.

102 , but enables critical access to grazing and water resources, and trade.

103 tions and economies grow, new constraints on water resources are appearing, raising questions about l

104 Four potential risks for water resources are identified: (1) the contamination of

105 tudy provides an analysis of how efficiently water resources are used for unconventional shale develo

106 Cyanobacteria pose a serious threat to water resources around the world.

107 ltivation ponds require appropriate land and water resources, as well as transportation and utility i

108 uction processes, implying increasing use of water resources at the expense of environmental water ba

109 re anthropogenic substances that contaminate water resources at trace concentrations.

110 distributed irrigation systems, and land and water resource availability across sub-Saharan Africa (S

111 ncertainties to predicting droughts, floods, water resource availability, and ecosystem services.

112 urface change responses in projecting future water resource availability, with important implications

113 unoff, a substantial effect on the timing of water resources availability.

114 Atmospheric moisture is a ubiquitous water resource available at any time and any place, maki

115 a are critical for sustainable management of water resources but remain very limited.

116 Treated wastewater is a valuable water resource, but its reuse for agricultural irrigatio

117 ental challenges, including contamination of water resources by agrichemicals, such as nutrients and

118 Contamination of water resources by cleaning products is more likely to o

119 the potential for conserving both energy and water resources by measuring the life-cycle economic eff

120 However, contamination of water resources by trace organic compounds (TOrCs), incl

121 For fecal-oral parasites, water resources can aggregate many different hosts in sm

122 Heavy metals in water resources can come from various industrial activit

123 Snow plays a fundamental role in global water resources, climate, and biogeochemical processes;

124 ies were higher for camera traps placed near water resources compared with those placed on trails.

125 us crucial to alleviate the conflict between water resource constrain and economic development.

126 ssential component of energy production, and water resource constraints will limit our options for me

127 uptions may not be primarily due to physical water resource constraints.

128 nmental flow (e-flow) due to the increase in water resource consumption in the agricultural sector an

129 n events are increasingly valuable as global water resources continue to be stretched to their limits

130 d facilitated long-term sharing of a limited water resource, decreased aggression, and strongly defin

131 rters of net virtual water at the expense of water resource depletion in other water scarce provinces

132 tion was found in five variables: per capita water resources, disposable income, dependence on foreig

133 The warm spring also depleted soil water resources earlier, and thus exacerbated water limi

134 The potential impact on water resources, ecosystems and human livelihood require

135 intensification with impacts on agriculture, water resources, ecosystems, and the human environment.

136 ven though they have relatively few land and water resource endowments.

137 cal role of future changes in ARs to Western water resources, especially over California.

138 nship between human settlement locations and water resources evolved over time?

139 Results show that sufficient reclaimed water resources exist within 25 miles of 92 power plants

140 improving future projections of climate and water resources, food production, and ecosystem vulnerab

141 nges to achieving sustainable development of water resources, food, and energy security, as these sec

142 r monsoon (ASM) precipitation is the primary water resource for agriculture in many Asian countries t

143 mplications for the study site (an important water resource for ~500,000 people) and other lakes in t

144 ng the study period, the dependence on green water resources for crop production in China increased,

145 here acid deposition has negatively affected water resources for decades and caused the extirpation o

146 ependence of demographic growth on available water resources for exporting and importing nations.

147 r spill sites; and (4) the overextraction of water resources for high-volume hydraulic fracturing tha

148 the world's natural water towers and provide water resources for millions of people.

149 to assess the impacts of changing climate on water resources for the Alabama-Coosa-Tallapoosa River B

150 ion suggests that, from the point of view of water resource forecasting, climate model development sh

151 This suggested that surface-water resources form passive traps and contribute to the

152 s US to assess the coevolution of humans and water resources from 1790 to 2010.

153 can enter surface, drinking and recreational water resources from aquatic birds.

154 s for almost five decades and persist in our water resources, fruits, vegetables and processed food a

155 irect effects of biofuels on global land and water resources, global ecosystems, air quality, public

156 Technologies to save water and tap new water resources greatly increased energy and infrastruct

157 Due to the scarcity of water resources, growers use deficit irrigation (DI) - w

158 ment (including food availability, and a key water resource), habitat type and seasonal variation (co

159 Management policies for water resources harvesting must be adopted to adapt to c

160 thermore, the economy-oriented allocation of water resources has caused many socio-environmental prob

161 dies of fisheries, forests, and pastoral and water resources have identified many variables that infl

162 alternatives that can reduce GHG emissions, water resource impacts, and energy costs.

163 ter harvesting is utilized as an alternative water resource in buildings, a combination of municipal

164 from 125 shallow wells, a dominant drinking water resource in rural Bangladesh, monitored over a 17

165 Groundwater is a key water resource in semiarid and seasonally dry regions ar

166 n turn might contribute to the protection of water resources in a truly sustainable manner.

