ライフサイエンスコーパス: accelerator

1 fraction), delivered from a clinical linear accelerator.

2 dy of its subsequent growth upon exiting the accelerator.

3 dulator in a plasma channel guided wakefield accelerator.

4 t, including real-time imaging on the linear accelerator.

5 ionized by the laser pulse exiting from the accelerator.

6 ate, an oxidation product of a vulcanization accelerator.

7 he high-gradient, nonlinear plasma wakefield accelerator.

8 tumor-surrounding dose of 25 Gy on a linear accelerator.

9 o exchange despite being a rapid GDP release accelerator.

10 , limited by secondary components of the LPA accelerator.

11 15)O, or (16)O(p,pn)(15)O reactions using an accelerator.

12 ma,n)(15)O reaction using an electron linear accelerator.

13 dy (Ab2) as a signaling probe and coreaction accelerator.

14 inct positron bunch in plasma-based particle accelerators.

15 luding the development of staged high-energy accelerators.

16 been hindered by the lack of hospital-scale accelerators.

17 d their potential as compact charge particle accelerators.

18 ages over conventional, large-scale particle accelerators.

19 e larger than those achieved in conventional accelerators.

20 , and short bunch duration over conventional accelerators.

21 iently and can pave way to compact table-top accelerators.

22 ude less than those used in laser wake-field accelerators.

23 ge systems on the currently available linear accelerators.

24 radio-frequency klystrons that power today's accelerators.

25 higher than can radio-frequency cavity-based accelerators.

26 glucose-stimulated expression of cell cycle accelerators.

27 agnitude beyond those accessible at particle accelerators.

28 -ray-free electron lasers driven by electron accelerators.

29 ould be produced without using vulcanization accelerators.

30 e) were not associated with any hypothesised accelerators.

31 bsequently can be run on suitable NVIDIA GPU accelerators.

32 hree provisions were shown to be development accelerators.

33 s of high-repetition rate laser-based proton accelerators.

34 Building on the Accelerator-1 Project, we hypothesized that time to repe

35 tense proton beam from the LUNA 400-kilovolt accelerator(11) and detected the gamma-rays from the nuc

36 American Heart Association Mission: Lifeline Accelerator-2 Project.

37 In these accelerators, a drive beam (either laser or particle) pr

38 tiwall carbon nanotubes as electron transfer accelerator, alcohol dehydrogenase as biocatalyst and po

39 design innovations in high-field magnets for accelerators and compact fusion reactors, and largely de

40 ng those observed in high-intensity particle accelerators and enabling control of an EM field generat

41 er thanks to the advent of powerful electron accelerators and high-rate electron beam treatment (ELT)

42 energy-density science, compact plasma-based accelerators and light sources.

43 cuum electronic devices, particle detectors, accelerators and new types of plasmonic couplers.

44 agrance chemicals, hair dyes, metals, rubber accelerators and preservatives.

45 e as a platform for next generation particle accelerators and sources for electron, x-rays, ions and

46 receptor of C3b/C4b, C3/C5 convertase decay accelerator, and cofactor for factor I-mediated cleavage

47 al for designing multi-stage laser-wakefield accelerators, and generating high-brightness, spatially

48 th electron accelerators, developing cheaper accelerators, and granting government support for pilot

49 The findings suggest the UN's accelerator approach for this high-risk adolescent popul

50 Among these, plasma-based accelerators are arguably the most promising, thanks to

51 Laser-wakefield accelerators are compact devices capable of delivering u

52 The cost, size and availability of electron accelerators are dominated by the achievable acceleratin

53 Compact, table-top sized accelerators are key to improving access to high-quality

54 Plasma-based accelerators are particularly attractive because they ar

55 While compact laser-driven ion accelerators are seeding the development of novel high i

56 de and show promise for dielectric wakefield accelerators as sources of high-energy electrons.

