ライフサイエンスコーパス: solar energy

1 directly into the desired end product using solar energy.

2 engineering molecular antenna for harvesting solar energy.

3 r the simultaneous conversion and storage of solar energy.

4 energy via the collection of low-temperature solar energy.

5 quired for the large-scale implementation of solar energy.

6 nerate hydrogen efficiently from water using solar energy.

7 most important routes for the utilization of solar energy.

8 ues to use the huge amount of waste heat and solar energy.

9 ater splitting for hydrogen production using solar energy.

10 water are converted into chemical fuels from solar energy.

11 resolved in order to take full advantage of solar energy.

12 new strategies to improve the utilization of solar energy.

13 ental-friendly production of H2 by utilizing solar energy.

14 s due to the compelling prospect of low-cost solar energy.

15 al energy generated by renewable wind and/or solar energy.

16 mising alternative for dye degradation using solar energy.

17 ire a portion of their electricity come from solar energy.

18 re relevant to the conversion and storage of solar energy.

19 ds economical photovoltaic conversion of the solar energy.

20 elop clean syngas production using renewable solar energy.

21 plitting is a promising approach for storing solar energy.

22 hemically stable and can efficiently capture solar energy.

23 liquid hydrocarbon fuels using concentrated solar energy.

24 rop plants could expand their ability to use solar energy.

25 About 50% of the solar energy absorbed at the Earth's surface drives evap

26 er year to the atmosphere, using half of all solar energy absorbed by land surfaces in the process.

27 brookite nanoparticles, which increases the solar energy absorption and enhances the photocatalytic

28 Plants capture solar energy and atmospheric carbon dioxide (CO2) throug

29 life cycle CO2 emissions is only found when solar energy and atmospheric CO2 are used.

30 nd some of their topical applications in the solar energy and biological fields.

31 citons enables applications in harvesting of solar energy and biological imaging.

32 These bacteria began to convert solar energy and carbon dioxide into bioenergy and oxyge

33 Artificial photosynthetic systems can store solar energy and chemically reduce CO2 We developed a hy

34 into a single photoelectrode, which converts solar energy and CO2 directly into reduced carbon specie

35 play an important role in the absorption of solar energy and hence direct radiative forcing (DRF), l

36 of dark forests increases the absorption of solar energy and increases surface temperature, particul

37 t due to its capacity to efficiently harvest solar energy and its potential to solve the global energ

38 ical applications, such as the harvesting of solar energy and molecular electronics.

39 e consists of antenna complexes that harvest solar energy and reaction centres that convert the energ

40 ch for renewable production of hydrogen from solar energy and requires interfacing advanced water-spl

41 promising techniques to utilize the abundant solar energy and sea water or other unpurified water thr

42 ctrochemically oxidized to I3(-), harvesting solar energy and storing it as chemical energy.

43 of cyanobacteria and rhodophyta that harvest solar energy and transport it to the reaction center.

44 etwork of pigment-protein complexes captures solar energy and transports it to the reaction center, w

45 trum of visible light ( approximately 50% of solar energy) and achieve highly efficient water disinfe

46 light, which represents only 4% of the total solar energy, and this leads to a slow treatment speed.

47 id materials currently under development for solar energy applications in dye or quantum dot-sensitiz

48 describe a novel strategy for dye-sensitized solar energy applications in which redox-separated lifet

49 ics, semiconductors, biomedical sensors, and solar energy applications.

50 portance, particularly in photochemistry and solar energy applications.

51 ffer promising features for potential use in solar energy applications.

52 al antenna could provide inspiration for new solar energy applications.

53 iological systems that can capture and store solar energy are rich in a variety of chemical functiona

54 e for improvements with no precedents in the solar energy arena.

55 covery presents a new range of materials for solar-energy-based molecular transduction.

56 ted promise for terawatt-scale deployment of solar energy because of its low-cost, solution-based pro

57 the new gateway to enhance the absorption of solar energy beyond the so called Yablonovitch Limit.

58 ith a trickle-charge of photosynthesis using solar energy, billions of tons of living biomass were st

59 minated by biomass burning the absorption of solar energy by aerosols within the atmosphere increased

60 In nature, solar energy can be harvested by photosynthesis where pr

61 g both natural photosynthesis and artificial solar energy capture(1,2).

62 in a broad range of applications related to solar energy conversion (photovoltaics, photocatalysis),

63 ficant impact on many applications including solar energy conversion and biomedical imaging.