167 and migration on land use and transboundary water resources in an active war zone remains a challeng

168 w is important for sustainable management of water resources in an arid area.

169 orld, resulting in contamination of drinking water resources in aquifers as well as eutrophication of

170 The management of water resources in arid and semiarid areas has long been

171 The energy sector is a major user of fresh water resources in China.

172 cal step toward monitoring and investigating water resources in climate-sensitive regions, so the hum

173 whether model-based projections of decreased water resources in dry parts of the region(4) are justif

174 The sustainability of water resources in future decades is likely to be affect

175 s significant impacts on the availability of water resources in other different and often drier regio

176 (HMA) has experienced a spatial imbalance in water resources in recent decades, partly because of a d

177 ven the ongoing impacts of climate change on water resources in SA, awareness of the relationship bet

178 groundwater recharge, which is critical for water resources in semiarid and arid regions.

179 on potential effects from uranium mining on water resources in the area.

180 potranspiration exerted a negative effect on water resources in the Drava basin.

181 Vast water resources in the oceans can only be tapped into if

182 istent snow cover, slow runoff, and increase water resources in the UCRB may represent an important m

183 ty are still inculcated in the management of water resources in the United States (US).

184 oped coastal provinces is largely relying on water resources in the water-scarce northern provinces,

185 This study investigates multiple types of water resources in the western mining area in China, the

186 ng Ancestral Puebloan populations to exploit water resources in unexpected locations.

187 climate variability influences hydrology and water resources in water-limited landscapes.

188 Water resources in western North America depend on winte

189 onmental impacts of shale-gas development on water resources, including methane migration to shallow

190 One potential irrigation water resource is treated wastewater for agricultural fi

191 ination of biological channels, catheters or water resources is a major threat to public health, whic

192 Thus, the biological integrity of global water resources is at a substantial risk.

193 s; therefore, the detection of metal ions in water resources is essential for monitoring health and e

194 Pressure on farm land and water resources is increasing in China due to rising foo

195 stems is practiced in countries with limited water resources; it leads to stagnant periods during whi

196 fuels, metals, minerals, nuclear resources, water resources, land resources, abiotic renewable resou

197 mprove sustainability and reduce pressure on water resources, land, and ecosystem in Iran.

198 eting anions in distilled as well as natural water resources like a sea, lake, and river.

199 ressures that mining expansion has placed on water resources, livelihood assets, and social relations

200 nderstanding Arctic climate, managing Arctic water resources, maintaining the health and livelihoods

201 past CAT implementations in domains such as water resource management and carbon emissions, we outli

202 ervices, is critical for promoting effective water resource management and ensuring the use, safety,

203 M, providing a possible direction for future water resource management and epidemiological studies.

204 Water resource management and governance at the river ba

205 induced changes to rainfall is essential for water resource management and infrastructure design.

206 ble energy storage and conversion as well as water resource management are in the focus of intensive

207 h climate change, poses a great challenge to water resource management globally.

208 has important ecological, biogeochemical and water resource management implications, such as for the

209 havior, which has important implications for water resource management in a warming world.

210 of fiber-optic seismic sensing to facilitate water resource management in semi-arid regions.

211 in streamflow responses poses a challenge to water resource management in the northeastern United Sta

212 use gas concentration scenarios and existing water resource management measures and estimate the time

213 tional constraints, but it requires that the water resource management model is based on an evolution

214 henomena, ranging from cellular exchanges to water resource management or green energy conversion.

215 Finally, operational results for a water resource management system including this model ar

216 a nutrient recovery system on wastewater and water resource management using Laguna de Bay, Philippin

217 fit sustainable green growth in agriculture, water resource management, and coastal ecosystems, as hy

218 l spark up strategic planning, comprehensive water resource management, and extensive treatment schem

219 nto the future, with strong implications for water resource management, food security, ecosystem stud

220 lar importance for effective agriculture and water resource management.

221 variability, have important implications for water resource management.

222 e precipitation measurements are crucial for water resources management, agriculture, weather predict

223 ating these concepts into land use planning, water resources management, and preparations for, and re

224 nsboundary river basin is a complex issue in water resources management.

225 nt Strategies that include nutrient load and water resources management.

226 GWET and BWET, which could lead to improved water resources management.

227 supporting tool in algal bloom monitoring or water-resource management.

228 These findings are useful to water resource managers for adapting to changing climate

229 Water resource managers often tout the potential of pota

230 Water resource managers, early career scientists, and ve

231 certainties to support informed decisions by water resource managers.

232 This insight may assist water-resources managers in alleviating one of the world

233 serves as a blueprint for future large-scale water resource monitoring.

234 ver, management of drinking and recreational water resources needs to be improved by incorporating ef

235 The global occurrence in water resources of organic micropollutants, such as pest

236 precedented pressure on the limited land and water resources of the planet, underpinning concerns ove

237 ences between the electricity grid mixes and water resources of the two regions.

