ライフサイエンスコーパス: glassy

1 This does not prevent 3D systems from being glassy.

2 orescence is observed from these clusters in glassy 2-methyltetrahydrofuran and in the solid state at

3 and crystallization of three multicomponent glassy alloys, Al86Y7Ni5Co1Fe0.5Pd0.5, Al85Y8Ni5Co1Fe0.5

4 ot previously observed in crystallization of glassy alloys, and seems to originate from instability o

5 amorphous ice, also called vitreous water, a glassy and amorphous solid.

6 The glassy and rubbery states of the bound polymer as temper

7 dye, we observe lasing from the CLCE in both glassy and rubbery states.

8 The formation of ultraviscous, glassy, and amorphous gel states in aqueous aerosol foll

9 in particular that the water dynamics become glassy, and diffusion of lipids in the apposed leaflets

10 nderstanding of bacterial physiology, as the glassy behavior of the cytoplasm impacts all intracellul

11 , we find the conditions when it can exhibit glassy behaviour, which represents a kind of synchronous

12 crystals and other complex materials such as glassy C-S-H, natural composite structures, and manmade

13 Bare glassy carbon (GC), bismuth-coated glassy carbon (Bi-GC), and mercury-coated glassy carbon

14 d of electrically coupled but well-separated glassy carbon (GC) and boron-doped diamond (BDD) electro

15 mercury in aqueous solutions was studied at glassy carbon (GC) and indium-tin oxide (ITO) electrodes

16 This complex was electropolymerized on glassy carbon (GC) and multiwalled carbon nanotube (MWCN

17 enes (HFs) nano-complex was immobilized on a glassy carbon (GC) electrode and protected with a chitos

18 The WC NTs supported PtNPs modified glassy carbon (GC) electrode is highly sensitive toward

19 In this work, a CNF modified glassy carbon (GC) electrode that was coated with Nafion

20 rbon nanotubes (MWCNTs) was used to modify a glassy carbon (GC) electrode to detect trace concentrati

21 onium cation is covalently attached onto the glassy carbon (GC) electrode via graphene nanosheets (GN

22 ation of UA, Try and AP using N-CDs modified glassy carbon (GC) electrode was demonstrated for the fi

23 i-walled carbon nanotubes (f-MWCNs) modified glassy carbon (GC) electrode was developed for determina

24 n the PEDOT-rGO-Fe2O3-PPO composite modified glassy carbon (GC) electrode.

25 Glassy carbon (GC) electrodes are well-known to contain

26 ammetric experiments undertaken at macrodisk glassy carbon (GC) electrodes for oxidation of ferrocene

27 performance of boron-doped diamond (BDD) and glassy carbon (GC) electrodes for the electrochemical ox

28 raphy (mu-ECoG) arrays with platinum (Pt) or glassy carbon (GC) electrodes were manufactured.

29 thering of DNA probes, where highly reactive glassy carbon (GC) substrates are prepared via electroch

30 The SC electrodes were built on Au, Pt, and glassy carbon (GC) substrates using galvanostatically de

31 Glassy carbon (GC) working electrodes were first coated

32 Bare glassy carbon (GC), bismuth-coated glassy carbon (Bi-GC)

33 able carbon supporting electrodes, including glassy carbon (GC), boron-doped diamond (BDD), and scree

34 (BPG), edge plane pyrolytic graphite (EPG), glassy carbon (GC), or high-purity graphite (HPG) electr

35 five different classes of carbon electrodes: glassy carbon (GC), oxygen-terminated polycrystalline bo

36 NTs or traditional carbon electrodes such as glassy carbon (GC).

37 ed glassy carbon (Bi-GC), and mercury-coated glassy carbon (Hg-GC) electrodes were compared for the C

38 trate that copper nanoparticles supported on glassy carbon (n-Cu/C) achieve up to 4 times greater met

39 cursors (such as graphite, amorphous carbon, glassy carbon and C60).