64 ss in the exploitation of vegetable dyes for solar energy conversion and compares them to the propert

65 An integrated photoelectrochemical solar energy conversion and electrochemical storage devi

66 between PSII and cytb6f complexes integrates solar energy conversion and electron transfer by fosteri

67 ght-responsive photocatalyst in the arena of solar energy conversion and environmental remediation.

68 uding thermally controlled photonic devices, solar energy conversion and optical data storage.

69 ferroelectric semiconductor-based cells for solar energy conversion and other applications.

70 e useful for various applications, including solar energy conversion and photochemotherapy.

71 alytic properties and with potential uses in solar energy conversion and photonic devices.

72 ess because of a trade-off between efficient solar energy conversion and photoprotection.

73 ables the application of nonlinear optics to solar energy conversion and storage.

74 dyes with panchromatic light absorption for solar energy conversion applications.

75 we highlight recent advances in the field of solar energy conversion at a molecular level.

76 o a new chemical strategy for dye-sensitized solar energy conversion based on molecular excited state

77 Ds) have emerged as attractive materials for solar energy conversion because of their broad spectral

78 f considerable efforts in energy storage and solar energy conversion because of their unique properti

79 uctors are revolutionizing photovoltaic (PV) solar energy conversion by showing remarkable performanc

80 t, enzymatic, photo-biocatalytic systems for solar energy conversion can be facilitated, and the prec

81 timize charge transport and recombination in solar energy conversion devices using electrodes functio

82 ghts for subsequent fabrication of MOF-based solar energy conversion devices.

83 tial incorporation into a range of practical solar energy conversion devices.

84 ials potentially useful for integration into solar energy conversion devices.

85 hockley-Queisser limit describes the maximum solar energy conversion efficiency achievable for a part

86 The latter exhibit improved solar energy conversion efficiency and photosynthetic pr

87 tures offer a promising route to improve the solar energy conversion efficiency of semiconductors.

88 enhance natural photosynthesis for improved solar energy conversion efficiency.

89 Artificial photosynthetic systems for solar energy conversion exploit both covalent and supram

90 tificial photosynthetic reaction centers for solar energy conversion have similar requirements.

91 mportant mechanism contributing to efficient solar energy conversion in photosystem I.

92 sis is the mimicry of the natural process of solar energy conversion into chemical energy carriers.

93 tal oxide surfaces are important to emerging solar energy conversion processes, photocatalysis, and g

94 Photovoltaic (PV) technologies for solar energy conversion represent promising routes to gr

95 s the potential to supersede the traditional solar energy conversion scheme by means of boosting the

96 resented architectures, their application in solar energy conversion schemes and energy production ha

97 ons of this compound or related compounds in solar energy conversion schemes as an efficient light-ha

98 ng and positioning such materials for use in solar energy conversion schemes.

99 Solar energy conversion starts with the harvest of light

100 long been a central goal of molecular-based solar energy conversion strategies.

101 tremely important for devising a sustainable solar energy conversion system.

102 chromatically absorbing and highly versatile solar energy conversion system.

103 for achieving efficient exciton transport in solar energy conversion systems is precise structural co

104 a new methodology to build highly efficient solar energy conversion systems.

105 volved, finely tuned molecular machinery for solar energy conversion that exquisitely manages photon

106 of 1.5 eV, is a main candidate material for solar energy conversion through both photovoltaics and p

107 there is still no efficient means of direct solar energy conversion to H2 on a large scale despite a

108 aid in the development of new materials for solar energy conversion using a combination of spectrosc

109 a promising earth-abundant semiconductor for solar energy conversion with the potential to achieve te

110 ies, addressing "secure, clean and efficient solar energy conversion".

111 nt for fields as diverse as optoelectronics, solar energy conversion, and photobiology.

112 erging applications in the biomedical field, solar energy conversion, as well as security encoding.

113 dvantages of chemically synthesized QDHs for solar energy conversion, beginning with an overview of v

114 heterostructures and their applications for solar energy conversion, emphasizing mechanistic insight

115 erial for a diverse range of applications in solar energy conversion, energy storage, and electronics

116 chitectures that underpin future advances in solar energy conversion, fuel-cell catalysis, medical im

117 of applications including optical detectors, solar energy conversion, lasers, and sensors.

118 Solar energy conversion, particularly solar-driven chemi

119 titanium dioxide is important for its use in solar energy conversion, photocatalysis, and other appli

120 As an artificial system mimicking such solar energy conversion, porous chalcogenide aerogels (c

121 that is important in telecommunications and solar energy conversion.