57 bient plasma electrons into the laser-driven accelerator at much lower density than was previously po

58 ver, with the move of HPC facilities towards accelerator based architectures, a need for an efficient

59 , which employs a laser-driven high gradient accelerator based on inverse free electron laser (IFEL),

60 us size and cost of current state-of-the-art accelerators based on conventional radio-frequency techn

61 To address this need, short wavelength accelerators based on wakefields, where an intense relat

62 Accelerator-based ion beam irradiation techniques have b

63 To complement radio-frequency accelerator-based large-scale facilities, novel laser-ba

64 and coherent imaging made possible by linear-accelerator-based light sources.

65 ions being pursued include both reactor- and accelerator-based strategies to sustain the continued av

66 s that use a high-brightness linear electron accelerator-based x-ray source with pulse-by-pulse timin

67 to demonstrate concurrent operation of laser accelerator, beam shaping, dosimetry and irradiation pro

68 g higher acceleration gradient in SRF cavity accelerator beyond the theoretical limit of bulk Nb.

69 annotation, which can serve as an important accelerator both for human and machine-guided exploratio

70 This holds great promise for compact accelerator building blocks and advanced light sources.

71 ead, MDA has been proposed as an elimination accelerator, but the contribution of asymptomatic infect

72 achievable at the most advanced conventional accelerators by orders of magnitude.

73 A compact linear accelerator can be utilized to control the resonant wave

74 particles in a conventional radio-frequency accelerator can reach.

75 locity of the wakefield of a laser wakefield accelerator can, theoretically, be manipulated by shapin

76 the astrophysical neutrino signal comes from accelerators capable of producing cosmic rays of these e

77 acceleration-gradient plasma-based particle accelerators capable of producing ultra-relativistic ele

78 he solar system--are also efficient particle accelerators, capable of energizing a large number of ch

79 f the fields in a nonlinear plasma wakefield accelerator cavity produced by a relativistic electron b

80 42 GeV electron beam at the Stanford Linear Accelerator Center (SLAC).

81 Eliminating the IE2-accelerator circuit reduces transcriptional strength thr

82 With all three development accelerators combined, the probability of adolescents re

83 ce Experimental Facility of the Japan Proton Accelerator Complex (J-PARC) for an iron sample.

84 ISCAS-85 circuit benchmarks, 6 deep-learning accelerator components, and a 32-bit RISC-V ALU, based o

85 ares all these properties with two other "AD accelerator" compounds.

86 New accelerator concepts must be developed to achieve higher

87 The Typhoid Vaccine Accelerator Consortium is playing a critical role in coo

88 rating fields sustainable by radio-frequency accelerators demand for the pursuit of alternative and m

89 This Mission: Lifeline STEMI Systems Accelerator demonstration project represents the largest

90 Equipping research institutes with electron accelerators, developing cheaper accelerators, and grant

91 Micro-fabricated dielectric laser accelerators (DLAs) are an attractive approach, because

92 Dielectric laser accelerators (DLAs) provide a compact and cost-effective

93 k was to display the effect of electron beam accelerator doses on properties of plasticized fish gela

94 Plasma accelerators driven by particle beams are a very promisi

95 Electron accelerators driven with optical or infrared sources hav

96 esults for the production of (99)Mo from the accelerator-driven subcritical fission of an aqueous sol

97 esults for the production of (99)Mo from the accelerator-driven subcritical fission of an aqueous sol

98 have been produced from dithiocarbamate-type accelerators (DTCs) or thiuram-type accelerators (thiura

99 solutions such as photonic pre-processors or accelerators, electronic-photonic hybrid circuits, and n

100 d (12)C ion beam treatment planning (optimal accelerator energies, beam positions, and particle numbe

101 veil the beam loading process underlying the accelerator energy efficiency.

102 beam is the next challenge for plasma-based accelerators envisioned for future light sources and col

103 nt technology used for particle detection in accelerator experiments for several decades, eventually

104 wing number of ever more potent laser-plasma-accelerator facilities worldwide as complementary space

105 rookhaven National Laboratory Laser-Electron Accelerator Facility (LEAF).

106 using 2 GeV Au or Bi ions provided by an ion accelerator facility.

107 catalyst, and the clay minerals acted as an accelerator for both the reductant and catalyst.

108 nous GREtkLUC reporter acts at the CLS as an accelerator for gene induction by GRs in U2OS cells.

