ライフサイエンスコーパス: energy efficiency

1 ccompanied by information loss and a drop in energy efficiency.

2 lombic efficiency and 73 per cent round-trip energy efficiency.

3 her working concentration will yield greater energy efficiency.

4 y enable new technological possibilities for energy efficiency.

5 ajor improvements in computational power and energy efficiency.

6 urons can promote both coding efficiency and energy efficiency.

7 ts, both in terms of product selectivity and energy efficiency.

8 hot carriers, and may limit device speed and energy efficiency.

9 similar to common sulfur cathodes with high energy efficiency.

10 ort cycle life, use of electrolytes, and low energy efficiency.

11 00 mA/cm(2) and demonstrated up to 69% DC-DC energy efficiency.

12 able product synthesis at maximum carbon and energy efficiency.

13 without sensory input and may contribute to energy efficiency.

14 ion of these zeolite membranes with improved energy efficiency.

15 by altering substrate metabolism to increase energy efficiency.

16 f undesired byproducts and operate with high energy efficiency.

17 ely 10(13) watts), even with improvements in energy efficiency.

18 ese compromises can be expressed in terms of energy efficiency.

19 consumption and an improvement in myocardial energy efficiency.

20 art apples, higher profitability and greater energy efficiency.

21 r therapies directed at improving myocardial energy efficiency.

22 per trophic levels, which may confer greater energy efficiency.

23 ent speeds up furrow closure while promoting energy efficiency.

24 erating fields over long distances with high energy efficiency.

25 m loading process underlying the accelerator energy efficiency.

26 itting CO2 and H2O into CO and O2 with a 50% energy efficiency.

27 ossible to substantially increase round-trip energy efficiency.

28 l strategy in epithelial tissues to maximize energy efficiency.

29 ulate solar irradiation and improve building energy efficiency.

30 se concerns by reducing weight and improving energy efficiency.

31 y adopting multi-stage operation with better energy efficiency.

32 pplications with the required throughput and energy efficiency.

33 ittle impact on the dewaterability limit and energy efficiency.

34 e dewaterability limit, dewatering rate, and energy efficiency.

35 energy homeostasis bias foraging to maximize energy efficiency.

36 -fold, without significant compromise to the energy efficiency.

37 is fuel forming half reaction with such high energy efficiency.

38 e) has a TOF of 210 s(-1) in water with high energy efficiency (180 mV overpotential) under 1 atm H2

39 tly improved Faradaic efficiency (96.8%) and energy efficiency (61.7%), together with a considerable

40 leads to high specific capacities, excellent energy efficiency (93.2%) with a voltage gap of only 0.2

41 rogen from fossil fuels offer no significant energy efficiency advantage over hybrid vehicles operati

42 ce, nearly 100% coulombic efficiency and 85% energy efficiency after 25,000 charge-discharge cycles.

43 are significant, the combination of superior energy efficiency among newer South Korean coal-fired po

44 this study, we carry out a thermodynamic and energy efficiency analysis of PRO work extraction.

45 this study, we carry out a thermodynamic and energy efficiency analysis of RED power generation, and

46 heir wild-type littermates but had increased energy efficiency and a greater median life span (12% in

47 molecular redox couple that shows about 95% energy efficiency and about 90% capacity retention after

48 a thermally promoted process with increased energy efficiency and atom economy for key transformatio

49 We found that technically feasible levels of energy efficiency and decarbonized energy supply alone a

50 Two major concerns have been the net energy efficiency and economic feasibility of switchgras

51 High energy efficiency and energy density, together with rapi

52 significantly improve the safety, lifetime, energy efficiency and environmental impact of man-made m

53 htweight metals critically needed for future energy efficiency and fuel savings.

54 Furthermore, the microspheres exhibited high energy efficiency and good cyclability, showing a capaci

55 or release of captured CO(2), leading to low energy efficiency and high cost.

56 er, this is achieved at the expense of lower energy efficiency and higher impacts in the other assess

57 chondrial uncoupling, which reduces cellular energy efficiency and increases lipid oxidation, is an a

58 However, issues related to reversibility, energy efficiency and kinetics prevent their practical a

59 The energy efficiency and light quality of currently availab

60 cle, but it is currently hindered by the low energy efficiency and low activity displayed by traditio

61 Spintronic computing promises superior energy efficiency and nonvolatility compared to conventi

62 This study compares the energy efficiency and power density performance of PRO a

63 ficial photosynthetic system has much higher energy efficiency and productivity of bio-based products

64 mical performance of Li-O2 cells in terms of energy efficiency and rate capability.

