ライフサイエンスコーパス: clean energy

1 vital strategy for renewable and sustainable clean energy.

2 gas (H(2)) represents a potential source of clean energy.

3 ssity to facilitate a fair transition toward clean energy.

4 instruments to accelerate the transition to clean energy.

5 ntial of wind to serve the global demand for clean energy.

6 rategies, to photo- and electrocatalysis for clean energy.

7 r cells, improving performance and advancing clean energy.

8 photoelectrochemical devices and systems for clean energy.

9 multi-objective scheduling optimization for clean energy.

10 efficiently utilize terrestrial emission for clean energy.

11 ly increasing due to the surging demands for clean energy.

12 as bioengineering, flexible electronics, and clean energy.

13 purred the search for alternative sources of clean energy.

14 layer) has been investigated as a source of clean energy.

15 overpotentials holds tremendous promise for clean energy.

16 treating industrial wastewater and producing clean energy.

17 plasmas and aims to deliver sustainable and clean energy.

18 sing candidate in the quest for sustainable, clean energy.

19 eactors holds the promise of sustainable and clean energy(1).

20 ing infectious disease control, facilitating clean energy access, reducing air pollution, tackling ma

21 Thanks to the push for clean energy and advances in characterization capabiliti

22 essential for the sustainable production of clean energy and bulk chemicals, but is still challengin

23 -gases of high importance in the contexts of clean energy and climate alteration, respectively--in ex

24 globally, but also offers a way to generate clean energy and ease the challenges associated with hyd

25 gard to next-generation technologies such as clean energy and environmental sustainability.

26 s to obtain higher catalytic activity toward clean energy and fuel conversion.

27 itting is a promising avenue to sustainable, clean energy and fuel production.

28 The absence of reliable access to clean energy and the services it provides imposes a larg

29 enewables can enable access to decentralised clean energy and, coupled with interventions to increase

30 he most effective and sustainable carrier of clean energy, and liquid-phase hydrogen storage material

31 e manufacturing practices in EDM in terms of clean energy, and responsible consumption and production

32 sing water oxidation catalysts for practical clean energy application.

33 ogen from methane and light hydrocarbons for clean energy applications remains a technical challenge

34 evices, such as sensors and photovoltaics or clean energy applications such as hydrogen production.

35 has great potential for use in aerospace and clean energy applications, but its supply is currently l

36 Molten salts are crucial for clean energy applications, yet exploring their thermophy

37 torage is in high demand for next-generation clean energy applications.

38 inide complexes are critical for a wealth of clean-energy applications.

39 Adoption studies of ICSs or clean energy are scarce, scattered, and of differential

40 pulation, disadvantaged by lack of access to clean energy, are exposed to high levels of indoor air p

41 To make clean energy available to all people is the long-term go

42 sence of heavy metals, as well as the use of clean energy, available oxidant, and a common solvent ar

43 ugh electrocatalysis holds great promise for clean energy, but its large-scale application relies on

44 But a full transition to clean energy can only be realized if numerous challenges

45 The clean energy carrier, hydrogen, if efficiently produced

46 onal design of new electrocatalysts for both clean energy conversion and green oxidizer production.

47 ign and synthesis of COF-based catalysts for clean energy conversion and storage are presented.

48 sis of noble-metal-free electrocatalysts for clean energy conversion applications; however, there are

49 lution reaction (OER) is a key bottleneck in clean energy conversion due to sluggish kinetics and hig

50 rd a better understanding of a series of key clean energy conversion reactions including oxygen reduc

51 Today sustainable and clean energy conversion strategies are based on sunlight

52 Electrocatalysis plays a central role in clean energy conversion, enabling a number of sustainabl

53 ovide an overview of applications of REEs in clean energy conversion, especially their use as next-ge

54 major applications to organic reactions and clean energy-conversion systems.

55 % below 2005 levels by 2035 with accelerated clean energy deployment.

56 c viability of low temperature fuel cells as clean energy devices is enhanced by the development of i

57 nge membranes (AEMs) play a critical role in clean energy devices, and optimizing their performance r

58 regenerative fuel cells, and other important clean energy devices.

59 regenerative fuel cells, and other important clean energy devices.

60 ogies ranging from printable organs to novel clean energy devices.

61 Efficient and practical clean-energy devices for electrochemical or photoelectro

62 global and U.S. domestic effort to develop a clean energy economy and curb environmental pollution in

63 (CO(2)RR) is a promising technology for the clean energy economy.

64 orld's all-purpose power from wind in a 2030 clean-energy economy.