40 Here we demonstrate immobilization on glassy carbon and carbon paper in an ink composed of the

41 trometry is used to characterize the fate of glassy carbon at water oxidizing potentials and demonstr

42 For the first time, glassy carbon beads were asymmetrically modified with bi

43 s were performed in which the potential of a glassy carbon disk electrode was linearly scanned in the

44 tammetry with a silver nanoparticle-modified glassy carbon electrode (AgNP-GCE) in aqueous solutions

45 oparticles decorated graphene oxide modified glassy carbon electrode (AgNPs@GO/GCE).

46 s(3+) in aqueous solution by a AuNP modified glassy carbon electrode (Aunano@GCE) using the electroch

47 trode (SGE) and a gold nanoparticle-modified glassy carbon electrode (AuNPs-GCE) was demonstrated.

48 e electrochemical deposition on DNA modified glassy carbon electrode (DNA/GCE) surface.

49 ium nanoparticles (Ru NPs) are formed on the glassy carbon electrode (GC) at electrodeposition potent

50 n of haemoglobin in human red blood cells on glassy carbon electrode (GC) was demonstrated.

51 ion@silver6 (rGO-Nf@Ag6) nanohybrid modified glassy carbon electrode (GC/rGO-Nf@Ag6).

52 pared to that of the conventionally employed glassy carbon electrode (GCE) and proved to be more sens

53 lated AuNPs-AOx assembly was stabilized on a glassy carbon electrode (GCE) by chitosan-Nafion mixture

54 zenyl]pyridinium bromide (Br-Py) coated on a glassy carbon electrode (GCE) for the quantitative detec

55 d polymer (MIP) which was synthesized onto a glassy carbon electrode (GCE) in aqueous solution using

56 is covalently attached onto the surface of a glassy carbon electrode (GCE) modified with the nanocomp

57 tructured gold nanoarray was fabricated on a glassy carbon electrode (GCE) surface by using template-

58 atalytic activity along with conductivity of glassy carbon electrode (GCE) surface.

59 This G-Au nanocomposite was used to modify glassy carbon electrode (GCE) to fabricate an electroche

60 nylated capture antibody, immobilized on the glassy carbon electrode (GCE) using streptavidin modifie

61 SB) (TiO2/MWCNT/CHIT/SB) on the surface of a glassy carbon electrode (GCE) was developed for thrombin

62 Glassy carbon electrode (GCE) was fabricated with a thin

63 The surface of the glassy carbon electrode (GCE) was modified by a drop cas

64 The glassy carbon electrode (GCE) was modified with the CAO-

65 d by multi-walled carbon nanotube (MWCNT) on glassy carbon electrode (GCE) were applied as new nanobi

66 ters on the surface, (Cu) m ,(Ag) n |polymer|glassy carbon electrode (GCE), as shown by X-ray photoel

67 A glassy carbon electrode (GCE), modified with multiwall c

68 An immunosensor was built on a glassy carbon electrode (GCE), through the steps of form

69 phene oxide (GO) sheet on the surface of the glassy carbon electrode (GCE).

70 carbon nanotube (PLL/f-MWCNT) film modified glassy carbon electrode (GCE).

71 of GOx was revealed at the RGO-GOx modified glassy carbon electrode (GCE).

72 tion was achieved with the TKec/LDH modified glassy carbon electrode (GCE).

73 carbon nanotube+chitosan composite coated on glassy carbon electrode (GCE/f-MWCNT-Chit@Th) for quick

74 (AMEL) using reduced graphene oxide modified glassy carbon electrode (GCE/RGO) has been developed.

75 voltammetric studies showed that the GO-PcCo/glassy carbon electrode (GO-PcCo/GCE) improves electroch

76 obilized on a graphene/ionic liquid-modified glassy carbon electrode (GR-IL/GCE) to develop a highly

77 was obtained at the Hb-PpPDA@Fe3O4 modified glassy carbon electrode (Hb-PpPDA@Fe3O4/GCE) through dir

78 ed on multi-walled carbon nanotubes modified glassy carbon electrode (MWNT/GCE) in phosphate buffer s

79 onodisperse nickel nanoparticles modified on glassy carbon electrode (Ni@f-MWCNT/GCE) were synthesize

80 The po-Gr-NR hybrid film deposited glassy carbon electrode (po-Gr-NR/GCE) served as the Fe(

81 3-hydroxynaphthalene sulfonic acid)-modified glassy carbon electrode (poly(AHNSA)/GCE) was prepared f

82 was obtained for the TTF(*+/2+) process at a glassy carbon electrode and 2.7 cm s(-1) for the Cc(+/0)

83 ized onto gold nanoparticles (GNPs)-modified glassy carbon electrode as a novel electrochemical platf

84 omposite (ZnO/Cysteic acid) was deposited on glassy carbon electrode by cyclic voltammetry.