109 y populated area is more likely to act as an accelerator for human-human spread but less likely to be

110 RGS proteins primarily act as GTPase accelerators for activated Galpha subunits of G-protein

111 ve the way towards compact, tunable GeV IFEL accelerators for applications such as driving soft X-ray

112 of extremely compact and cost-effective ion accelerators for both established and innovative applica

113 which aims to facilitate the use of graphics accelerators for computational models of large-scale neu

114 e tasks across numerous applications require accelerators for fast and low-power execution.

115 owards demonstrating the viability of plasma accelerators for high-energy physics applications.

116 his protein acts as a brake on the autophagy-accelerator function of HIF-1.

117 absence of the BXSB Y chromosome autoimmune accelerator gene (Yaa), which accelerates disease in mal

118 nd follow-up of six hypothesised development accelerators-government cash transfers to households, sa

119 tron motions of electrons in laser wakefield accelerators has the promise to produce high quality ima

120 Plasma wakefield accelerators have been used to accelerate electron and p

121 Laser wakefield accelerators have great potential as the basis for next

122 Metre-scale plasma wakefield accelerators have imparted energy gain approaching 10 gi

123 Particle accelerators have made an enormous impact in all fields

124 Table-top laser-plasma ion accelerators have many exciting applications, many of wh

125 Laser-driven ion accelerators have the advantages of compact size, high d

126 cheese, irradiated (0-4 kGy) in an electron accelerator, have been studied by electron spin resonanc

127 hereby introducing a cyclodextrin (CD) as an accelerator in CB-AAC, hydrogen bonding networks are for

128 ducing the energy gain of the 3-km-long SLAC accelerator in less than a metre for a small fraction of

129 that H3(K27I/M) mutations are strong disease accelerators in a RUNX1-RUNX1T1 AML mouse model, suggest

130 for various applications of laser-wakefield accelerators, including the development of staged high-e

131 depletion of laser energy, by sequencing the accelerator into stages, each powered by a separate lase

132 zing Magnet System (GAMS) and a 14 MV Tandem accelerator is greatly effective in suppressing this int

133 The plasma wakefield accelerator is one concept being developed for this purp

134 electric field gradients inherent to plasma accelerators is substantial correlated energy spread-an

135 ize and cost of conventional radio-frequency accelerators limit the utility and reach of this technol

136 High-gradient laser-plasma accelerators (LPA) have been proposed as a possible plat

137 Laser-plasma accelerators (LPAs) are capable of accelerating charged

138 Laser Plasma Accelerators (LPAs), delivering GeV electron beams in fe

139 ollable electron trapping in laser wakefield accelerators (LWFA).

140 Laser-wakefield accelerators (LWFAs) are high acceleration-gradient plas

141 Direct accelerator mass spectometry radiocarbon dating and Baye

142 High-precision accelerator mass spectrometer (AMS) (14)C dates of scarl

143 MS) was coupled to a +/- 300 kV single-stage accelerator mass spectrometer (SSAMS).

144 paper, we published a series of radiocarbon accelerator mass spectrometer measurements for the site

145 Accelerator mass spectrometer radiocarbon dates and rean

146 Capable of replacing large accelerator mass spectrometers, the technique quantifies

147 Catalytic graphitization for (14)C-accelerator mass spectrometry ((14)C-AMS) produced vario

148 an loess dust deposits to date, based on 125 accelerator mass spectrometry (14)C ages from Dunaszekcs

149 Here we apply improved accelerator mass spectrometry (14)C techniques to constr

150 The outstanding radiocarbon sensitivity of accelerator mass spectrometry (AMS) allowed the use of [

151 With the advent of accelerator mass spectrometry (AMS) and further developm

152 nd after the FDNPP incident were analyzed by accelerator mass spectrometry (AMS) and inductively coup

153 optimized for various biological/biomedical accelerator mass spectrometry (AMS) applications of mg o

154 Such high sensitivity was possible by using accelerator mass spectrometry (AMS) at the Vienna Enviro

155 es, demonstrating the feasibility of compact accelerator mass spectrometry (AMS) for the determinatio

156 The increasing role of accelerator mass spectrometry (AMS) in biomedical resear

157 Physical combination of an accelerator mass spectrometry (AMS) instrument with a co

158 ion extraction chromatography separation and accelerator mass spectrometry (AMS) measurement.

