ライフサイエンスコーパス: biofuel

1 omising feedstock for biodiesel and aviation biofuel.

2 astly more efficient than a terrestrial crop biofuel.

3 rvesting for rising production of cellulosic biofuel.

4 ost produced crop, providing food, feed, and biofuel.

5 st-effective, energy-efficient production of biofuel.

6 rest as potential feedstocks for sustainable biofuels.

7 als, pigments, proteins and most prominently biofuels.

8 metabolism for development of algal-derived biofuels.

9 imple sugars that can then be converted into biofuels.

10 rticulate filters and when introducing novel biofuels.

11 as potential for the production of specialty biofuels.

12 cohols (C6-C12) could be used as diesel-like biofuels.

13 g platform for the production of lipid-based biofuels.

14 l, three C5 alcohols that serve as potential biofuels.

15 h and for the generation of renewable liquid biofuels.

16 represent an attractive potential source of biofuels.

17 mportance for the use of plant materials for biofuels.

18 the commercial production of lignocellulosic biofuels.

19 ism in studies of photosynthesis, cilia, and biofuels.

20 Alkali metals are inherent constituents of biofuels.

21 le Fuels Standard (RFS2) for clean, advanced biofuels.

22 ncrease when combusting potassium-containing biofuels.

23 ng strategies for the production of advanced biofuels.

24 emissions reduction threshold for cellulosic biofuels.

25 beetle resistance, chemical feedstocks, and biofuels.

26 ILUC induced by expanded production of three biofuels.

27 of high-volume commodity chemicals, such as biofuels.

28 um), a strategic plant for second-generation biofuels.

29 in in the processes of converting biomass to biofuels.

30 ide a feedstock for downstream processing to biofuels.

31 , that is, in biotechnology, biorefining, or biofuels.

32 variants thereof in the future production of biofuels.

33 gronomic solution for future terpene-derived biofuels.

34 used as renewable sources for production of biofuels.

35 enes with applications as fine chemicals and biofuels.

36 nomic barrier to overcome to make cellulosic biofuels a commercial reality.

37 cations and has been explored as a potential biofuel additive.

38 tification, sports doping, petroleomics, and biofuel analysis, among many others) and remains a techn

39 y to improve plant cell wall composition for biofuel and bioproducts generation.

40 will allow the improvement of sugarcane for biofuel and chemicals production.

41 lic differences, observations that may guide biofuel and commodity chemical production with this spec

42 ons (I-TEQ) increased 23-fold when comparing biofuel and diesel data.

43 w here the status of terpenes as a specialty biofuel and discuss the potential of plants as a viable

44 gical applications, and as a model for algal biofuel and energy metabolism.

45 Technologies for biofuel and photovoltaic paths are evolving; it is criti

46 zofingiensis, because it produces lipids for biofuels and a highly valuable carotenoid nutraceutical,

47 neering efforts to improve the production of biofuels and aromatic industrial products as well as inc

48 Producing cellulosic biofuels and bio-based chemicals from woody biomass is i

49 s for the development of strains to maximize biofuels and bio-products yields from the lab to the fie

50 stem composition for improved conversion to biofuels and bio-products.

51 of algae as feedstock for the production of biofuels and biomaterials.

52 of solvent-like compounds, such as advanced biofuels and bulk chemicals, accumulation of the final p

53 more economic production of lignocellulosic biofuels and byproducts.

54 al metabolism for the generation of biomass, biofuels and chemicals a challenge.

55 The aim of producing sustainable liquid biofuels and chemicals from lignocellulosic biomass rema

56 Mass yields of biofuels and chemicals from sugar fermentations are limi

57 feedstock for a variety of materials such as biofuels and chemicals.

58 bstacle to widespread production of advanced biofuels and chemicals.

59 eck limiting the production of plant-derived biofuels and chemicals.

60 ical applications ranging from production of biofuels and commercial products to hydrocarbon remediat

61 as feedstock organisms useful for producing biofuels and coproducts.

62 for engineering microalgae for production of biofuels and high-value bioproducts.

63 in NS cells, promising commercial harvest as biofuels and nutritional lipids, several micron-sized dr

64 om carbohydrate feedstocks for production of biofuels and oleochemicals.

65 a source of valuable aromatic compounds for biofuels and other bioproducts.

66 n and metabolic engineering of organisms for biofuels and other chemicals, as well as investigations

67 ts to engineer biological systems to produce biofuels and other desired chemicals.