65 The drive towards increased energy efficiency and reduced air pollution has led to a

66 ing to a redefined speed limit, and improved energy efficiency and reliability of phase-change memory

67 g and reveals new targets to improve cardiac energy efficiency and stress resistance.

68 atible; it thus has the potential to improve energy efficiency and system performance in aerospace, a

69 to current national energy systems-including energy efficiency and the decarbonization of electricity

70 this study, we perform the first analysis of energy efficiency and the expected performance of the TO

71 atively high temperatures, which compromises energy efficiency and the long-term stability of the cat

72 ransfer from the antenna to the cofactor for energy efficiency and then electron transfer between the

73 e while preserving the hardware's underlying energy-efficiency and high throughput, running on the af

74 level, the weighted-average product-specific energy efficiencies (and ranges) are estimated to be 88.

75 cycles, at high power, with high round-trip energy efficiency, and at low cost are required.

76 e storage of electrical and chemical energy, energy efficiency, and better energy management systems.

77 Renewable energy, energy efficiency, and energy conservation are all commo

78 ional measurements included cookstove power, energy efficiency, and fuel use.

79 ms are evaluating novel solvents, optimizing energy efficiency, and validating engineering models.

80 ic) and a porous carbon O2 cathode with high energy efficiency ( approximately 95%) and improved rate

81 Ever-increasing demands on conversion and energy efficiencies are a strong driving force for the d

82 mitigating osmosis, faradaic and round-trip energy efficiency are more than doubled, from 18% to 50%

83 High gradients of energy gain and high energy efficiency are necessary parameters for compact,

84 We calculated energy efficiency as the number of glutamate molecules r

85 eports on using this concept, for optimizing energy efficiency, as well as to improve upon the electr

86 ficiency when cycled at a 5C rate, and a 79% energy efficiency at 50C.

87 ciency when cycled at a 5C rate and an 84.2% energy efficiency at a 50C rate.

88 Transpose achieves run time and energy efficiency at the expense of memory as it takes t

89 We examined release site probabilities and energy efficiency at the terminals of two glutamatergic

90 optimization aims at achieving not just the energy efficiency but also (membrane) area efficiency, l

91 particle syntheses have higher material and energy efficiency, but are more limited in the shapes ac

92 by strategies such as lifespan extension or energy efficiency, but only when applied to all products

93 The drive to improve building energy efficiency by decreasing ventilation rates increa

94 This change would also increase energy efficiency by eliminating the need to produce add

95 Our focus is to obtain run time and energy efficiency by reducing the number of cache misses

96 ducted through electrodes) and corresponding energy efficiency by the factor approximately (D- - D+)/

97 roving the energy-delay product, a metric of energy efficiency, by more than an order of magnitude.

98 Energy efficiencies, calculated from changes in saliniti

99 Energy efficiency can be viewed as one aspect of nerve t

100 with an O2-evolving anodic reaction in high-energy-efficiency cells are not yet available.

101 is of CDI in terms of energy consumption and energy efficiencies during the charging and discharging

102 The net effect results in an increase in the energy efficiency (EE) for H2 production (DeltaEE) by 17

103 We estimate the system-level life-cycle energy efficiency (EF) and carbon intensity (CI) across

104 ltiple fronts, including efforts to increase energy efficiency; efforts to deploy nonfossil fuel sour

105 cal sciences including research on improving energy efficiency, environmentally friendly uses for oil

106 perature result in an unexpected increase in energy efficiency, especially near normal body temperatu

107 ectively, achieving a very high electrolysis energy efficiency exceeding 80% at considerably high cur

108 n taken together, these correspond to a high-energy efficiency for CO production, on par with that wh

109 The current efficiency and energy efficiency for H2 generation were calculated to r

110 erature result in an exponential increase in energy efficiency for single action potentials by increa

111 ple of how COPTEM can be used, we develop an energy efficiency gap analysis to investigate the possib

112 trosynthesis of energetic molecules at solar energy efficiency greater than any photovoltaic conversi

113 The need for greater energy efficiency has garnered increasing support for th

114 Lower energy efficiencies, however, will occur in systems oper

115 bstrate use may be an indication of impaired energy efficiency in the failing heart, providing a targ

116 stigate the role of claudin-2 in maintaining energy efficiency in the kidney.