159 Accelerator mass spectrometry (AMS) measurements of the

160 n this study, we perform very high-precision accelerator mass spectrometry (AMS) measurements on dend

161 We report experiments designed to improve accelerator mass spectrometry (AMS) of (10)Be and (26)Al

162 (14)C labeling combined with accelerator mass spectrometry (AMS) provides exquisite s

163 Accelerator mass spectrometry (AMS) radiocarbon dating s

164 For ultratrace analysis, the Accelerator Mass Spectrometry (AMS) setup of the Technic

165 duction of samples as CO(2) gas into a (14)C accelerator mass spectrometry (AMS) system with a microw

166 Biological and biomedical applications of accelerator mass spectrometry (AMS) use isotope ratio ma

167 iocarbon dates from the recent generation of accelerator mass spectrometry (AMS) versus dates from pr

168 The multiactinide analysis with accelerator mass spectrometry (AMS) was applied to sampl

169 al setup, combining laser ablation (LA) with accelerator mass spectrometry (AMS), has been investigat

170 1.10 kg samples of unsalted market butter by accelerator mass spectrometry (AMS).

171 ation devices with mass spectrometry (MS) or accelerator mass spectrometry (AMS).

172 kg) concentrations accomplished by employing accelerator mass spectrometry (AMS).

173 ith HPLC separation and flux quantitation by accelerator mass spectrometry (AMS).

174 nic compounds for radiocarbon analysis using accelerator mass spectrometry (AMS).

175 We present data obtained at the Center for Accelerator Mass Spectrometry (CAMS) at Lawrence Livermo

176 tography (HPLC) separations by liquid sample accelerator mass spectrometry (LS-AMS).

177 irectly date archaeological pottery based on accelerator mass spectrometry analysis of (14)C in absor

178 (14)C-accelerator mass spectrometry dating and the geological

179 Currently, accelerator mass spectrometry is the predominant tool fo

180 ral nucleotide salvage enzymes followed with accelerator mass spectrometry provided precise quantitat

181 Our accelerator mass spectrometry radiocarbon dates of 14 in

182 A revised chronology based on 26 accelerator mass spectrometry radiocarbon dates on ostri

183 Here, we report a series of accelerator mass spectrometry radiocarbon dates on ultra

184 Here, we show, by accelerator mass spectrometry radiocarbon dating of 23 i

185 We test the accuracy of accelerator mass spectrometry radiocarbon dating of 29 h

186 In addition, accelerator mass spectrometry radiocarbon determinations

187 n 1989, it was directly radiocarbon dated by accelerator mass spectrometry to 36.4-34.7 kyr cal BP.

188 hese labeled phytochemicals allow the use of accelerator mass spectrometry to trace the tissue distri

189 A series of 31 accelerator mass spectrometry ultrafiltered dates on bon

190 cted from five deep-sea sediment samples and accelerator mass spectrometry was used for single-atom c

191 Using the sensitive technique of accelerator mass spectrometry, coupled with high-perform

192 -12) in (14)C/(12)C ratios, as determined by accelerator mass spectrometry, is demonstrated.

193 Using accelerator mass spectrometry, this signal was found thr

194 and (36)Cl/(35)Cl ratios were performed with accelerator mass spectrometry.

195 es, the final sample was measured by compact accelerator mass spectrometry.

196 dosed guinea pigs analyzed by both CRDS and accelerator mass spectrometry.

197 technique to the more expensive and complex accelerator mass spectrometry.

198 genetic approaches, and dating through (14)C accelerator mass spectrometry.

199 y using ultraclean laboratory procedures and accelerator mass spectrometry.

200 ratio in the separated uranium target using accelerator mass spectrometry.

201 ruary 2005) and summer (June-August 2005) by accelerator mass spectrometry.

202 icrodoses of a radio-microtracer measured by accelerator mass spectrometry.

203 g chromatographic separation and analysis by accelerator mass spectrometry.

204 -oxodG in MCF-7 human breast cancer cells by accelerator mass spectrometry.