68 Deriving biofuels and other lipoid products from algae is a promi

69 Despite their potential as biofuels and precursors for specialty chemicals, the und

70 roalgae as a feedstock for the production of biofuels and renewable chemicals.

71 lysaccharide, particularly in the context of biofuels and renewable nanomaterials.

72 maceutical interest, production of potential biofuels and shuffling of disease-resistance traits betw

73 to both the production of second-generation biofuels and the generation of valuable coproducts from

74 e of renewable biomass for the production of biofuels and valuable chemicals.

75 n farming algae for the direct production of biofuels and valuable lipids.

76 s of important pharmaceutical, aromatherapy, biofuel, and industrial components, warranting considera

77 the production of novel therapeutic agents, biofuels, and commodity chemicals.

78 care, computer technology, the production of biofuels, and more.

79 r food and, increasingly, for industrial and biofuel applications.

80 lgae cultivation as a way of producing algal biofuels at a commercial scale more sustainably.

81 Second generation biofuels based on cellulosic ethanol produced from terre

82 We recommend that this biofuel be used with caution and that whenever possible

83 Our observations quantify the impact of biofuel blending on aerosol emissions at cruise conditio

84 that, compared to using conventional fuels, biofuel blending reduces particle number and mass emissi

85 xtractive fermentation for the production of biofuel blendstocks.

86 DPF indeed supported a PCDD/F formation with biofuel but remained inactive with petroleum-derived die

87 y commodity crops that are used for food and biofuel, but have not been developed for agricultural pr

88 e biological stability of two emerging naval biofuels (camelina-JP5 and Fischer-Tropsch-F76) and thei

89 matter, including petroleum-based fuels and biofuels, can create undesired secondary water-quality e

90 Enzymatic biofuel cell (EBFC) operates at ambient temperature and

91 The enzymatic biofuel cell (EFC) generated an open circuit potential o

92 Fundamental part of each Glucose biofuel cell (GBFC) is two bioelectrodes which their sur

93 f-powered sensing system, driven by a hybrid biofuel cell (HBFC) with carbon paper discs coated with

94 s a promising enzyme for the construction of biofuel cell anodes and biosensors capable of oxidizing

95 de dehydrogenase (ADH and AldDH) enzymes for biofuel cell applications.

96 ) at anode and cathode, respectively, in the biofuel cell arrangement.

97 The biofuel cell assembly produced a linear dynamic range of

98 - and membrane-free enzymatic glucose/oxygen biofuel cell based on transparent and nanostructured con

99 nes was quantified at the levels expected in biofuel cell electrodes.

100 When operated in 45 mM glucose, the biofuel cell exhibited an open circuit voltage and power

101 ysiological glucose concentration (5mM), the biofuel cell exhibits open circuit voltage and power den

102 The biofuel cell generated maximum power output of 130microW

103 In this study, a supercapacitor/biofuel cell hybrid device was prepared by the immobilis

104 he input voltage (as low as 0.25 V) from the biofuel cell is converted to a stepped-up power and char

105 lectron transfer (DET) based sulphite/oxygen biofuel cell is reported that utilises human sulphite ox

106 This study focuses on an improved biofuel cell operating on phorbol myristate acetate (PMA

107 The contact lens biofuel cell presented here is a step toward achieving s

108 In the optimum conditions the biofuel cell produced the power density of 1.713 mW cm(-

109 The biofuel cell structure-based glucose sensor synergizes t

110 or glucose oxidation is of great interest in biofuel cell technology because the enzyme are unaffecte

111 Contact lens biofuel cell testing was performed in a synthetic tear s

112 A contact lens biofuel cell was fabricated using buckypaper electrodes

113 ently used in a conventional two-compartment biofuel cell where the power density output was recorded

114 ity obtained from the continuously operating biofuel cell with a maximum power output of 0.086microW/

115 -2) , a new efficiency record for a hydrogen biofuel cell with base metal catalysts.

116 eview highlights the progress on implantable biofuel cell, with focus on the nano-carbon functionaliz

117 - and membrane-free enzymatic glucose/oxygen biofuel cell.

118 advantages of both the glucose biosensor and biofuel cell.

119 yme electrodes were integrated to a DET-type biofuel cell.

120 As a proof of biofuels cell conception, the bioanode was combined with

121 ntegration of supercapacitors with enzymatic biofuel cells (BFCs) can be used to prepare hybrid devic

122 Enzymatic biofuel cells (BFCs) may power implanted medical devices

123 Enzymatic biofuel cells (EBFCs) are capable of generating electric

124 Enzymatic biofuel cells (EBFCs) can generate energy from metabolit

125 MCOs have been used to elaborate enzymatic biofuel cells (EBFCs), a subclass of fuel cells in which

126 this HTPS/GOx-based electrode in long-lived biofuel cells and amperometric biosensors.

