ライフサイエンスコーパス: renewable

1 ed scenarios largely involve natural gas and renewables.

2 ncy, demand response, and the integration of renewables.

3 s of electricity from coal, natural gas, and renewables.

4 y that can help spur large-scale adoption of renewables.

5 and HNO(3)-treated ACFCs were effective and renewable adsorbents for low-concentration Hg(0) adsorpt

6 s efficient for increasing the production of renewable alkanes via synthetic biology-based approaches

7 uels are a promising ecologically viable and renewable alternative to petroleum fuels, with the poten

8 conomic and environmental competitiveness of renewable alternatives relative to conventional generati

9 om whiteness to transparency, using the same renewable and biodegradable building blocks.

10 bioinspired strategy to craft materials for renewable and clean energy technologies.

11 is unique ion regulation capability with the renewable and cost-effective raw materials available, wo

12 ripotent stem cells (hPSCs) provide a highly renewable and genetically defined cell source, but effic

13 Variable renewable and natural gas technologies account for nearl

14 Increasing shares of renewable and natural gas technologies in future nationa

15 ter adaptation, as economic drivers increase renewable and natural gas-based capacity, while water-in

16 s growing awareness of climate change, novel renewable and naturally sourced materials have received

17 The cell-based glycan array is self-renewable and reports glycosyltransferase genes required

18 Research toward renewable and sustainable energy has identified specific

19 ocatalysts presents a promising platform for renewable and sustainable energy.

20 ergy economy to one that is supplied by more renewable and sustainable materials.

21 c growth is epitomized by the development of renewable and unconventional energy, whose adoption is a

22 prospects for the widespread penetration of renewables and extensive power-sector decarbonization th

23 he resultant wind deployment displaces other renewables, and thus has a negligible effect on CO(2) em

24 lyzer and increased availability of variable renewables appear not to be key factors in whether elect

25 ing trend, we conclude that an investment in renewables at a level consistent with meeting 80% of pro

26 hout carbon emission from H(2) obtained from renewables at small units operated at lower pressure.

27 ularly true in the search for sustainable or renewable aviation fuels.

28 Here we introduce a renewable barcoding system to observe evolutionary dynam

29 -renewables case) with close to one third of renewables being curtailed.

30 rnative SPEs fabrication procedures based on renewable, biocompatible sources or waste materials, suc

31 s are valuable information for the future of renewable biofuel development and their applicability in

32 synthesize novel valuable molecules such as renewable biofuels or anticancer drugs.

33 eal metabolic engineering projects producing renewable biofuels, hoppy flavored beer without hops, fa

34 c biomass bodes well for full utilization of renewable biomass feedstocks.

35 In contrast with fossil resources, renewable biomass is a virtually inexhaustible reservoir

36 In this work, a low cost, green and renewable biomass resource is utilised for the high yiel

37 ds is a key step for catalytic conversion of renewable biomass to hydrocarbon feedstocks.

38 promising technology for the valorization of renewable biomass to sustainable advanced fuels and fine

39 cellulose, which is one of the most abundant renewable biomaterials in nature.

40 nd a promising resource for the synthesis of renewable bioproducts from atmospheric CO2 Growth and me

41 Trees as the most abundant renewable bioresource have attracted significant attenti

42 gradation is central to the carbon cycle and renewable biotechnologies.

43 self-powered sensor networks and large-scale renewable blue energy.

44 ent configurations of storage additions, new renewable capacity, and carbon prices.

45 rbon dioxide offers an accessible, cheap and renewable carbon feedstock for synthesis.

46 Lignocellulosic biomass offers a renewable carbon source which can be anaerobically diges

47 cular consumption of plastics and to produce renewable carbon-neutral monomers.

48 These renewable carboxylic acids are involved in the synthesis

49 ves 72% CO(2) reductions (relative to a zero-renewables case) with close to one third of renewables b

50 The generation of pancreatic cell types from renewable cell sources holds promise for cell replacemen

51 Among the least renewable cells in the human body, CMs renew approximate

52 technology is to become a viable option for renewable chemical and fuel production.

53 extracted on commercial scales, and serve as renewable chemical feedstocks and building blocks(2,3),

54 he breakdown of lignocellulosic biomass into renewable chemical precursors that could form the basis

55 ch with the aim of converting electricity to renewable chemicals and fuels.

56 penes and their derivatives are sustainable, renewable chemicals that can be used as a complementary

57 anthropogenic climate change while creating renewable chemicals.