85 Glassy carbon electrode coated with this nanocomposite w

86 nanotubes assimilated with beta-cyclodextrin/glassy carbon electrode exhibited catalytic activity tow

87 of MWCNT-polyethyleneimine and MWCNT-DNA on glassy carbon electrode for discriminative detection of

88 nt was tested in conjunction with a modified glassy carbon electrode for glucose detection.

89 ed on the MWCNTs-TiN composite modified on a glassy carbon electrode for nitrite sensing are investig

90 n the short GONRs were adopted to modify the glassy carbon electrode for the electrochemical detectio

91 demonstrated that voltammograms recorded on glassy carbon electrode in Britton-Robinson buffer at pH

92 the AgNPs/CQDs nanohybrid was casted on the glassy carbon electrode in order to prepare an amperomet

93 sible two-electron two-proton reduction on a glassy carbon electrode in sulphuric acid.

94 Generally, a glassy carbon electrode is first covered with gold nanop

95 fferential pulse voltammetry with a modified glassy carbon electrode is presented.

96 This paper describes the application of a glassy carbon electrode modified with a thin film of mes

97 BoNT/A antibody was immobilized on glassy carbon electrode modified with Au nanoparticles/g

98 The sensor was prepared on a glassy carbon electrode modified with lead film recovere

99 repared by drop-casting a silk solution on a glassy carbon electrode modified with multiwalled carbon

100 Glassy carbon electrode modified with rGO-yttria serves

101 The glassy carbon electrode modified with single walled carb

102 Under the optimized conditions, a glassy carbon electrode modified with the imprinted nano

103 cer, a multiwalled carbon nanotubes-modified glassy carbon electrode on which poly(pyrrole propionic

104 Cyclic voltammograms were taken with glassy carbon electrode or screen-printed carbon electro

105 ells or raw blood cells was immobilized on a glassy carbon electrode surface with Nafion films employ

106 ed on the surface of the MWCNT-COOH modified glassy carbon electrode through amide linkage.

107 te sensing platform was directly formed on a glassy carbon electrode through an in situ electrochemic

108 ulti-walled carbon nanotube (MWCNT) modified glassy carbon electrode through layer-by-layer technique

109 bound to the composite material coated on a glassy carbon electrode to complete the immunosensor, ab

110 arboxylic group on the surface of nanoporous glassy carbon electrode to prepare the DNA biosensor.

111 Therefore, the Pd, Ru, and Rh NPs decorated glassy carbon electrode were examined for their efficacy

112 posed system was achieved by modification of glassy carbon electrode with graphene oxide/chitosan fil

113 were prepared through the modification of a glassy carbon electrode with highly cross-linked polyeth

114 ized NKA-LCP material was immobilized onto a glassy carbon electrode, forming a highly stable enzyme

115 adsorption of the iron(II) porphyrin on the glassy carbon electrode, the contribution of the adsorbe

116 sor platform, which is based on the use of a glassy carbon electrode-confined conducting polymer that

117 ue by multi-walled carbon nanotubes modified glassy carbon electrode.

118 O) and polydopamine (PDA) composite modified glassy carbon electrode.

119 nted pyrolytic graphite and voltammetry at a glassy carbon electrode.

120 tform for immobilization of the aptamer on a glassy carbon electrode.

121 es the reduction of CO2 and formic acid on a glassy carbon electrode.

122 and differential pulse (DP) voltammetry at a glassy carbon electrode.

123 functionalized carbon nanotube transducer on glassy carbon electrode.

124 s-Linked Pectin)-Au NPs (gold nanoparticles)/Glassy Carbon Electrode.