127 catalysis promises to be valuable for future biofuel cells and biosensors.

128 sensor opens new doors for implementation of biofuel cells and capacitor circuits for medical diagnos

129 riety of applications, including implantable biofuel cells and self-powered sensors.

130 g electrochemical paper-based biosensors and biofuel cells and to identify, at the light of newly acq

131 Biofuel cells are bio-electrochemical devices, which are

132 Enzymatic biofuel cells are bioelectronic devices that utilize oxi

133 Glucose biofuel cells are capable to generate sufficient power f

134 These findings show that glucose biofuel cells can be further investigated in the develop

135 Enzymatic biofuel cells can generate electricity directly from the

136 neration by flow through miniature enzymatic biofuel cells fed with an aerated solution of glucose an

137 s the advancements in the field of enzymatic biofuel cells over the last 30 years.

138 Biofuel cells that generate electricity from glucose in

139 The maximum power densities of biofuel cells using CA, EC and EPC electrodes without BQ

140 Biofuel cells utilize vegetable and animal fluids (e.g.

141 nd electrode configuration in biosensors and biofuel cells will be discussed.

142 as employed to prepare the enzyme anodes for biofuel cells, and the EAPC anode produced 7.5-times hig

143 the feasibility of POx-based biosensors and biofuel cells, the enzyme electrodes were prepared using

144 me in electrochemical glucose biosensors and biofuel cells, was measured between pH 4.5 and 8.5 using

145 enhance the enzyme functions in implantable biofuel cells.

146 yme immobilization enhancement in glucose/O2 biofuel cells.

147 energy conversion capability in ethanol/air biofuel cells.

148 in LbL thin films relevant to biosensors and biofuel cells.

149 c electrodes for enzyme-based biosensors and biofuel cells.

150 ent delivery vehicles, and as biosensors and biofuel cells.

151 old higher power output than other leukocyte biofuel cells.

152 se monitoring biosensors and high performing biofuel cells.

153 o aid in the development of energy efficient biofuel cells.

154 ion of biosensors, bioanodes, biocathodes or biofuel cells.

155 ation of a novel bioanode for ethanol-oxygen biofuel cells.

156 of its chemical or biological treatment for biofuels, chemicals, or biochar production.

157 ally below the threshold of at least 60% for biofuels classified as cellulosic biofuels under the Ren

158 articular, we parametrize the kOA of biomass/biofuel combustion sources as a function of the black ca

159 energy policies have led to an escalation in biofuel consumption at the expenses of food crops and pa

160 rting a PCDD/F formation, when operated with biofuel containing impurities of potassium.

161 cal challenges involved in lignocellulose-to-biofuels conversion.

162 especially deriving from large-scale use of biofuels coupled to carbon capture and storage technolog

163 ase to characterize availability of land for biofuel crop cultivation, and the CERES-Maize and BioCro

164 We investigated changes in biofuel crop production and grassland land covers surrou

165 Here we provide a global assessment of biofuel crop production, reconstruct global patterns of

166 The targeted biofuel crop Sorghum bicolor has a sequenced and well-an

167 ends in epsilon(c )across important food and biofuel crop species.

168 ic model for its close relative and emerging biofuel crop, switchgrass (Panicum virgatum).

169 ction of switchgrass (Panicum virgatum) as a biofuel crop.

170 p production, reconstruct global patterns of biofuel crop/oil trade and determine the associated disp

171 epsilon(c) was greatest in biofuel crops (0.049-0.066), followed by C4 food crops (

172 e efficient and dynamic nitrogen foraging in biofuel crops like poplar.

173 crop choice (first versus second generation biofuel crops), infrastructure development, and environm

174 modity crop prices and federal subsidies for biofuel crops, such as corn and soybeans, have contribut

175 r study demonstrates a continual increase in biofuel crops, totaling 1.2 Mha, around registered apiar

176 ity (yield potential) of available lands for biofuel crops.

177 50:50 (by volume) blend of Jet A fuel and a biofuel derived from Camelina oil.

178 hydrogenase, and thus have both medical and biofuel development applications.

179 de-offs between environmental protection and biofuel development objectives.

180 so provides decision support for sustainable biofuel development.

181 litating further prokaryotic LD research and biofuel development.

182 al attention should be given to camelina-JP5 biofuel due to its relatively rapid biodegradation.