117 nvironment can negatively affect adoption of energy efficiency in the United States because of the po

118 the 'hydrogen-cycling' model for increasing energy efficiency in this bacterium.

119 ular metabolism were acquired that increased energy efficiency in two respects.

120 effect of hypothetical strategies to improve energy efficiency in UK housing stock and to introduce 1

121 We therefore recommend aggressive energy efficiency, in combination with low-carbon genera

122 It has been generally established that energy efficiency increases and, therefore, per capita N

123 With respect to performance, we argue that energy efficiency is a reasonable optimality criterion f

124 It is believed that energy efficiency is an important constraint in brain ev

125 Here we demonstrate that this increase in energy efficiency is due largely to a warmer body temper

126 However, its energy efficiency is greatly undermined by the large ove

127 Our analytical model indicates that energy efficiency is optimal ( approximately 0.15) at hi

128 Overall refinery energy efficiency is the ratio of the energy present in

129 arge voltage profiles and the consequent low-energy efficiency (<80%).

130 tricity: compared to the West, an equivalent energy efficiency measure in the Midwest is expected to

131 that could be achieved by pursuing different energy efficiency measures across the nation.

132 ntial sector by deploying cost-effectiveness energy efficiency measures.

133 Adoption of energy-efficiency measures and renewable generation port

134 plain how high level control targets such as energy efficiency might influence overall physiological

135 of the reaction by a factor of 2.3, and the energy efficiency (mol product/joule of incident photons

136 onomically provide the power, cycle life and energy efficiency needed to respond to the costly short-

137 ts designed diverse portfolios that included energy efficiency, nuclear, coal with carbon capture and

138 stoichiometric yields of 54-91% and overall energy efficiencies of 64-82%.

139 At modest current densities, round-trip energy efficiencies of 99% can be achieved.

140 s high as jCO = 25-30 mA/cm(2) and attendant energy efficiencies of PhiCO approximately 80% for the c

141 ago, there are still factors that limit the energy efficiencies of the processes.

142 as 10% based on total energy applied with an energy efficiency of 22% based on the consumed energy in

143 oduction at a rate of 0.8 m(3)/m(3)/d and an energy efficiency of 51%.

144 r)2 TTz]Cl4 /N(Me) -TEMPO AORFB delivered an energy efficiency of 70 % and 99.97 % capacity retention

145 rformance (coulombic efficiency of 100 % and energy efficiency of 70 %).

146 generated steam at a rate of 2.0 LMH with an energy efficiency of 78%.

147 d PRO-MD system can theoretically achieve an energy efficiency of 9.8% (81.6% of the Carnot efficienc

148 d OER electrocatalyst in alkaline medium and energy efficiency of an electrolyzer using state-of-the-

149 flow cells using this electrolyte deliver an energy efficiency of ca. 70% and an impressively high en

150 ed if the cell's fitness function is the the energy efficiency of cells under fast growth conditions,

151 To estimate the rate and energy efficiency of ClpAP-catalyzed measurements of pro

152 rovides a means to significantly improve the energy efficiency of CO2 to methanol conversions.

153 The energy efficiency of combustion synthesis accrues from t

154 ents contribute to the coding efficiency and energy efficiency of cortical neurons remains unclear.

155 Improving energy efficiency of electrocatalytic and photocatalytic

156 The energy efficiency of heat engines could be improved by t

157 We compare the energy efficiency of hybrid and fuel cell vehicles as we

158 The energy efficiency of hydroxyl radical formation is compa

159 al redox flow batteries and high voltage and energy efficiency of Li-ion batteries, showing great pro

160 e to that in multibubble cavitation, but the energy efficiency of light emission is much higher.

161 re and electrode architecture to improve the energy efficiency of lithium-ion batteries based on conv

162 e of the standing wave cavity to improve the energy efficiency of microwave-assisted flow reactions.

163 ionic dynamics and may have implications for energy efficiency of neural excitation in many systems i

164 The energy efficiency of neural signal transmission is impor

165 ivity are needed to provide insight into the energy efficiency of plant metabolism under various cond

166 rmogenesis contributes to the relatively low-energy efficiency of protein); and 3) maintenance or acc

167 membranes that could be used to improve the energy efficiency of separation processes.