125 and its response compared to a conventional glassy carbon electrode.

126 anotubes-bismuth nanocomposite film modified glassy carbon electrodes (BiNPs/Nafion-MWCNTs/GCE) as a

127 phene nanosheets-aryldiazonium salt modified glassy carbon electrodes (GCE) as sensing platform and e

128 oxyl groups (MWCNTf) was developed to modify glassy carbon electrodes (GCE) for the detection of redu

129 The oxidation of glassy carbon electrodes (GCE) modified with SWCNT-Polyt

130 The generated polymer is immobilized onto glassy carbon electrodes (GCE) to generate a metal-organ

131 s been developed at bare and Nafion-modified glassy carbon electrodes (GCE).

132 A voltammetric platform based on modifying glassy carbon electrodes (GCEs) with ruthenium nanoparti

133 nanotubes (SWCNTs) as electrode modifiers on glassy carbon electrodes (GCEs).

134 ave been immobilized using graphene modified glassy carbon electrodes and the memory functions of fer

135 etric response of antioxidant compounds when glassy carbon electrodes are inserted into the pericarp

136 attachment of fungal colony microsamples to glassy carbon electrodes in contact with aqueous acetate

137 f the immobilized enzyme with GO and DDAB on glassy carbon electrodes was carried out by cyclic volta

138 Glassy carbon electrodes were modified with small carbon

139 the developed biosensors were compared with glassy carbon electrodes without CNOs.

140 The films F1 and F2 were cast on the glassy carbon electrodes, covered with an anionic polyel

141 into their corresponding diazonium salts on glassy carbon electrodes.

142 rd electrochemistry relative to metallic and glassy carbon electrodes.

143 consists of successive modification steps of glassy carbon electrodes: (i) creation of COOH groups, (

144 The glassy carbon electrodic substrate was electrochemically

145 in situ laser heating techniques to convert glassy carbon into "quenchable amorphous diamond", and r

146 silicone oil, acting as lipophilic binder of glassy carbon paste electrode, with subsequent electroch

147 degradation of IrO2 particles drop-coated on glassy carbon rotating disk electrode using Nafion as a

148 (on supports and catalysts deposited onto a glassy carbon rotating disk electrode) and in situ (in a

149 al growth process, in aqueous solution, on a glassy carbon substrate has been successfully developed

150 ty as a function of film thickness on Au and glassy carbon substrates are consistent with the hypothe

151 f alkanethiol-capped gold nanoparticles on a glassy carbon support during electrochemical reduction o

152 the level of copper catalyst loading on the glassy carbon support has an enormous impact on the morp

153 GCC-Re species on glassy carbon surfaces display catalytic currents greate

154 Glassy carbon surfaces were modified with -OH, -CH3, -SO

155 technique using an elemental analyzer with a glassy carbon tube and filling (temperature conversion/e

156 ardized using AC impedance-spectroscopy with glassy carbon working electrode and platinum counter/ref

157 RuNP decorated on the glassy carbon would be hydrated, which in turn assist to

158 An electrode substrate (glassy carbon, carbon cloth) was sequentially dipped for

159 inum, highly ordered pyrolytic graphite, and glassy carbon, was achieved using a very fast, reproduci

160 osited Au nanoparticles (AuNPs) supported on glassy carbon, where subnanoentity (i.e., sub-AuNP) reac

161 l fabricated from lithographically patterned glassy carbon.

162 valent interactions and further deposited on glassy carbon.

163 able using rigid substrates such as glass or glassy carbon.

164 erwise identical arrays prepared on glass or glassy carbon.

165 ized poly-Fe(vbpy)3(PF6)2 film electrodes on glassy carbon.

166 A system with amperometric detection using a glassy-carbon electrode presented high precision (RSD =

167 pension of the nanoconjugate was placed on a glassy-carbon electrode to prepare the recognition/sensi

168 The samples exhibiting glassy characteristics are further characterized.

169 vitrified on arbitrary substrates, producing glassy coats encapsulating biomolecules.

170 gelatin-plasticizer films were stored under glassy conditions (Tg-10 degrees C), previously determin

171 Results showed in samples stored under glassy conditions that the Maillard reaction did not occ

172 matrices that exhibited thermally reversible glassy consistency.