65 Hydrogen is increasingly being discussed as clean energy for the goal of net-zero carbon emissions,

66 In the effort to generate sustainable clean energy from abundant resources such as water and c

67 reen technologies to provide clean water and clean energy from abundantly available renewable resourc

68 obes provide a platform for the synthesis of clean energy from renewable resources.

69 nologies essential to a circular economy and clean energy future.

70 hemical performance, aiming at an affordable clean energy future.

71 In the transition to a clean-energy future, CO2 separations will play a critica

72 , to boost its storage capacity toward these clean energy gases.

73 These energy sources, often referred to as "clean energy", generate no operational onsite GHG emissi

74 oaches in support of DOE missions related to clean energy generation and environmental characterizati

75 actively pursued owing to its importance in clean energy generation and storage.

76 One prospective method of clean energy generation is the electrochemical hydrogen

77 A LIFE-based fleet of power plants promises clean energy generation with no greenhouse gas emissions

78 ogress towards a sustainable future based on clean energy generation, transmission and distribution,

79 ields from catalysis to electrochemistry and clean energy generation.

80 sion' was publicly heralded as the future of clean energy generation.

81 eir full potential and aligning with broader clean energy goals.

82 mploying renewable materials for fabricating clean energy harvesting devices can further improve sust

83 lling alternatives to liquid electrolytes in clean energy-harvesting and -storage technologies.

84 on emissions, the demand for sustainable and clean energy has now become more important than ever.

85 Generation of clean energy in a viable manner demands efficient and su

86 lements (REEs) are critical to high-tech and clean-energy industries; however, their bioavailability

87 lts underscore that environmental impacts of clean energy infrastructure merit scrutiny to ensure tha

88 mperative for the sustainable development of clean energy initiatives.

89 ion conditions with excellent efficiency and clean energy input.

90 ord high of 10.5% in 2021 (indicator 3.1.1); clean energy investment exceeded fossil fuel investment

91 In addition, although clean energy investment grew by 10% globally in 2023-exc

92 Supporting this, global clean energy investment increased by 15% in 2022, to $1.

93 Clean energy investment is 38% lower than fossil fuel sp

94 -harvesting is crucial to the development of clean energy materials and devices.

95 and cryogenic electron microscopy in probing clean-energy materials are presented and emerging opport

96 a is experiencing a rapid transition towards clean energy, nevertheless, solid fuel combustion remain

97 in the development of, access to, and use of clean energy, only 2.3% of electricity in low HDI countr

98 ic SDG targets, such as increasing access to clean energy or improving health outcomes, rather than e

99 ation and demand lead to underutilization of clean energy, particularly in industrial parks with over

100 Clean energy plans must include safer, more sustainable,

101 are one of the most prevalent and impactful clean energy policies implemented by states in the Unite

102 Despite the continent's clean energy potential, electric vehicle adoption faces

103 anic synthesis, as well as those involved in clean energy processes such as production of hydrogen an

104 rodes are essential for many devices used in clean energy production and consumer electronics.

105 ations, as wastewater treatment coupled with clean energy production and power supply systems for iso

106 fossil-fuel technologies has revolutionized clean energy production using fuel cells.

107 efficiency, and durability is desirable for clean energy production.

108 ing the demand for sustainable approaches to clean-energy production and waste recycling.

109 lude by extending this framework to emerging clean energy reactions such as hydrogen peroxide product

110 Our findings highlight the importance of clean energy replacements in multiple sectors on achievi

111 arbon products is an important challenge for clean energy research.

112 ecessary for the development of sustainable, clean energy resources and to avoid nuclear pollution.

113 introduces a novel and efficient method for clean energy scheduling optimization by integrating PSO

114 ng optimization and a mathematical model for clean energy scheduling optimization is constructed.

115 mplexity and uncertainty challenges faced in clean energy scheduling within the current power system,

116 ghly regulated worldwide, and we confirm the clean energy sector as an unrecognized and potentially g

117 n bolster sustainable agriculture and expand clean energy services.

118 A comprehensive programme for clean energy should optimise mitigation and, simultaneou

119 he most aggressive plausible transition to a clean-energy society provides benefits for climate chang

120 ve high energy densities and are crucial for clean energy solutions.

121 o address the challenges posed by delivering clean energy solutions.

122 value added that is held by the co-produced clean energy source (syngas).

123 Harnessing solar power as a clean energy source requires the continuous development

124 e interest for their potential in developing clean energy sources and storage technologies.

125 The randomness and volatility of existing clean energy sources have increased the complexity of gr

126 Providing stable and clean energy sources is a necessity for the increasing d

127 ilitating public engagement around potential clean energy sources.