205 eces were measured for (14)C with the use of accelerator mass spectrometry.

206 5) ((14)C/(12)C), i.e., in the same order as accelerator mass spectroscopy, achieved with a relativel

207 tonuclear reactions using an electron linear accelerator may allow for feasible and economical produc

208 In general, accelerators may provide a mechanism for signal-transduc

209 The use of a 1 cm long wakefield accelerator means that the length of the beamline (exclu

210 in are the development of macromolecular ion accelerator (MIA) and the results obtained by MIA.

211 ck all independent components, including all accelerator modules and all external optical lasers, to

212 n gas MS, Auger EM, resonance ionization MS, accelerator MS, transmission EM, focused ion-beam micros

213 ffective solution to this problem by driving accelerator nanostructures with visible or near-infrared

214 of sources, such as cosmic events, particle accelerators, nuclear reactors and clinical radionuclide

215 0.020 GeV m(-1) using a dielectric wakefield accelerator of 15 cm length, with sub-millimetre transve

216 han 42 GeV is achieved in a plasma wakefield accelerator of 85 cm length, driven by a 42 GeV electron

217 ronary diastolic suction wave (the principal accelerator of coronary blood flow).

218 These results demonstrate that AtELP2 is an accelerator of defense gene induction, which functions l

219 that the XPC DNA repair complex is a potent accelerator of global and locus-specific DNA demethylati

220 ut CKD can also be viewed conceptually as an accelerator of traditional cardiovascular risk factors.

221 itch from a mediator of cell death toward an accelerator of tumor progression.

222 e debate as to whether obesity can act as an accelerator of type 1 diabetes (T1D).

223 milarly acted as activators of PPH genes and accelerators of chlorophyll degradation.

224 autoantibodies to cryptic antigens as novel accelerators of kidney dysfunction and acute or chronic

225 Laser-plasma accelerators of only a centimetre's length have produced

226 ular diseases can be considered superimposed accelerators of this underlying process.

227 s across multiple SDGs-and synergies between accelerators on achieving SDG-aligned targets in a highl

228 This would enable compact table-top accelerators on the MeV-GeV (10(6)-10(9) eV) scale for s

229 By comparison, conventional modern linear accelerators operate at gradients of 10-30 MeV m(-1), an

230 lly visualize, for example, plasma wakefield accelerators, optical rogue waves or fast ignitor pulses

231 ndred shorter than those of state-of-the-art accelerators optimized for high instantaneous flux.

232 ifficulty in control and optimization of the accelerator outputs due to coupling between input parame

233 tioning beyond the pause-release step as an "accelerator" over specific early gene body regions.

234 ron beam diagnostics of accelerators used by accelerator physicists.

235 lecting structures (TDSs) are widely used in accelerator physics to measure the longitudinal density

236 potential applications in plasma physics and accelerator physics.

237 maceutical metabolites, rubber vulcanization accelerators, plasticizers, and flame retardants.

238 The Accelerator program increased uptake of key care process

239 The Mission: Lifeline STEMI Systems Accelerator program, implemented in 16 US metropolitan r

240 utics, Leukemia and Lymphoma Society Therapy Accelerator Program.

241 Laser wakefield accelerators promise to revolutionize many areas of acce

242 ow that the XFEL driven by a superconducting accelerator provides unprecedented beam stability within

243 uesting additional evidence to inform which 'accelerator' provisions can simultaneously reduce multip

244 Programme's proposed approach of development accelerators-provisions that lead to progress across mul

245 The plasma wakefield accelerator (PWFA) embodies one such concept, in which t

246 Plasma Wakefield Accelerators (PWFA) offer both, making them attractive c

247 elerating gradients in conventional particle accelerators, reaching high energy typically demands use

248 Particle accelerators represent an indispensable tool in science

249 However, laser-driven wakefield accelerators require intense femtosecond sources and dir

250 We use a neutral-atom accelerator ring to bring BECs to very high speeds (16 t

251 ators promise to revolutionize many areas of accelerator science.