238 ios to quantify the climate change impact on water resources of two contrasting catchments vulnerable

239 sessments of LULC change impacts on climate, water resources or biodiversity.

240 gration allowed sauropods access to food and water resources over a wide region or during times of dr

241 trade has led to enhanced savings in global water resources over time, indicating its growing effici

242 d risk for contamination of shallow drinking water resources, particularly by fugitive gases, because

243 The development of water resources, particularly in Africa, has changed the

244 rgeted adaptation strategies and sustainable water resources planning in the MRCB.

245 Water resources planning requires decision-making about

246 ther, flooding and climate models and inform water resource policies.

247 irrigation and possible changes to existing water resource policy.

248 , the rainfall response may adversely affect water resources, potentially impacting human livelihoods

249 approaches have shown promise for different water resources problems, and they have demonstrated an

250 es, suggesting a high potential for improved water resource projections through hydrological model de

251 High-quality water resources provide a wide range of benefits, but th

252 s before the present, ka) has been linked to water resources provided by large Himalayan river system

253 ing, but there appear to be adequate surface water resources, provided that access is available.

254 m that impair aquatic ecosystem function and water resource quality for society.

255 carbon dioxide (CO2) emissions generated by water resource recovery facilities (WRRFs) during treatm

256 h wastewater processes are currently used in water resource recovery facilities (WRRFs) for required

257 limits on nutrient discharges are motivating water resource recovery facilities (WRRFs) to consider t

258 ological nutrient removal (BNR) processes at water resource recovery facilities (WRRFs) with data-dri

259 emissions from different types of sewers and water resource recovery facilities (WRRFs).

260 energy increase may be especially useful at water resource recovery facilities that already combust

261 In water resource recovery facilities, sidestream biologica

262 al (and recovery as biomass) at an operating water resource recovery facility (WRRF).

263 logies and processes that are needed for the water resource recovery facility of the future.

264 charge it to the Great Lakes Water Authority Water Resource Recovery Facility.

265 The main goals for sustainable water resource recovery include maximizing energy genera

266 ia coli (E. coli) contamination in foods and water resources represents a major threat for human heal

267 er- and polyfluoroalkyl substances (PFAS) in water resources requires a basin-scale approach.

268 erall impact of climate change mitigation on water resources requires accounting for the second part

269 cords provide additional support to Africa's water resources research on hydroclimatic variability an

270 pply energy and environmental impacts at the water resource scale.

271 reduced evapotranspiration will shorten the water resources scarcity period for most monsoon regions

272 iate food demand without compromising future water resources seem critical for the sustainability of

273 they are continuously defiling limited fresh water resources, seriously affecting the terrestrial, aq

274 nmental impacts especially eutrophication on water resources such as lakes.

275 xtreme environment with multiple but limited water resources (such as dew, fog, snow and rain), yet t

276 minant in many regions affected by declining water resources, suggesting a high potential for improve

277 linking climatic and hydrologic processes to water resource supply and demand management and other hu

278 or agricultural water management considering water-resources sustainability criteria.

279 , decision making and organizing sustainable water resource systems.

280 ological drought and warming are shrinking a water resource that supports more than 1 trillion dollar

281 vide a means of exploiting locally available water resources that are currently considered to be unsa

282 ssful management of water infrastructure and water resources that was accomplished largely without in

283 of freshwater supply constraints and saline water resources, the geographic conclusions are similar

284 tural adaptations, such as the management of water resources, the introduction of pastoral lifeways,

285 ting depth and access to deeper nutrient and water resources, thereby impacting climate resilience of

286 the removal of all sorts of pollutants from water resources, thus opening new perspectives for this

287 the long-term vulnerability of mountain snow-water resources to climate change.

288 ncy, however, the capability of its land and water resources to realize this goal is largely unknown.

289 , this suggests that LSLAs often appropriate water resources to the detriment of local users.

290 utole, an emerging contaminant of concern in water resources, under conditions relevant to both natur

291 he development of strategies for sustainable water resource usage, enhancing resilience to extreme ev

292 and Peru) reporting similar contamination in water resources used for agriculture, livestock, and hum

293 sults on the effects of land cover change on water resources vary greatly and the topic remains contr

294 n, in order to evaluate the pressures on the water resources, virtual water flows, and water footprin

295 ely contributed to an increasing scarcity in water resources, which may in turn be endangering food s

296 lead to eutrophication and impaired drinking water resources, while soil erosion reduces water qualit

297 On the supply side, renewable water resources will be affected by projected changes in

298 The contamination of water resources with nitrate is a growing and significan

299 tial risks that shale gas operations pose to water resources, with an emphasis on case studies mostly

300 Eutrophication has threatened water resources worldwide, yet mechanistic understanding