ライフサイエンスコーパス: photovoltaic

1 n assessing the impacts of climate change on photovoltaics.

2 e single-junction Shockley-Queisser limit in photovoltaics.

3 lar cells, organic-, and nanostructure-based photovoltaics.

4 kites is essential for their advanced use as photovoltaics.

5 r CoIns in molecular aggregates relevant for photovoltaics.

6 ctor applications including lasers, LEDs and photovoltaics.

7 ic applications including but not limited to photovoltaics.

8 cle toward higher-performance perovskite CQD photovoltaics.

9 s a challenge for large-scale integration of photovoltaics.

10 tability and performance in 2D/3D perovskite photovoltaics.

11 ons in electron acceptors for use in organic photovoltaics.

12 ing module for artificial photosynthesis and photovoltaics.

13 ZTN) which has attracted recent interest for photovoltaics.

14 ly improves the performance of perovskite QD photovoltaics.

15 ation losses inherent to all single-junction photovoltaics.

16 r successful application in high-performance photovoltaics.

17 ving high-efficiency metal-halide perovskite photovoltaics.

18 to be a poor photocatalyst, is promising for photovoltaics.

19 ts have been a key constraint for perovskite photovoltaics.

20 phores with potential use in singlet fission photovoltaics.

21 hermal barrier coating, and more recently to photovoltaics.

22 nergy in the solar's spectrum peak for GaInP photovoltaics.

23 f this concept to be exploited for lead-free photovoltaics.

24 long-standing concern for hybrid perovskite photovoltaics.

25 material offering high efficiencies in solar photovoltaics.

26 nhancing the open-circuit voltage of organic photovoltaics.

27 structures such as resistors, capacitors and photovoltaics.

28 s including bioimaging, optical sensors, and photovoltaics.

29 erovskite solar cells in building-integrated photovoltaics(17-23).

30 sical organic semiconductors used in organic photovoltaics (5-20 nm) imposes severe limits on the max

31 (2)GeS(4) has been identified as a promising photovoltaic absorber material introduced as an alternat

32 ) (-) (y) MA(x) Cs(y) PbI(3-) (z) Br(z) ) as photovoltaic absorbers, as they enable easier processing

33 procity relations relating light emission to photovoltaic action and regarding minimal attainable pho

34 ts were not likely the cause of the observed photovoltaic action from photoacid-modified membranes.

35 erging as valid alternatives to conventional photovoltaic active materials owing to their low cost an

36 Photovoltaics along with SLB reduced the use of grid ele

37 properties of perovskites already proved for photovoltaics, also should be of interest in photoredox

38 skite nanocrystals (NCs) are of interest for photovoltaic and light-emitting devices due to optoelect

39 ites have emerged as promising materials for photovoltaic and optoelectronic applications.

40 research, the prospects for perovskite-based photovoltaic and optoelectronic devices, including non-p

41 rkable stability and promising efficiency in photovoltaic and optoelectronic devices, yet fundamental

42 n remarkable performance as active layers in photovoltaic and other optoelectronic devices.

43 Two photocurrent generation mechanisms of photovoltaic and photoconductive dominances coexist in t

44 ic applications, including imaging, sensing, photovoltaics and communications.

45 skite (HaP)-based optoelectronics, including photovoltaics and light-emitting diodes.

46 at resisted magnetic recording, solar thermo-photovoltaics and nano-scale heat transfer systems.

47 riven by both their potential application in photovoltaics and optoelectronics and by the fundamental

48 racted significant attention in the field of photovoltaics and other optoelectronic applications due

49 should have broad applications, including in photovoltaics and other optoelectronic devices.

50 dy of natural and artificial photosynthesis, photovoltaics and photosensitive materials.

51 ns such as nanophotonics, silicon photonics, photovoltaics, and biosensing.

52 among molecules to optimize photocatalysis, photovoltaics, and energy storage.

53 tions, which may include chemical stability, photovoltaics, and light emission.

54 ize fields as diverse as biological imaging, photovoltaics, and optogenetics.