58 , demonstrating the feasibility of upcycling renewable chitin-containing waste into value-added NCCs

59 Here we show if cost trends for renewables continue, 62% of China's electricity could co

60 a cost optimization model, here we show that renewables could provide a source of power cheaper or at

61 ial of energy storage technologies to reduce renewable curtailment and CO(2) emissions in California

62 renewable penetrations with as little as 9% renewable curtailment.

63 emissions reductions with as little as 0.3% renewable curtailment.

64 to 54% emissions reductions with close to 3% renewable curtailment.

65 In Texas, the same renewable-deployment level leads to 54% emissions reduct

66 biofuel production to 20.8 billion liters of renewable diesel annually without significant water-stre

67 hydrogels are biocompatible, biodegradable, renewable, easy to obtain, inexpensive, and non-toxic.

68 ime shipping, and aviation and the growth of renewable electricity and storage on the grid.

69 atalysis include the possible utilization of renewable electricity as an electron source and high ene

70 enewable methane, obtained via CO(2)RR using renewable electricity as energy input, has the potential

71 tial to offset a significant fraction of non-renewable electricity demands globally, yet it may occup

72 ectricity exchanges makes the integration of renewable electricity easier, importing electricity may

73 orical overlap occurs in Western Europe, the renewable electricity facilities under development incre

74 d, and on-site electrolysis cells powered by renewable electricity generated from solar or wind sourc

75 os of different combinations of PHEV uptake, renewable electricity generation shares, and PHEV fuelin

76 Currently hydropower dominates renewable electricity generation, accounting for two-thi

77 With the expected rapid growth of renewable electricity generation, charging plug-in hybri

78 climate change demands a transition towards renewable electricity generation, with wind power being

79 remain as a feasible alternative powered by renewable electricity instead of fossil energy.

80 cal CO(2) reduction reaction (CO(2) RR) with renewable electricity is a potentially sustainable metho

81 ia from nitrogen under mild conditions using renewable electricity is an attractive alternative(1-4)

82 efficiencies need to reach at least 60%, and renewable electricity prices need to fall below 4 cents

83 approach in mitigating the intermittency of renewable electricity production.

84 trochemical CO(2) reduction (ECR) powered by renewable electricity provides an attractive approach be

85 In the future, as other renewable electricity sources become more important, ele

86 d is thus an important step toward realizing renewable electricity storage through long-lived organic

87 Harnessing renewable electricity to drive the electrochemical reduc

88 ytic reduction of carbon dioxide, powered by renewable electricity, to produce valuable fuels and fee

89 al cement process could be powered solely by renewable electricity.

90 ising avenue for the storage of intermittent renewable electricity.

91 vides an attractive avenue to the storage of renewable electricity.

92 Synthetic fuels derived from renewable energies can act as energy storage media, thus

93 cations have been envisioned in the field of renewable energies, telecommunications, and quantum elec

94 Among renewable energies, wind and solar are inherently interm

95 on for the long-term storage of intermittent renewable energies.

96 h can be used to produce hydrogen fuel using renewable energies.

97 y is therefore of substantial importance for renewable energy applications.

98 Furthermore, intermittent renewable energy can easily power the brine utilization

99 s, which will have broad implications in the renewable energy catalysis and electrosynthesis of valua

100 ef overview of various reactions involved in renewable energy conversion and storage, including the o

101 e focus this review on the impacts of marine renewable energy devices (MREDs) on underwater marine or

102 nique materials to various fields, including renewable energy devices and ultrafast sensors.

103 Implementation of the European Union Renewable Energy Directive has triggered exponential gro

104 Coordinated planning of renewable energy expansion and biodiversity conservation

105 However, renewable energy facilities can be land-use intensive an

106 We identified 2,206 fully operational renewable energy facilities within the boundaries of the

107 Use of renewable energy for charging and operation, ease of com

108 device as it demonstrates the generation of renewable energy from microalgae; however, inadequate el

109 rowing need to store an increasing amount of renewable energy in a sustainable way has rekindled inte

110 ss with renewed interest for storing surplus renewable energy in the form of methane.

111 sess the extent of current and likely future renewable energy infrastructure associated with onshore

112 a promising platform molecule for the future renewable energy infrastructure owing to its high energy

113 Second, this next wave of renewable energy infrastructure represents a ~30% increa

114 ciently produced by water electrolysis using renewable energy input, would revolutionize the energy l

115 There is growing concern that large renewable energy installations will displace other land

116 duction of carbon dioxide (CO(2)) powered by renewable energy is an attractive sustainable approach t

117 Transitioning from fossil fuels to renewable energy is fundamental for halting anthropogeni

118 becoming increasingly critical to balancing renewable energy production and consumption(1).

119 promoting the development of cost-effective renewable energy production and conversion devices.