122 mical reactivity studies and possible use in solar energy conversion.

123 r excited states can be rapid and useful for solar energy conversion.

124 w discusses the efficiency of photosynthetic solar energy conversion.

125 s, spanning areas from biological imaging to solar energy conversion.

126 rm processes such as resonant tunnelling and solar energy conversion.

127 heralding a new photocatalytic paradigm for solar energy conversion.

128 n and the understanding of QD interfaces for solar energy conversion.

129 ng antennae and catalytic centers to achieve solar energy conversion.

130 nologies are being developed for large-scale solar energy conversion.

131 a solution to the energy storage problem in solar energy conversion.

132 carrier extraction from singlet fission for solar energy conversion.

133 absorbers in solar cells aiming at a greener solar energy conversion.

134 Electrons are the workhorses of solar energy conversion.

135 hey are ideal light-harvesting materials for solar energy conversion.

136 ption to UV light, making it inefficient for solar energy conversion.

137 tial of organic semiconductors for efficient solar energy conversion.

138 tiated with the goal of finding solutions to solar energy conversion.

139 tential harvesting of energetic carriers for solar energy conversion.

140 olymorph most relevant in photocatalysis and solar energy conversion.

141 splitting is one of the grand challenges in solar energy conversion.

142 ue to potential applications in the field of solar energy conversion.

143 y wasting reaction is of direct relevance to solar energy conversion.

144 nostructures is a potential new paradigm for solar energy conversion; however, the reported efficienc

145 nter (PSII RC) indicates that photosynthetic solar-energy conversion might be optimized through the i

146 Molecular approaches to solar-energy conversion require a kinetic optimization o

147 -enhanced thermionic emission is a method of solar-energy conversion that promises to combine photon

148 avorable excited-state properties for use in solar-energy conversion.

149 ent, high-quality optoelectronic devices and solar-energy conversion.

150 or panchromatic light-harvesting systems for solar-energy conversion.

151 unctionality, relative to the embodiments of solar energy-conversion systems that have been developed

152 The efficiency of solar-energy-conversion devices depends on the absorptio

153 uired for the rapid development of efficient solar energy-converting devices.

154 rd osmosis (FO), driven by renewable energy (solar energy), denoted as EDFORD (ED-FO Renewable energy

155 e, we evaluate the land sparing potential of solar energy development across four nonconventional lan

156 rstanding environmental interactions between solar energy development and land-use decisions.

157 policy milestones; however, the extent that solar energy development on nonconventional surfaces can

158 s identified as potentially land-sparing for solar energy development.

159 ature-mimicking architectures for artificial solar energy devices.

160 reasing biomass yields and developing robust solar energy devices.

161 When wind or solar energy displace conventional generation, the reduc

162 diluted draw solution was then pumped to the solar energy driven ED.

163 artificial photosynthesis, in particular for solar-energy-driven synthesis of organic chemicals and c

164 CZTS) is a promising material for harvesting solar energy due to its abundance and non-toxicity.

165 uce this inert molecule to fuels by means of solar energy, either directly, after conversion of light

166 and promises a general approach for storing solar energy electrochemically with high theoretical sto

167 d applications in sensing, bioimaging, novel solar energy exploitation including photocatalytic coenz

168 ture provides a novel approach to harvesting solar energy for a broad range of phase-change applicati

169 we investigate the possibility of utilizing solar energy for biomass conversion by performing the ox

170 verage is mainly due to the concentration of solar energy for heat and electricity.

171 nna complexes not only aid in the capture of solar energy for photosynthesis, but regulate the quanti

172 In a similar way to plants absorbing solar energy for photosynthesis, humans can wear the as-

173 s-fabricated photovoltaic textile to harness solar energy for powering small electronic devices.

174 n because of its ability to directly utilize solar energy for production of solar fuels, such as hydr

175 Cyanobacteria are able to use solar energy for the production of hydrogen.

176 Harvesting solar energy from sunlight to generate electricity is co

177 omising solutions for renewable and portable solar energy generation and other related phase-change a

178 s of using perovskite-perovskite tandems for solar-energy generation.

179 Most life forms on Earth are supported by solar energy harnessed by oxygenic photosynthesis.

180 Solar energy harvesting and hydrogen economy are the two

181 ires applications such as in photodetection, solar energy harvesting and light emission.