55 ntrol phonon propagation in thermoelectrics, photovoltaics, and other materials requiring thermal man

56 sed as 2D material for field effect devices, photovoltaics, and photocatalysis.

57 ocatalysts, solar energy conversion devices, photovoltaics, and photonics.

58 ic and optoelectronic devices, including non-photovoltaic applications such as X-ray detectors and im

59 position process in molten salt for possible photovoltaic applications.

60 tion to the current progress of these QDs in photovoltaic applications.

61 lectronics required for untethered flight (a photovoltaic array and a signal generator) weighs 259 mi

62 Organic photovoltaics based on non-fullerene acceptors (NFAs) sh

63 The device demonstrates a pronounced photovoltaic behavior with a short-circuit current of 1.

64 derived hole transfer process in all-polymer photovoltaic blends, which is a fundamentally different

65 pecially highlight compound 1 as a promising photovoltaic candidate.

66 tion (P(gen) ~ 1.25 muWcm(-2)) in our thermo-photovoltaic cell by actively tuning the gap between a h

67 ctrical energy requirements are ensured by a photovoltaic cell that is a dye sensitized solar cell (D

68 ed to improve the photoanode features of the photovoltaic cell, a dye sensitized solar cell (DSSC), a

69 cal heat source to generate electricity in a photovoltaic cell.

70 ow where it is converted to electricity by a photovoltaic cell.

71 ure germanium photodetector to form a thermo-photovoltaic cell.

72 Semitransparent organic photovoltaic cells (ST-OPVs) that utilize a nonfullerene

73 m should use low-cost and easily processable photovoltaic cells and display minimal energy losses ass

74 Organic photovoltaic cells are now approaching commercially viab

75 Organic photovoltaic cells are partiuclarly sensitive to exciton

76 s of marine-based floating islands, on which photovoltaic cells convert sunlight into electrical ener

77 A key characteristic of organic photovoltaic cells is the efficient charge separation in

78 tegrated photovoltaics employing transparent photovoltaic cells on window panes provide an opportunit

79 ally, we subjected a second group of organic photovoltaic cells to 20 Suns of ultraviolet illuminatio

80 s in electronic devices such as transistors, photovoltaic cells, and water-splitting electrodes.

81 self-signalled biosensing system that merges photovoltaic cells, plastic antibodies and electrochromi

82 on, in regenerative photoelectrochemical and photovoltaic cells.

83 p-type Si wafer, indicating potential use in photovoltaic cells.

84 light-emitting diodes, flexible displays and photovoltaic cells.

85 thermally evaporated single-junction organic photovoltaic cells.

86 performance in organic-based devices such as photovoltaics, chemical sensors, and photodetectors.

87 sol water is an essential problem within the photovoltaic community.

88 important focus of study within the organic photovoltaic community.

89 been a long-standing question in the organic photovoltaics community.

90 ecombination losses in the resulting organic photovoltaics, contributing to a certified high power co

91 materials have shown tremendous potential in photovoltaic detectors and solar cells.

92 Finally, photovoltaic detectors have shown excellent photocurrent

93 ihilation could increase the performance for photovoltaics, detectors, and light emitting diodes.

94 The results provide new research paths for photovoltaics, detectors, infrared imaging, flexible ele

95 y pave the way towards a reliable perovskite photovoltaic device at low-cost.

96 nits tunes the optoelectronic properties and photovoltaic device characteristics in a predictable way

97 come another focus in the optoelectronic and photovoltaic device community.

98 athway to implement advanced single-junction photovoltaic device designs that can capture energy typi

99 cell device performance parameters including photovoltaic device efficiency, open circuit voltage, fi

100 and gap, the highest stability, and the best photovoltaic device performance.

101 lized by ultrafast microscopy), and improved photovoltaic device performance.

102 ized power conversion efficiency of 22.6% of photovoltaic device was demonstrated with theophylline t

103 roduced aluminum back surface field (Al-BSF) photovoltaic device.

104 llection is critical in any photodetector or photovoltaic device.

105 first introduced to stabilize optoelectronic/photovoltaic devices against moisture, more interesting

106 npolar media, an integral process in organic photovoltaic devices and doped molecular films.