128 ts, nuclear reactors, nuclear waste systems, clean energy sources.

129 change mitigation effects when combined with clean energy sources.

130 an urgent task to develop the renewable and clean energy sources.

131 Clean energy spending in these countries only accounted

132 Although they hold the promise of clean energy, state-of-the-art fuel cells based on polym

133 talysts in supercapacitors and batteries for clean energy storage as well as in air/water treatments

134 feedstocks offers an attractive strategy for clean energy storage by directly utilizing solar energy,

135 nd demonstrates its promising application in clean energy storage.

136 critical for informing regional economic and clean energy strategies.

137 hemicals becomes a significant challenge for clean energy studies.

138 d stability under different load demands and clean energy supply conditions.

139 n electrochemistry, thus boosting the entire clean energy system.

140 to meet many analytical challenges in future clean energy systems and environmental management.

141 construction and maintenance of reliable and clean energy systems around the world.

142 oxide materials, ranging from catalysts and clean energy systems to emerging multifunctional devices

143 ustrate the ability of AI to power cheap and clean energy systems.

144 Electrocatalysts are required for clean energy technologies (for example, water-splitting

145 We further underscore the associated clean energy technologies and a sustainable nitrogen-bas

146 reactivity of molecular oxygen is crucial to clean energy technologies and green chemical synthesis,

147 e in the recovery and utilization of REEs in clean energy technologies and provide perspectives for e

148 der implications for the adoption of similar clean energy technologies and related policy challenges

149 The rapid growth of clean energy technologies is driving a rising demand for

150 ed that deployment of a diverse portfolio of clean energy technologies makes a transition to a low-ca

151 ments (REEs) are critical resources for many clean energy technologies, but are difficult to obtain i

152 ic-electronic conducting (MIEC) membranes in clean energy technologies, i.e., oxyfuel combustion, cle

153 chemical reactions are crucial for desirable clean energy technologies, including advanced water elec

154 f this conversion has inspired the design of clean energy technologies, including solar cells and pho

155 anthanide series, are key components of many clean energy technologies, including wind turbines and p

156 uction of oxygen is important for developing clean energy technologies, such as fuel cells, and is vi

157 rare earth elements (REEs) in many emerging clean energy technologies, there is an urgent need for t

158 ch as utilizing renewable energy sources and clean energy technologies, we can mitigate the adverse i

159 trategy to craft materials for renewable and clean energy technologies.

160 highly efficient carbon-based catalysts for clean energy technologies.

161 erials (CMM) due to their essential roles in clean energy technologies.

162 critical minerals that are indispensable for clean energy technologies.

163 ce electrocatalysts are important to advance clean energy technologies.

164 , we must rapidly displace fossil fuels with clean energy technologies.

165 erphase and define reaction kinetics of many clean energy technologies.

166 ive and durable catalysts play a key role in clean energy technologies.

167 recious Pt catalysts holds great promise for clean energy technologies.

168 e to cope with the significant challenges of clean energy technologies.

169 e both domestic mining growth and affordable clean energy technologies.

170 igh temperatures are at the core of thriving clean-energy technologies.

171 tteries limit the commercialization of these clean-energy technologies.

172 Fuel cells as an attractive clean energy technology have recently regained popularit

173 nts (REEs) are critical to multiple areas in clean energy technology, including magnets, catalysts, a

174 stainable development goal of affordable and clean energy, there has been a growing need for low-cost

175 oughs across technological applications from clean energy to information processing(1-11).

176 shore wind power offers a new option for the clean energy transition of the power sector in China's c

177 The global clean energy transition requires the development of alte

178 The clean energy transition will require a vast increase in

179 zation process may have implications for the clean energy transition, CO(2) storage and utilization,

180 For this clean energy transition, the versatile green ammonia may

181 gmatites is rapidly expanding to support the clean energy transition, yet associated water-quality im

182 2e) emissions as hydrogen use rises during a clean energy transition.

183 challenges and potential threats in China's clean-energy transition.

184 The clean energy transitions result in remarkable reductions

185 esearch shows how this Framework can address clean energy transitions, strengthen emerging industries

186 These proposals include separately targeting clean energy uptake and demand-side efficiency in indivi

187 It contributes to the overall improvement of clean energy utilization within the State Grid and provi

188 cate that this method significantly improves clean energy utilization, increasing it from 62.4% (with

189 N) to enhance grid scheduling efficiency and clean energy utilization.

190 Rivers provide unrivaled opportunity for clean energy via hydropower, but little is known about t