182 ed design offers an inexpensive and scalable solar energy harvesting and steam generation technology

183 to artificial photosynthesis for large-scale solar energy harvesting and storage.

184 energy transfer, is critically important in solar energy harvesting assemblies, damage protection sc

185 In solar energy harvesting devices based on molecular semic

186 Diatoms exhibit high solar energy harvesting efficiency due to their frustule

187 brication technique offers a new approach to solar energy harvesting for high-efficiency steam genera

188 rt is a key challenge in achieving efficient solar energy harvesting in both organic solar cells and

189 ment proteins in biohybrid architectures for solar energy harvesting is attractive due to their globa

190 significantly influence the performances of solar energy harvesting systems, particularly (photovolt

191 rage and release are two major challenges of solar energy harvesting technologies.

192 ive function of BCs may find applications in solar energy harvesting, imaging, and sensing devices.

193 w structure has a variety of applications in solar energy harvesting, thermoplasmonics and related te

194 new avenues in photonics, quantum optics and solar energy harvesting.

195 erformance in applications like displays and solar energy harvesting.

196 ions including non-volatile data storage and solar energy harvesting.

197 silver clusters are promising materials for solar energy harvesting.

198 hotonics, biology, sensing, spectroscopy and solar energy harvesting.

199 it further consideration for applications in solar energy harvesting.

200 /n junctions for organic nanoelectronics and solar energy harvesting.

201 devices for light manipulative processes and solar energy harvesting.

202 ed thermoelectric technologies for efficient solar energy harvesting.

203 s of coherence and bioinspiration on diverse solar-energy harvesting solutions, including artificial

204 se results hint at promising applications in solar-energy harvesting, optical signal multiplexing, an

205 ,2'-bipyridine), making them of interest for solar-energy-harvesting applications.

206 has implications for the design of efficient solar-energy-harvesting devices.

207 of the NZB, septic tank aeration, and use of solar energy have been found to be important factors in

208 Hydrogen produced from water and solar energy holds much promise for decreasing the fossi

209 hallenges in realizing the full potential of solar energy; however, the land-use efficiency (LUE; Wm(

210 e to their utilization of readily accessible solar energy; however, the output of solar cells can be

211 Biology sustains itself by converting solar energy in a series of reactions between light harv

212 forts are dedicated to convert and store the solar energy in a single device.

213 The forest canopy is the engine that fixes solar energy in carbohydrates to power interactions amon

214 house gas emissions and simultaneously store solar energy in chemical form.

215 ennae to harvest light for the conversion of solar energy in complicated photosynthetic processes.

216 an store the intermittent renewable wind and solar energy in H2 fuels.

217 hold promise for the large-scale storage of solar energy in the form of (solar) fuels, owing to the

218 tion, and water splitting functions to store solar energy in the form of chemical bonds.

219 ynthesis for directly harvesting and storing solar energy in the form of chemical fuel.

220 nding to an additional 6.4 +/- 0.9 W/m(2) of solar energy input into the Arctic Ocean region since 19

221 Solar energy installations in deserts are on the rise, f

222 perate with ATP synthase to convert captured solar energy into a biologically consumable form, ATP.

223 The conversion of solar energy into chemical energy is catalyzed by two mu

224 initial steps of photosynthesis that convert solar energy into chemical energy, ultimately powering a

225 considered as the most useful way to convert solar energy into chemical energy.

226 t of synthetic systems for the conversion of solar energy into chemical fuels is a research goal that

227 hemical transformation for the conversion of solar energy into chemical fuels.

228 y investigated systems for the conversion of solar energy into electricity, particularly for implemen

229 le, clean and easy-processing way to convert solar energy into electricity.

230 sis (AP) is a promising method of converting solar energy into fuel (H(2)).

231 that control the photochemical conversion of solar energy into H(2).

232 One promising approach is to convert solar energy into hydrogen fuel using photoelectrochemic

233 Biological conversion of solar energy into hydrogen is naturally realized by some

234 nomically feasible technology for converting solar energy into hydrogen.

235 otosynthesis to directly harvest and convert solar energy into usable or storable energy resources.

236 g bio-based products directly from CO(2) and solar energy is a desirable alternative to the conventio

237 Solar energy is an alternative, sustainable energy sourc

238 Currently, steam generation using solar energy is based on heating bulk liquid to high tem

239 Making efficient use of solar energy is one of the biggest challenges of our tim

240 Solar energy is particularly attractive because it is es

241 Solar energy is potentially the largest source of renewa

242 Solar energy is readily available in most climates and c

243 cing carbon dioxide to hydrocarbon fuel with solar energy is significant for high-density solar energ

244 (NIR) light, which accounts for about 40% of solar energy, is highly significant.