107 property-performance relations of D18-based photovoltaic devices and helps guide design or fabricati

108 photodynamic therapy regimes, in addition to photovoltaic devices and solar cells, among a vast multi

109 Quantum dot (QD) photovoltaic devices are attractive for their low-cost s

110 However, such 2D photovoltaic devices are limited by low quantum efficien

111 effective scheme to design high-performance photovoltaic devices assembled by 2D materials.

112 ptical absorption via selenium substitution, photovoltaic devices based on a PM6:CH1007:PC(71)BM tern

113 Photovoltaic devices fabricated from perovskite absorber

114 nversion efficiencies for solution-processed photovoltaic devices for Cu(2)ZnSn(S,Se)(4) (CZTS), Cu(2

115 Planar photovoltaic devices from optimized ACI perovskite films

116 interest in the field of optoelectronic and photovoltaic devices though challenging due to the low d

117 als, with implication in fields ranging from photovoltaic devices to quantum information processing.

118 ve revolutionized the development of organic photovoltaic devices, acting as excellent electron accep

119 y (PCE) and average visible transmittance of photovoltaic devices, are presented from the materials s

120 of Cu(3)VSe(4) NSs as an absorber for solar photovoltaic devices, Cu(3)VSe(4) NSs thin-films deposit

121 and thence into positive-intrinsic-negative photovoltaic devices, increasing the device efficiency a

122 performance in biomedicine, photodetectors, photovoltaic devices, light-emitting devices, sensors, m

123 ter a promising candidate for use in organic photovoltaic devices.

124 anism for improving the efficiency of future photovoltaic devices.

125 ercapacitors, photoelectrochemical cells and photovoltaic devices.

126 can potentially enhance the photocurrent in photovoltaic devices.

127 tronic properties in both optoelectronic and photovoltaic devices.

128 advantageous features for solution-processed photovoltaic devices.

129 omising ways of increasing the efficiency of photovoltaic devices.

130 s potential for increasing the efficiency of photovoltaic devices.

131 of improving the efficiency and stability of photovoltaic devices.

132 t the maximum power conversion efficiency of photovoltaic devices.

133 transfer dyads, which can operate in organic photovoltaic devices.

134 organic field-effect transistors and organic photovoltaics, DTT self-assembly and templated assembly

135 tly emerged as a promising candidate for CQD photovoltaics due to their superior optoelectronic prope

136 The bulk photovoltaic effect (BPVE) rectifies light into the dc c

137 bstantial photoconductance and visible-light photovoltaic effect are found in radical hydrocarbons.

138 y boron-doped silicon substrate silences the photovoltaic effect induced from LED illumination.

139 ropic phase boundaries, the associated flexo-photovoltaic effect induces on one side an enhanced phot

140 It is well known that the photovoltaic effect produces a direct current (DC) under

141 voltaic effect, there is another new type of photovoltaic effect that generates alternating current (

142 tive phenomena-such as rectification(1), the photovoltaic effect(2), the quantum Hall effect(3) and h

143 rom the DC generated by the conventional p-n photovoltaic effect, there is another new type of photov

144 rent, in analogy to that which occurs in the photovoltaic effect.

145 power output in addition to the conventional photovoltaic effect.

146 trate a unidirectional conduction and strong photovoltaic effect.

147 The photovoltaic efficiency of perovskite solar cells (PSCs)

148 photocurrent generation and further improve photovoltaic efficiency of perovskite solar cells (PSCs)

149 AMA) have been reported to possess excellent photovoltaic efficiency with minimal hysteresis; in this

150 renewable energy sector owing to their high photovoltaic efficiency, low manufacturing cost, and fle

151 oaden their photoresponse and increase their photovoltaic efficiency.

152 uld be one of the reasons for their observed photovoltaic efficiency.

153 Building-integrated photovoltaics employing transparent photovoltaic cells o

154 CM is promising disruptive improvements in photovoltaic energy conversion and light detection techn

155 taic action and regarding minimal attainable photovoltaic energy conversion losses in OPV devices.