120 increase as more mines target materials for renewable energy production and, without strategic plann

121 Renewable energy production is necessary to halt climate

122 Change (IPCC) Special Report predicted that renewable energy production must leap from [Formula: see

123 ning areas (82%) target materials needed for renewable energy production, and areas that overlap with

124 l rice bran oil with high economic value for renewable energy production.

125 ive research frontier in a wide range of key renewable energy reactions and devices.

126 O(2) ) is attractive within the context of a renewable energy refinery.

127 across the U.S. and determine the amount of renewable energy required to offset the CO2 emissions re

128 ttracted extensive attention in the field of renewable energy research because of their remarkable ef

129 obal climate models to scales sufficient for renewable energy resource assessment.

130 We conclude with a super-resolution study of renewable energy resources based on climate scenario dat

131 Halide perovskites are revolutionizing the renewable energy sector owing to their high photovoltaic

132 Biogas is a renewable energy source composed of methane, carbon diox

133 eliability, availability, and quality of the renewable energy source.

134 vest the coldness from the universe as a new renewable energy source.

135 of smart textiles for harvesting energy from renewable energy sources on the human body and its surro

136 and can be directly coupled with distributed renewable energy sources such as wind and solar.

137 ectricity sector, as they can counterbalance renewable energy sources' intermittency and provide grid

138 Despite efforts to develop renewable energy sources, coal use has not declined on a

139 s is needed to mitigate the intermittency of renewable energy sources.

140 uld provide a means to produce biofuels from renewable energy sources.

141 cient and that can be easily integrated with renewable energy sources.

142 scalable technologies for making fuels using renewable energy sources.

143 e strategies to produce chemical fuels using renewable energy sources.

144 rcoming the intermittency and variability of renewable energy sources.

145 storage of energy produced intermittently by renewable energy sources.

146 The intimately related issue of renewable energy storage is being addressed with new str

147 olytic reactions that can potentially enable renewable energy storage, including water, CO(2) and N(2

148 O is important for long-term and large-scale renewable energy storage.

149 volution reaction (OER) is a key process for renewable energy storage.

150 mands stemming from consumer electronics and renewable energy systems have pushed researchers to stri

151 icient carbon-based metal-free catalysts for renewable energy technologies and beyond.

152 Electrocatalysts are key for renewable energy technologies and other important indust

153 perceived as environmentally benign, 'green' renewable energy technologies have ecological costs that

154 lysts and its increasing use in emerging and renewable energy technologies such as fuel cells and ele

155 he oxygen evolution reaction (OER) is key to renewable energy technologies such as water electrolysis

156 The practical scale-up of renewable energy technologies will require catalysts tha

157 rals to the electrodes of bioelectrochemical renewable energy technologies.

158 ctrocatalysis and plays an important role in renewable energy technologies.

159 proved and precious metal-free catalysts for renewable energy technologies.

160 It is crucial for leaping forward renewable energy technology to develop highly active oxy

161 orld continues to rapidly transition towards renewable energy these areas will face increasing pressu

162 emical feedstocks, which uses both CO(2) and renewable energy(3-8).

163 d States with respect to using fossil fuels, renewable energy, and nuclear energy?

164 RFBs) could enable widespread integration of renewable energy, but only if costs are sufficiently low

165 ls, such as hydrocarbons and alcohols, using renewable energy, but the efficiency of the process is l

166 aterials in biomedicine, tissue engineering, renewable energy, environmental science, nanotechnology

167 hydropower is a potentially clean source of renewable energy, some projects produce high greenhouse

168 a pivotal reaction in many technologies for renewable energy, such as water splitting, metal-air bat

169 splitting as the best solution for clean and renewable energy, the worldwide efforts for development

170 an health impacts compared to those with low renewable energy, while inducing a more pronounced shift

171 es are an important technological option for renewable energy-based decarbonization of the electricit

172 cells have emerged as promising, potentially renewable energy-based, energy conversion technologies f

173 nodules using artificial devices can enable renewable energy-driven fertilizer production.

174 of OER electrocatalysts for applications in renewable energy-related devices.

175 for producing clean chemicals and utilizing renewable energy.

176 ant to using ammonia to store and distribute renewable energy.

177 achieved with high penetrations of variable renewable energy.

178 ortance in many fields such as catalysis and renewable energy.

179 could provide a critically needed source of renewable energy.

180 the major challenges of electrocatalysis for renewable energy.

181 have hindered the large-scale development of renewable energy.

182 at importance in realising a future based on renewable energy.

183 ncrease in the production of sustainable and renewable energy.

184 energy storage is fundamental to the use of renewable energy.