245 r the direct production of hydrogen by using solar energy, is to develop low-cost yet highly efficien

246 uxes from the leaf surfaces and the absorbed solar energy load, leading to mathematical expressions f

247 mats from real-time fluorescence imaging, to solar energy materials, to optoelectronic devices and ma

248 erged as a new and highly promising class of solar-energy materials.

249 liquid hydrocarbon fuels using concentrated solar energy mediated by redox reactions of a metal oxid

250 Their kinetic energy can be used to harvest solar energy or create sensitive photodetectors and spec

251 Solar energy plays a critical role in contributing to th

252 er change from energy development, including solar energy, presents trade-offs for land used for the

253 ost, light-weight and environmentally benign solar energy production.

254 more than half a century, the production of solar energy remains costly, largely owing to low power

255 Instead, solar energy represents a renewable, economic and green

256 The utilization of solar energy requires an efficient means for its storage

257 Large-scale utilization of solar-energy resources will require considerable advance

258 se of supplemental nuclear, hydro, wind, and solar energy sources.

259 n-renewable sources of energy with renewable solar energy sources.

260 solar energy is significant for high-density solar energy storage and carbon balance.

261 anagement, including micro-channel coolants; solar energy storage media; building temperature regulat

262 Greater levels of solar energy storage provide an effective solution to th

263 provides an attractive route for large-scale solar energy storage, but issues surrounding the efficie

264 ange of reactions important in catalysis and solar energy storage, ours are the only values reported

265 ses a solution to the problem of large-scale solar energy storage.

266 actical solar water splitting as a means for solar energy storage.

267 taic-electrolysis systems for cost-effective solar energy storage.

268 implications for efficiency enhancements in solar energy systems.

269 the application of TiO2 in a diverse set of solar energy systems; however, what a black TiO2 nanopar

270 However, the development of solar-energy technologies is severely hindered by poor e

271 y of KBNNO to absorb three to six times more solar energy than the current ferroelectric materials su

272 hen these fuels are produced by solely using solar energy they are labeled as solar fuels.

273 hieve efficient and high-capacity storage of solar energy, through improving both photocurrent and ph

274 membrane (ICM) system for the conversion of solar energy to ATP.

275 mentally sustainable strategy for converting solar energy to biocommodities than approaches that rely

276 II) is a membrane-bound enzyme that utilizes solar energy to catalyze the photooxidation of water.

277 rochemical water splitting directly converts solar energy to chemical energy stored in hydrogen, a hi

278 Natural photosynthesis harnesses solar energy to convert CO2 and water to value-added che

279 n in recent decades, utilizing the unlimited solar energy to convert CO2 to fuels (e.g., formic acid

280 e the most important cofactors for capturing solar energy to drive photosynthetic reactions.

281 esents a promising technology for converting solar energy to fuel.

282 Harnessing solar energy to generate H(2) from H(+) is a crucial pro

283 Using solar energy to generate steam is a clean and sustainabl

284 to have different functions from harvesting solar energy to metabolonics for cleaning heavy and meta

285 This enzyme used solar energy to power the thermodynamically and chemical

286 riate materials and systems that can utilize solar energy to produce chemical fuels.

287 Plants use solar energy to produce lipids directly from inorganic e

288 tre, the only known natural enzyme that uses solar energy to split water.

289 Solar energy trapped at the surface created a colder, is

290 relatively high conversion efficiencies for solar energy, typical dye-sensitized solar cells suffer

291 nto one device allows for the more efficient solar energy usage.

292 Utility-scale solar energy (USSE) [i.e., >/= 1 megawatt (MW)] developm

293 As utility-scale solar energy (USSE) systems increase in size and numbers

294 l applications in night-vision surveillance, solar energy utilization and in vivo bio-imaging.

295 des is a viable process with implications in solar energy utilization and our understanding of primor

296 is a key step towards realizing large-scale solar energy utilization.

297 ts for photocatalytic water purification and solar energy utilization.

298 three technologically distinct approaches to solar energy utilization: solar electricity, solar therm

299 PS) systems are promising for the storage of solar energy via transportable and storable fuels, but t

300 key role in determining the competiveness of solar energy with other exhaustible energy sources.