156 further facilitate the reduction in cost of photovoltaic energy, new approaches to limit module temp

157 sic organisms are a promising alternative to photovoltaics for solar electricity production.

158 Floating photovoltaic (FPV) systems, also called floatovoltaics,

159 ated with onshore wind, hydropower and solar photovoltaic generation, within three important conserva

160 ances in organic-inorganic hybrid perovskite photovoltaics have triggered the inclusion of organic io

161 -induced polarization and ionic migration in photovoltaic hysteresis.

162 stablished, which does not contribute to the photovoltaic hysteresis.

163 great potential in the design of systems for photovoltaics in which intermolecular interactions in se

164 semiconductor, flat panel display, and solar photovoltaic industries.

165 t low electrically-resistive contract in the photovoltaics industry.

166 Powering distributed HS-DAC with photovoltaics (instead of coal) while including recaptur

167 the established mechanisms for conventional photovoltaics; instead, it is suggested to be a result o

168 lls represent a revolutionary shift in solar photovoltaics, introducing relatively soft defect contai

169 t density of the two-terminal tandem organic photovoltaic is significantly enhanced from 10.3 to 11.7

170 alization of the positive polaron in organic photovoltaics is considered essential for the effective

171 and hybrid organic-inorganic heterojunction photovoltaics is often limited by high carrier recombina

172 state-of-the-art of 2D-materials-based solar photovoltaics is presented here so that the recent advan

173 Cu(3) PSe(4) , a promising new material for photovoltaics, is reported.

174 ure owing to their demonstrated potential in photovoltaic, lasing, and display applications.

175 lline-silicon solar cells have dominated the photovoltaics market for the past several decades.

176 olar energy conversion using new or improved photovoltaic materials and artificial photosynthesis for

177 provides ample opportunities to study novel photovoltaic materials and device design architectures w

178 work paves a pathway to search for magnetic photovoltaic materials and to design switchable devices

179 r cells (PSCs) are one of the most promising photovoltaic materials due to their unprecedented develo

180 halide perovskites have emerged as promising photovoltaic materials, but, despite ultralow thermal co

181 to halide perovskites - an emerging class of photovoltaic materials.

182 trical properties, which make them excellent photovoltaic materials.

183 trategies for the synthesis of new lead-free photovoltaic materials.

184 pairs of triplet excitons, have potential as photovoltaic materials.

185 with a state-of-the-art, low-cost perovskite photovoltaic minimodule, this system reaches a 2.3% sola

186 With the scaling trends in photovoltaics moving toward thinner active materials, th

187 The photovoltaics of organic-inorganic lead halide perovskit

188 anic optoelectronic devices, such as organic photovoltaic (OPV) cells, is to a large extent dictated

189 and solid-state microstructure with organic photovoltaic (OPV) device performance has intensely been

190 electron-accepting (A) materials in organic photovoltaic (OPV) devices is commonly probed by charge-

191 a well-studied cathode interlayer in organic photovoltaic (OPV) devices, where it for standard device

192 Organic photovoltaic (OPV) efficiencies continue to rise, raisin

193 e efficiency as well as stability of organic photovoltaics (OPVs) are achieved by designing ternary b

194 The performance of organic photovoltaics (OPVs) has rapidly improved over the past

195 Organic photovoltaics (OPVs) have attracted tremendous attention

196 Ternary blend organic photovoltaics (OPVs) have been introduced to improve sol

197 g the power conversion efficiency of organic photovoltaics (OPVs) is still an ongoing challenge to ov

198 ient cathode interlayer material for organic photovoltaics (OPVs) was produced by integrating C(60) f

199 he predominant fabrication method of organic photovoltaics (OPVs).

200 which offers a unique application of organic photovoltaics (OPVs): semitransparent OPVs.

201 rs relevant to improved performance in solar photovoltaics or light-emitting diodes.

202 hnology, whose natural transparency and good photovoltaic output under ambient light conditions affor

203 s between the metal electrode and a standard photovoltaic packing film.