173 matrices that exhibited thermally reversible glassy consistency.

174 composition of molybdenum in five samples of glassy debris from the 1945 Trinity nuclear test has bee

175 , chromatite formed at >1000 degrees C has a glassy disposition that prevents its water-based leachin

176 sing computer simulations, here we show that glassy dynamics in supercooled two- and three-dimensiona

177 ated dynamics, are crucial for understanding glassy dynamics in thin films.

178 Our analysis suggests a picture of glassy dynamics in which two dynamical processes coexist

179 ed on the timescale of packaging, exhibiting glassy dynamics, which slows the motor, causes significa

180 ties of quiescent glasses and relate them to glassy dynamics.

181 and we recover the Adam-Gibbs description of glassy dynamics.

182 usual estimate of the onset temperature for glassy dynamics.

183 a, Cs, Ba, La, Ce, Nd, Sm, Dy, Lu, U, Th) in glassy fallout from the first nuclear test, Trinity, are

184 A cellulose glassy fiber paper conjugate pad retains the marker immu

185 housands of anchor spicules (long, hair-like glassy fibers).

186 Nanometrically thin glassy films depart strikingly from the behavior of thei

187 these materials, is whether the ultra-stable glassy films formed by vapour deposition are ever equiva

188 By contrast, in thin glassy films, we find that particles at the center of th

189 uces a disordered gamma-phase and subsequent glassy freezing at yet lower temperatures.

190 internal stresses-an intrinsic signature of glassy frustration-anharmonicity and low-frequency vibra

191 KEY MESSAGE: Glassy Hair 1 (GLH1) gene that promotes papillae formati

192 on the cell wall surface, we identified the GLASSY HAIR 1 (GLH1) gene, which is necessary for papill

193 rs of magnitude, the viscosity of an organic glassy host at temperatures more than 100 K below its th

194 ssemblage of proxies, including magnetic and glassy impact-related spherules, high-temperature minera

195 a continuous scale from crystalline, through glassy intermediate states, to chaotic configurations.

196 ilicon carbide, diffusion bonded with a thin glassy layer.To improve mechanical properties in ceramic

197 rrangement of particles to a nonergodic soft glassy-like solid, occurs below approximately 40 degrees

198 cally taken to be the temperature at which a glassy liquid is no longer able to equilibrate on experi

199 ed the gap between structure and dynamics in glassy liquids above their dynamical glass transition te

200 ly, geometric motifs have been identified in glassy liquids, but a causal link between these motifs a

201 vskite combines switchable polarization with glassy magnetization, although it lacks long-range magne

202 The latter is a glassy material that resulted from the melting of the na

203 er curve are predicted by the theory of soft glassy materials and have been previously shown to descr

204 The studies on dynamics and deformation in glassy materials are particularly challenging because of

205 While glassy materials can be made from virtually every class

206 relaxation dynamics, reminiscent of soft and glassy materials close to the jamming transition, and mi

207 s with time can be used to classify magnetic glassy materials into two distinct classes.

208 Similarly, collective transport in glassy materials is well documented [for example, J.

209 pproach to performing fundamental studies of glassy materials over a large dynamic range of time scal

210 there is a feasible strategy for identifying glassy materials with high structural stability against

211 ion for the elastic to plastic transition in glassy materials with the capacity for finite plastic fl

212 n principles with the general versatility of glassy materials.

213 the nature of phonon transport in amorphous/glassy materials.

214 ting the versatility and porosity of MOFs to glassy materials.

215 namics is discussed to compare it with other glassy materials.

216 This also applies to glassy materials.

217 two-step relaxation, somehow reminiscent of glassy materials.

218 s applies to both crystals and amorphous and glassy materials.

219 e.g., persistent radicals embedded in frozen glassy matrices).