183 es being advanced as a source of biomass for biofuel end uses.

184 today with regard to agriculture, medicine, biofuels, environmental decontamination, ecological sust

185 key source of urban ultrafine particles.The biofuel ethanol has been introduced into urban transport

186 titive and environmentally sustainable algal biofuel faces technical challenges that are subject to h

187 Most biofuel facilities are expected to be sited near to feed

188 America, and is being developed as a future biofuel feedstock crop.

189 has recently been recognized as a potential biofuel feedstock crop.

190 tryococcus braunii is considered a promising biofuel feedstock producer due to its prodigious accumul

191 iated with phenotypic traits of interest for biofuel feedstock production.

192 ntially for industrial applications, such as biofuel feedstock production.

193 rge-scale cultivation of poplar for use as a biofuel feedstock will have on air quality, specifically

194 Accurate compositional analysis in biofuel feedstocks is imperative; the yields of individu

195 The cultivation of biofuel feedstocks will contribute to future land use ch

196 entral and North America and are emerging as biofuel feedstocks.

197 ion because of their utility as chemical and biofuel feedstocks.

198 First generation biofuels focused on food crops like corn and sugarcane f

199 d Guerbet-type process for the production of biofuel from ethanol has been developed.

200 Commercial scale production of biofuels from lignocellulosic feed stocks has been hampe

201 The derivation of second-generation biofuels from non-edible biomass is viewed as crucial fo

202 f intermediates towards lignin production in biofuel grasses.

203 such as wheat, barley and several potential biofuel grasses.

204 e (ILUC) -related carbon emissions caused by biofuels has led to inclusion of an ILUC factor as a par

205 lity when transferred to an Escherichia coli biofuel host, with IL resistance established by an inner

206 scale implementation of centrate-based algal biofuel, however, is limited by availability of centrate

207 he most widely used renewable transportation biofuel in the United States, with the production of 13.

208 factor as a part of the carbon intensity of biofuels in a Low Carbon Fuel Standard.

209 tricity directly from the chemical energy of biofuels in physiological fluids, but their power densit

210 substituting low-carbon advanced cellulosic biofuels in place of petroleum.

211 rous published studies of the emissions from biofuels-induced "indirect" land use change (ILUC) attem

212 applications, such as in pharmaceutical and biofuel industries.

213 development for the emerging lignocellulosic biofuel industry.

214 le characteristics for the second-generation biofuels industry.

215 gical target for improving the production of biofuels is the modification of plant cell walls.

216 triacylglycerol (TAG), a promising source of biofuel, is induced upon nitrogen starvation (-N), but t

217 bacterial production of FAMEs and FAEEs for biofuels, it may be easier to optimize and transport the

218 inties for the bulk POA emitted from biomass/biofuel, lignite, propane, and oil combustion sources.

219 gar (sugarcane [Saccharum officinarum]), and biofuel (Miscanthus spp.) producers and contribute appro

220 No natural gas, biofuels, nuclear power, or stationary batteries are nee

221 the impact of fatty acid methyl ester (FAME) biofuel on PCDD/F emissions.

222 To evaluate the important impacts of biofuels on food security, the food-energy nexus needs t

223 m complex chemical conversions of biomass to biofuels or commodity chemicals are emerging as promisin

224 ga into an efficient production platform for biofuels, pharmaceuticals, green chemicals and industria

225 h commercial samples from a distillery and a biofuel plant.

226 , which can be a desirable trait in crop and biofuel plants.

227 duction of approximately 0.5 g of high-value biofuel precursors from a 1.7-g portion of fermentation

228 t implications in engineering more efficient biofuel producers.

229 ng ethanol-induced stresses and responses in biofuel-producing bacteria at systems level has signific

230 c compounds that can inhibit fermentation by biofuel-producing microbes.

231 Given the important role of microbes in biofuel production and bioremediation, a thorough unders

232 or constructing highly effective enzymes for biofuel production and represents the first lignocellulo

233 able approaches to harvesting microalgae for biofuel production and water treatment.