185 ne of the promising candidates for clean and renewable energy.

186 ls have developed into a promising branch of renewable energy.

187 rial fields, such as catalysis, sensing, and renewable energy.

188 roducing valuable multi-carbon products from renewable energy.

189 lectrocatalytic processes is central to many renewable-energy initiatives.

190 Lignin, one of the most abundant renewable feedstock, is used to develop a biocompatible

191 ing catalytic iridium; thus, inexpensive and renewable feedstocks are utilized in the formation of co

192 years, the biosynthesis of adipic acid from renewable feedstocks has been demonstrated using both ba

193 rogenation of higher alcohols available from renewable feedstocks is also described.

194 Production of platform chemicals from renewable feedstocks is becoming increasingly important

195 biosynthesis processes for optimal biofuels, renewable feedstocks, and medical studies in health and

196 ot limited to the use of naturally abundant, renewable feedstocks, solvents, metal catalysts, energy,

197 hesives will be made from benign, cheap, and renewable feedstocks.

198 s been proposed as an approach for producing renewable fertilizers and reducing nutrient loads to was

199 gen reduction is a critical half reaction in renewable fuel cell development and a key step in the de

200 new avenues for sustainable, practical, and renewable fuel production through biomass valorization.

201 ng routes to produce hydrogen as a clean and renewable fuel source.

202 The Renewable Fuel Standard (RFS) program specifies a greenh

203 current yield levels is unlikely to meet the Renewable Fuel Standard emissions reduction threshold fo

204 ne of the most crucial challenges to produce renewable fuel.

205 ignocellulosic biomass for the production of renewable fuels and chemicals, as well as for forage.

206 yield.Bio-oil is a potential major source of renewable fuels and chemicals.

207 ing lignocellulosic biomass to produce green renewable fuels and high-value chemicals pretreats the b

208 ount for approximately 16 billion gallons of renewable fuels by the year 2022, contributing significa

209 The synthesis of renewable fuels from abundant water or the greenhouse ga

210 y relevant for industries seeking to produce renewable fuels from lignocellulosic biomass.

211 es offer the promise of zero-carbon-emission renewable fuels needed for heavy-duty transportation.

212 entally friendly production of chemicals and renewable fuels.

213 The route commences from a renewable furan starting material and features a number

214 s continues to be a promising technology for renewable generation of energy.

215 d into the electricity grid to firm variable renewable generation, increasing the efficiency and effe

216 on of global, crop-specific estimates of non-renewable groundwater abstraction and international food

217 ytic transformation of CO(x) (x = 1, 2) with renewable H(2) into valuable fuels and chemicals provide

218 r-splitting cycle that simultaneously drives renewable H(2) production and DAC of CO(2) is demonstrat

219 ansfer in enzymes and benchmarks for a fully renewable H(2) technology, [FeFe]-hydrogenases behave as

220 oduced from carbon dioxide using sustainable renewable hydrogen and energy.

221 However, renewable hydrogen production is expensive and in limite

222 Incorporating renewable identification number (RIN) values advantages

223 ils are valuable commodities for food, feed, renewable industrial feedstocks and biofuels.

224 puts capable of being substituted with local renewable inputs were replaced in a hypothetical scenari

225 amount of energy storage that is needed for renewable integration.

226 oeconomy depends on increased utilization of renewable lignocellulosic biomass.

227 cal reduction of CO2 to ethanol, a clean and renewable liquid fuel with high heating value, is an att

228 to biofuels is a promising route to provide renewable low-carbon fuels, based on a low- or negative-

229 These devices are made from easily sourced renewable materials for fabrication while exhibiting all

230 Renewable methane, obtained via CO(2)RR using renewable

231 s, and solar cells are central to powering a renewable, mobile, and electrified future.

232 A combination of feasible manufacturing and renewable modules can offer an attractive advancement to

233 t flow-assisted organization and assembly of renewable native cellulose nanofibrils (CNFs), which yie

234 ric proanthocyanidins (OPACs) are potent and renewable natural bioactives possible to be refined into

235 aerobic digestion (AD) for the production of renewable natural gas (RNG), and dry AD with electricity

236 s used to remove these proteins but is a non-renewable natural material and reduces wine volume due t

237 Chitin is the most abundant renewable nitrogenous material on earth and is accessibl

238 esis macrocyclization and the ethenolysis of renewable oils.

239 able from methane or CO(2), is a potentially renewable one-carbon (C1) feedstock for microorganisms.

240 nd, allow 90% CO(2) reductions from the same renewable penetrations with as little as 9% renewable cu

241 sed to inform the development of an extended renewable portfolio standard in North Carolina.