252 ligned targets, a combination of two or more accelerators showed cumulative positive associations, su

253 ddition to their established roles as fusion accelerators, SM proteins Sly1 and Vps33 directly shield

254 railing positron bunch in a plasma wakefield accelerator, spanning nonlinear to quasi-linear regimes,

255 diates the demanded fields directly into the accelerator structure or medium, are currently under int

256 rmacy (nuclear magnetic resonance), particle accelerators (such as the Large Hadron Collider) and fus

257 femtosecond sources and direct laser-driven accelerators suffer from low bunch charge, sub-micron to

258 o the development of next generation compact accelerators suitable for many applications such as isoc

259 cumulative positive associations, suggesting accelerator synergies of combination provisions.

260 Furthermore, MRI-guided linear accelerator systems, allowing use of MRI during treatmen

261 ource based on currently available laser and accelerator technologies, which would be an indispensabl

262 beyond what can be sustained by conventional accelerator technologies, with dynamic beam collimation

263 y particle beams are a very promising future accelerator technology as they can sustain high accelera

264 cting Radio-Frequency cavities are a leading accelerator technology.

265 d acceleration into a compact and affordable accelerator technology.

266 lectron diffraction (UED) experiments at the Accelerator Test Facility II (ATF-II) at Brookhaven Nati

267 he feasibility of a high energy neutral atom accelerator that could significantly impact applications

268 nit-specific with RFC-C Arg-88 serving as an accelerator that enables rapid ATP hydrolysis upon conta

269 We propose GateKeeper, a new hardware accelerator that functions as a pre-alignment step that

270 istic electron bunches in a compact electron accelerator that we believe will revolutionize experimen

271 1s instead function as pollen tube emergence accelerators that favor conspecific pollen over pollen f

272 of clusters, as well as the influencers and accelerators that give insight as to why a cluster exist

273 tallations and facilities including particle accelerators the EM field control is required.

274 One such wakefield based accelerator, the dielectric wakefield accelerator, uses

275 When coupled with a laser-plasma accelerator, this undulator constitutes a millimetre-siz

276 ate-type accelerators (DTCs) or thiuram-type accelerators (thiurams) during the vulcanization process

277 We map the accelerator to a highly self-cooperative transcriptional

278 ells were also irradiated with a 6 MV linear accelerator to assess the biological consequence of radi

279 sts (Fe-N-C SACs) as an advanced co-reactant accelerator to directly reduce the dissolved oxygen (O(2

280 ron beam from a 2 MeV Van de Graaff electron accelerator to generate a high concentration of hydroxyl

281 (MCP) detector is mounted at the end of the accelerator to record the ion signals.

282 ilds on the inherent ability of laser-plasma-accelerators to directly produce broadband Maxwellian-ty

283 Scaling these compact accelerators to multi-gigaelectronvolt energy would open

284 ty of utilizing plasma undulators and plasma accelerators to produce compact ultraviolet and X-ray so

285 Manipulating these ion accelerators, to convert the fast ions to neutral atoms

286 Unlike conventional accelerators, transient quasi-static charge separation a

287 r being possible with future laser-wakefield-accelerator ultrafast-electron-diffraction schemes.

288 ific applications such as table-top particle accelerators, ultrafast imaging systems and laser fusion

289 the traditional electron beam diagnostics of accelerators used by accelerator physicists.

290 based accelerator, the dielectric wakefield accelerator, uses a dielectric lined-waveguide to suppor

291 y (AMS) at the Vienna Environmental Research Accelerator (VERA) with extreme selectivity and recently

292 and the first linear radio-frequency cavity accelerator was ten radio-frequency periods (one metre)

293 While arthropod CCAP is a cardio-accelerator, we found that conoCAP-a decreases the heart

294 Using laser-plasma-accelerators, we reproduced relativistic, broadband radi

295 rning techniques to automate a 100 MeV-scale accelerator, which optimized its outputs by simultaneous

296 ng global thermodynamics of multi-GeV plasma accelerators, which underlie their viability for applica

297 The ultimate utility of plasma accelerators will depend on sustaining ultrahigh acceler

298 These ultra-compact terahertz accelerators with extremely short electron bunches hold

299 he realisation of cheap and compact particle accelerators with femtosecond scale control of particles

300 uctures enable high-gradient electron/proton accelerators with simple accelerating structures, high r