234 GHGs offset by biofuel production are analyzed for five different produ

235 ions to perennial crops that may be used for biofuel production are capable of substantially reducing

236 lly, the cobenefit of wastewater-based algal biofuel production as an alternate means of treating var

237 We show that natural gas can enhance FT biofuel production by reducing the need for water-gas sh

238 dely recognized as a promising candidate for biofuel production due to its ability to store high lipi

239 Advanced biofuel production facilities (biorefineries), such as t

240 ne of the drawbacks during second-generation biofuel production from plant lignocellulosic biomass is

241 Sustainable biofuel production from renewable biomass will require t

242 ay become a valuable reference for improving biofuel production in cyanobacteria, in which Ci is chan

243 Implementing the mandate for cellulosic biofuel production in the Renewable Fuel Standard (RFS)

244 atural gas has the potential to increase the biofuel production output by combining gas- and biomass-

245 ime frame for a range of forest recovery and biofuel production scenarios on abandoned agricultural l

246 forest recovery is superior to low-yielding biofuel production scenarios such as oil palm and corn.

247 Biofuel production scenarios with high yields, such as s

248 posing riverine nitrate-N load limits on the biofuel production system as a whole, including land use

249 and resource assessments of microalgae-based biofuel production systems have relied on growth models

250 wn to markedly reduce uncertainty in cost of biofuel production while also eliminating uncertainties

251 vation and processing must maximize rates of biofuel production while simultaneously minimizing the c

252 have been established as promising tools in biofuel production, a clear understanding of the motor's

253 merican deserts in comparison to agave-based biofuel production, another widely promoted potential en

254 eria are promising organisms for sustainable biofuel production, but several challenges remain to mak

255 great potential as a feedstock for microbial biofuel production, due to their high concentration of f

256 ich represents a major source of biomass for biofuel production, is composed of cellulose, hemicellul

257 elevance to biotechnological applications as biofuel production, the food and animal feed industry.

258 nt biomass (PB) is an important resource for biofuel production.

259 well as lipid accumulating algal strains for biofuel production.

260 use of pectin and alginate as feedstocks for biofuel production.

261 and their biomass composition for downstream biofuel production.

262 ignocellulose and increase the efficiency of biofuel production.

263 rse effects on the downstream processing for biofuel production.

264 tant carbon source for human consumption and biofuel production.

265 ions of this enzyme for levoglucosan-derived biofuel production.

266 lar conversion technologies, heat sinks, and biofuel production.

267 on, could prove useful in industries such as biofuel production.

268 a to produce actionable insights to increase biofuel production.

269 breakdown of lignocellulosic biomass during biofuel production.

270 ol/water mixtures due to their importance in biofuel production.

271 of both first-generation and next-generation biofuel production.

272 of genome engineering to harness diatoms for biofuel production.

273 cell walls that is required for large scale biofuel production.

274 ethylgallate, which are common byproducts of biofuel production.

275 , carbon emissions mitigation via increasing biofuels production resulted in decreases in tree cover,

276 ent and a promising biocatalyst for advanced biofuels production using lignocellulose materials.

277 marine fuel choices significantly; and (iv) biofuels rarely play a major role in the shipping sector

278 totaxis also finds important applications in biofuel reactors and microbiopropellers and is argued to

279 cies among the various subsystems, including biofuel refineries, transportation, agriculture, water r

280 fuels arid regions are best-suited, and for biofuels regions of a moderate and humid climate.

281 Altogether, biofuels rely on about 2-3% of the global water and land

282 Production of competitive microalgal biofuels requires development of high volumetric product

283 ubstantial attention only in recent years as biofuel research moves toward producing drop-in fuels.

284 The biofuels studied contained both low- and high-concentrat

285 missions include their capture into advanced biofuels, such as butanol.

286 the results show that meeting the cellulosic biofuel target in the RFS using Miscanthus x giganteus r

287 etable and animal fluids (e.g. glucose) as a biofuel to produce energy.

288 For algal biofuels to be economically sustainable and avoid exacer

289 ass into a spectrum of products ranging from biofuels to specialty chemicals.

290 st 60% for biofuels classified as cellulosic biofuels under the Renewable Fuels Standard.

291 Impacts per biofuel unit were 30, 750, and 1000 times greater, respe

292 Over the past decade a large increase in biofuel usage, more notably ethanol by light-duty vehicl

293 The prospect of increased biofuel use and mounting evidence on ultrafines' health

294 ch will be useful to assess the potential of biofuel use in aviation as a viable strategy to mitigate

295 nd no data have previously been reported for biofuel use in-flight.

296 anol to hydrocarbon blend-stock can increase biofuels use in current vehicles beyond the ethanol blen

297 Although biofuels will play an important role in conventional gas

298 es and the environmental impact of enhancing biofuels with natural gas.

299 eoff and the impact an increased reliance on biofuel would have on the number of people the planet ca

300 Providing all mobility in the U.S. via crop biofuels would require 130% of arable land with current