204 Consequently, all photovoltaic parameters are significantly enhanced in th

205 We find a pronounced decline of all photovoltaic parameters with decreasing CT state energy.

206 t results in significant improvements in the photovoltaic parameters.

207 The photovoltaic peak responsivity of 11.6 uA/W is obtained

208 d to be an effective approach to enhance the photovoltaic performance and device stability of perovsk

209 t, the defects can be reduced to enhance the photovoltaic performance and stability of derived PVSCs.

210 However, they suffer from poor photovoltaic performance as compared to the 3D perovskit

211 of the acceptor polymer too much reduces the photovoltaic performance as the donor phase-separation d

212 We show how the photovoltaic performance depends upon the heterojunction

213 end-group redistribution propensity, and BHJ photovoltaic performance of a series of ITIC variants, I

214 ich is likely responsible for the remarkable photovoltaic performance of such A-D-A semiconductors.

215 rption and reduced trap density for improved photovoltaic performance with BP incorporation.

216 a result, we achieved substantially improved photovoltaic performance with power conversion efficienc

217 esulting in dramatic improvements in organic photovoltaic performance, now exceeding 18% power conver

218 rs (ETLs) such as TiO(2) dictate the overall photovoltaic performance.

219 ctive layer morphology of OSCs for improving photovoltaic performance.

220 ded one exhibited a full regeneration of all photovoltaic performances.

221 lecular modulation, without compromising the photovoltaic performances.

222 charge carriers from the [Formula: see text] photovoltaic perovskite efficiently dope the thin [Formu

223 e previously observed photothermoelectric or photovoltaic photocurrents in graphene(12-20): the photo

224 onic (e.g., transistors) and photonic (e.g., photovoltaics, photodetectors or LEDs) technologies can

225 etectors) to polycrystalline films (e.g., in photovoltaics, photodetectors, and light-emitting diodes

226 F-TU molecular ink chemistry to lead to high-photovoltaic power conversion efficiencies and high-open

227 As photovoltaic power is expanding rapidly worldwide, it is

228 This is primarily due to their inadequate photovoltaic properties and chemical stability.

229 vskite oxides that exhibit ferroelectric and photovoltaic properties are promising multifunctional ma

230 tanding and the nexus between optoelectronic/photovoltaic properties of 2D and 3D halide perovskites,

231 , have been proven to play a crucial role in photovoltaic properties of ferroelectrics.

232 l why Pb halide perovskites exhibit superior photovoltaic properties, but Pb-free perovskites and per

233 ng phenomenon, influencing their optical and photovoltaic properties.

234 n arguable aspect for the prospect of onsite photovoltaic (PV) application.

235 This can be achieved in a system coupling a photovoltaic (PV) cell to an electrochemical cell (EC) f

236 Here, it is shown that dust-sized III-V photovoltaic (PV) cells grown on Si and silicon-on-insul

237 Perovskite photovoltaic (PV) cells have demonstrated power conversi

238 alide perovskites (MHPs) have transfixed the photovoltaic (PV) community due to their outstanding and

239 the optimal location for constructing solar photovoltaic (PV) farms.

240 Several cities are considering both photovoltaic (PV) generation and electric vehicles (EVs)

241 Global exponential increase in levels of Photovoltaic (PV) module waste is an increasing concern.

242 The accumulation of soiling on photovoltaic (PV) modules affects PV systems worldwide.

243 pection of cracks in polymer backsheets from photovoltaic (PV) modules.

244 of the environmental factors that influence Photovoltaic (PV) panel function.

245 termediate bandgap, associated with enhanced photovoltaic (PV) performance.

246 le initiative to systematically deploy solar photovoltaic (PV) projects to alleviate poverty in rural

247 erging technology application in which solar photovoltaic (PV) systems are sited directly on water.

248 and efficiency limits of arbitrarily complex photovoltaic (PV) topologies.