168 exterior of the tube is well insulated, the energy efficiency of such a reactor in heating the fluid

169 In the present work, to increase the energy efficiency of the adsorption-desorption processes

170 interconnectivity, information density, and energy efficiency of the brain using either approach.

171 The energy efficiency of the connectivity hubs was higher fo

172 etabolism, supporting our hypothesis for the energy efficiency of the connectivity hubs.

173 The factors controlling the energy efficiency of the heat engine were evaluated for

174 elative flow rate that maximizes the overall energy efficiency of the PRO-MD system for given working

175 At an applied voltage of 0.6 V, the overall energy efficiency of the process was 288% based solely o

176 limited mass and heat transfer kinetics, the energy efficiency of the system can be analytically dete

177 uses large voltage hysteresis and limits the energy efficiency of the system.

178 ads (Bodipy-NDI and TAPD-Ru), leading to the energy efficiency of the tetrad being 47% of the sum of

179 ects the hair bundles but also increases the energy efficiency of the vibrational shearing during sou

180 t gas stream, and improve the durability and energy efficiency of these engines.

181 elop new technical schemes for improving the energy efficiency of WWTPs by repurposing the stream of

182 ovoltaic systems would yield a CO2 reduction energy efficiency of ~10%, exceeding that of natural pho

183 O2 This scalable system has a CO2 reduction energy efficiency of ~50% when producing bacterial bioma

184 ost reduction with limited or no emphasis on energy efficiency or greenhouse gas minimization.

185 Continued advances in energy efficiency or the development of new cooling tech

186 Is E. coli optimized for growth speed, energy efficiency, or some other property?

187 tion technology, but pollutant emissions and energy efficiency performance of this class of stoves ar

188 nsistent test practices allows emissions and energy efficiency performance to be benchmarked and enab

189 From an energy-efficiency perspective, effective discrimination

190 eous as compared with swimming alone from an energy-efficiency perspective.

191 h, with consequent implications for national energy efficiency policies.

192 The trade-offs between different energy efficiency policy goals, as well as the environme

193 ansmission infrastructure, and the design of energy-efficiency policy and storage capacity.

194 ns that the true environmental benefit of an energy efficiency program may be approximately 20% small

195 ng climate policy, such as an enhancement in energy efficiency, promotion of renewable energy, and li

196 on for relatively scarce carbon sources, the energy efficiency provided by respiration may contribute

197 t H2 and protons at high rates and with high energy efficiencies, providing inspiration for the devel

198 eached up to 2.3 W/m(2), and (3) the overall energy efficiency reached up to 2.6% or 18% of the Carno

199 so help protect the environment by improving energy efficiency, reducing automobile exhaust and other

200 bilize climate are needed, including greater energy efficiency, renewable energy sources, geoengineer

201 Energy efficiency, renewable energy, urban design, price

202 have different expression levels, carbon and energy efficiencies, require auxiliary systems for biosy

203 estive flexibility provides Dolly Varden the energy efficiency required to survive and reproduce when

204 d contribute to the observed improvements in energy efficiency seen in patients with heart failure.

205 , satisfying 4.1-16% of the state's mandated energy-efficiency standard.

206 xtended elsewhere as renewable portfolio and energy efficiency standards become more common nationall

207 prescribed by California's Title 24 building energy efficiency standards within the heavily populated

208 of legislated renewable energy portfolio and energy efficiency standards.

209 R catalytic activity as well as electrolysis energy efficiency surpasses any previously reported OER

210 computing has now demonstrated unprecedented energy-efficiency through a new chip architecture based

211 Caveolae formation has raised the concept of energy efficiency to new heights.

212 rojections and investigate the potential for energy efficiency to offset increased demand.

213 to achieve maximum productivity and maximum energy efficiency under a given set of operational costs

214 impacts of large-scale initiatives-including energy efficiency upgrades and ventilation standards-tha

215 igh efficiency cell shows a 96.7% round trip energy efficiency when cycled at a 5C rate and an 84.2%

216 e, high-efficiency cell has a 95% round-trip energy efficiency when cycled at a 5C rate, and a 79% en

217 y represent actual operations, the practical energy efficiency will be lower than the theoretically a

218 (the removal of salts from seawater) at high energy efficiency will likely become a vital source of f

219 produce designer products at high carbon and energy efficiency with adjustable output, at high select

220 orrelating the variation in overall refinery energy efficiency with crude quality, refinery complexit

221 The modeling results demonstrate higher OHE energy efficiency with the LiCl-methanol draw solution c