242 s, a hypothetical CO(2) cap, and an extended renewable portfolio standard.

243 ction on air quality, vehicle emissions, and renewable portfolio standards, taking into account racia

244 rough day-night cycles, offering a clean and renewable power source with self-sustaining potential.

245 promising way to store energy produced from renewable power sources, can be converted into electrica

246 ow that the energy deficit in a future fully renewable production from wind power, hydropower, and ge

247 en illuminated by light, these QDs drive the renewable production of different biofuels and chemicals

248 Renewable production of fuels and chemicals from direct

249 c analysis of the integrated process for the renewable production of H(2), O(2), and electricity, as

250 Renewable production of Mfp proteins and the facile fabr

251 policymakers designing energy efficiency and renewable programs, regulators enforcing emissions stand

252 pecially attractive, as it is based on cheap renewable raw materials and often exhibits advantages in

253 The utilisation of renewable resource along with facile microwave treatment

254 , environmental friendly and a very valuable renewable resource.

255 China should promote renewable resources and energy, pursue a low-carbon life

256 forts to synthesize degradable polymers from renewable resources are deterred by technical and econom

257 Understanding why some renewable resources are overharvested while others are c

258 lly competitive and low-environmental-impact renewable resources can significantly contribute to meet

259 on of syngas with tunable CO/H(2) ratio from renewable resources is an ideal way to provide a carbon-

260 ronmentally friendly lubricants derived from renewable resources is highly desirable for many practic

261 ure and conversion, along with hydrogen from renewable resources, provide an alternative approach to

262 kely outcomes for many cooperatively managed renewable resources, which implies that achieving conser

263 PLA) is an FDA-approved polymer derived from renewable resources.

264 Only 14.66% of all inputs were considered "renewable," resulting in a moderate mean environmental l

265 the semiconductor/liquid interface provide a renewable route of mimicking natural photosynthesis and

266 bon-based nanoparticles produced by low-cost renewable routes that are bioavailable to mature plants.

267 ble (wind farms, run-of-river hydro) and non-renewable (shale gas) sources in British Columbia (BC),

268 al thermal radiation that is as large as the renewable solar energy.

269 th in situ extraction using the abundant and renewable solvent supercritical carbon dioxide (scCO(2))

270 d pluripotent stem cells (iPSCs) to create a renewable source for human induced pluripotent stem cell

271 is an attractive strategy for storing such a renewable source of energy into the form of chemical ene

272 es with contemporary primary production as a renewable source.

273 ment of technology for their production from renewable sources and efforts to promote their efficient

274 e composite biomaterials, made entirely from renewable sources and with promising applications in fie

275 r synthesis involve using molecules from bio-renewable sources as a basis for both the anionic and ca

276 n dioxide (CO(2))-emitting fossil fuels with renewable sources have driven interest in chemical stora

277 ble economy of the Earth's resources and for renewable sources of energy, a promising avenue is to ex

278 e storage of energy produced by intermittent renewable sources(1).

279 le gas are 1000 times higher than those from renewable sources, and run-of-river hydro has high overl

280 can be powered by electricity produced from renewable sources.

281 systems for energy storage from intermittent renewable sources.

282 ports and alternative natural materials from renewable sources.

283 systems to produce fuels and chemicals with renewable sources.

284 Large-scale CO2 hydrogenation could offer a renewable stream of industrially important C1 chemicals

285 ts of technologies and policies that enhance renewable systems integration.

286 ccelerate the implementation of policies for renewable technologies, while efficiency improvements ar

287 utum), an economically important species for renewable textile fiber production.

288 e long been cultivated worldwide for natural renewable textile fibers.

289 t can be considered environment friendly and renewable to prepare nanoparticles of carotenoids.

290 that without energy storage, adding 60 GW of renewables to California achieves 72% CO(2) reductions (

291 ered an important component, alongside other renewables, to mitigate global warming and to reduce fos

292 compounds and processes are depleting versus renewable, toxic versus benign, and persistent versus re

293 numerous fields, including petroleomics and renewable transportation fuels, but difficult to achieve

294 Using projections of renewable water availability and irrigation water demand

295 al virtual water trading and find trading of renewable water sources may triple by 2100 while nonrene

296 four times more water than its total annual renewable water, with large variations in food-energy-wa

297 ction and future electricity generation from renewable (wind farms, run-of-river hydro) and non-renew

298 s for a future Indian power economy in which renewables, wind and solar, could meet 80% of anticipate

299 ng interest in capturing H(2) generated from renewables with CO(2) to produce methanol.

300 ple to perform and analyze, inexpensive, and renewable, with unprecedented depth of coverage for subs