249 e sensitised solar cells (DSSCs) woven using photovoltaic (PV) yarns have been demonstrated but there

250 Photovoltaics (PV) are a versatile and compact route to

251 aterials in light-emitting diodes (LEDs) and photovoltaics (PV) in the literature, where materials ca

252 ing the temporal production profile of solar photovoltaics (PV) into better correlation with typical

253 al in a wide range of applications, such as, photovoltaics (PV), optoelectronics, sensors, and bio-el

254 Semitransparent (ST) photovoltaics (PVs) with selective absorption in the UV

255 extraction before complete thermalization in photovoltaics (PVs).

256 QDs) are of great interest in new-generation photovoltaics (PVs).

257 lar radiation intermittency to assess future photovoltaic reliability.

258 Across the modeled scenarios, solar photovoltaics represent the most cost-effective low-carb

259 ic/inorganic perovskites are revolutionizing photovoltaic research and are now impacting other resear

260 PSCs) has generated enormous interest in the photovoltaic research community.

261 efficient photocurrent generation through a photovoltaic response and electroluminescence within a s

262 Room temperature photovoltaic response with a cut-off wavelength of 3.4 m

263 plays on their properties and thereby on the photovoltaic response.

264 mpared to the highly self-aggregating N2200, photovoltaic results show that blending of more amorphou

265 al peripheral field, we developed a wireless photovoltaic retinal implant (PRIMA; Pixium Vision, Pari

266 vskites have been widely investigated in the photovoltaic sector due to their promising optoelectroni

267 The example of CuInSe(2) photovoltaic semiconductor reveals that single phase mat

268 ation of metal-organic frameworks (MOFs) for photovoltaic, sensing, and photocatalytic applications.

269 This yields enhanced photovoltaic short-circuit current density and good open

270 nce limits in optoelectronic devices such as photovoltaic solar cells and light-emitting diodes.

271 ilms, which are suitable for applications in photovoltaics, solar cells, and photo-catalysis.

272 electricity generation approaches including photovoltaics, solar thermal power systems, and solar th

273 tials (VEPs) recorded in rats implanted with photovoltaic subretinal implants.

274 ously reported near-infrared-light-sensitive photovoltaic subretinal prosthesis.

275 ctrodes play a fundamental role in far-field PhotoVoltaic systems, but have never been thoroughly inv

276 conductivity for electrodes in displays and photovoltaic systems.

277 de perovskites are one of the most promising photovoltaic technologies(1-4).

278 has been featured in the roadmap of standard photovoltaic technologies, a proper synergy is still lac

279 or formulating the future roadmap of various photovoltaic technologies.

280 tive to the presently commercially available photovoltaic technologies.

281 ials leading the field of low-cost thin film photovoltaics technologies.

282 Singlet exciton fission photovoltaic technology requires chromophores with their

283 as an emerging high-efficiency and low-cost photovoltaic technology(1-6), face obstacles on their wa

284 zed solar cells (DSCs) are a next-generation photovoltaic technology, whose natural transparency and

285 hoice for integration with future-generation photovoltaic technology.

286 is a key step towards a reliable perovskite photovoltaic technology.

287 lity of large-scale deployment of perovskite photovoltaic technology.

288 gnetic spectrum is exceedingly important for photovoltaics, telecommunications, and the biomedical sc

289 gies, from solid-state lighting to efficient photovoltaics that have transformed global energy landsc

290 In tandem organic photovoltaics, the front subcell is based on large-bandg

291 Despite performance improvements of organic photovoltaics, the mechanism of photoinduced electron-ho

292 ies of photonics applications, in particular photovoltaics, thermal emitters and sensors.

293 numerous advanced applications spanning from photovoltaics to biophotonics.

294 at small scales in applications ranging from photovoltaics to microfluidic devices.

295 t are presently in the focus of the field of photovoltaics turn out to be rather expected from the po

296 improve the efficiency of energy capture in photovoltaics when employed in the front cell of perovsk

297 Examples include, (i) photovoltaics where TTA-UC could lead to utilization of

298 The costs for solar photovoltaics, wind, and battery storage have dropped ma

299 l find use in bottom cells for stable tandem photovoltaics with a surface 2D layer passivating the 3D

300 iews on future prospects of perovskite-based photovoltaics, with discussions focused on strategies to