220 nown conditions of low molecular mobility of glassy matrices, but also with the non-Maillard reactive

221 n exogenous glucose+lysine in a starch-based glassy matrix were studied, using the methods of lumines

222 For (13)C spins on biomolecules frozen in a glassy matrix, electron decoupling reduces the line widt

223 nsistently identified a creased and distinct glassy membranous sheet enveloping the posterior vitreou

224 Although the preparation of glassy MOFs can be achieved by amorphization of crystall

225 ation of crystalline frameworks, transparent glassy MOFs exhibiting permanent porosity accessible to

226 s in new phase-separated bulk MGs containing glassy nanospheres and exhibiting exceptional plasticity

227 It is found that the glassy nanospheres within the shear band dissolve throug

228 Owing to their glassy nature, metallic glasses demonstrate a toughness

229 ather than the much believed rigidity of the glassy network.

230 enhancement in ice nucleation efficiency of glassy organic particles.

231 of semicrystalline, liquid-crystalline, and glassy organic semiconductor thin films down to the sub-

232 st to previous studies on simple mixtures of glassy organics.

233 Liquid and glassy oxide materials play a vital role in multiple sci

234 d that in the Zr-Cu-Al-Ag alloy system fully glassy phase can be obtained in a wide compositional ran

235 s we use the biradical TEKPol dissolved in a glassy phase of ortho-terphenyl (OTP).

236 anic aerosols can exist in highly viscous or glassy phase states.

237 Relaxation dynamics are the central topic in glassy physics.

238 and compare their properties in two distinct glassy polymer hosts.

239 linking the P2VP domains, thereby connecting glassy PS discs with pH-sensitive hydrogel actuators.

240 Despite the glassy regime, the bulk plastic deformation triggered th

241 damental physical understanding of such soft glassy rheology and how it can manifest in such diverse

242 Our results suggest that ubiquitous soft glassy rheology may be a consequence of emergent fractal

243 nching from the high-temperature melt yields glassy rods with diameters exceeding 1 cm, whereas for c

244 For example, the vibrational dynamics of glassy silica at long wavelengths are those of an elasti

245 ing activity was observed on the substratum (glassy silica-titania), when the serum level of the cult

246 e is monitored, revealing the existence of a glassy skyrmion phase at the phase transition field, whe

247 on and the solid residuals of sludge ash and glassy slags would be applied as cementitious materials.

248 upper troposphere SOA should be mostly in a glassy solid phase state.

249 s (TLS) have been a long-standing problem in glassy solids over the last fifty years, and have recent

250 e triplet ground states and DeltaEST of 2 in glassy solvent matrix are determined by a new approach b

251 Films stored in the glassy state (25+/-2 degrees C and 65+/-2% relative humi

252 We call such glassy state a spin jam.

253 ces the mechanical strength of starch in the glassy state and shifts the glass transition temperature

254 e find these particles are in a semisolid or glassy state based upon their behavior when exposed to m

255 ath can be used to tune the system between a glassy state dominated by thermal excitations over energ

256 festation of the glass transition region and glassy state for atmospheric and pressurised samples was

257 uctuations/structures to be preserved in the glassy state for leisurely investigation.

258 a liquid, freezes in the clean limit into a glassy state induced by quantum fluctuations.

259 The glassy state is known to undergo slow structural relaxat

260 Its glassy state is neither fragile nor strong.

261 It occurs just before the glassy state is reached and is preceded by water-like de

262 upon cooling, until dynamical arrest when a glassy state is reached.

263 reverses structural changes and the initial glassy state is recovered.

264 ing cells and promoting the formation of the glassy state of water.

265 any metallic liquid can be vitrified into a glassy state provided that the cooling rate is sufficien

266 hibition of reaction in gelatin films in the glassy state was related to the well-known conditions of

267 wer nucleation and points to an intermediate glassy state where the ions are frozen close to their or

268 propose that collagen I fibrils may be in a glassy state while hydrated.

269 e short-range magnetic ordering (the cluster glassy state) and the canted antiferromagnetism, and the

270 avored when transitioning from the liquid to glassy state, and exhibit the stiffest elastic response

271 latin-based films (bovine and salmon) in the glassy state, in mixtures with low molecular weight plas

272 temperature may be accomplished in a stable glassy state, which can be achieved by removal of water

273 al capsids has been shown to be trapped in a glassy state, with restricted molecular motion in vitro.

274 state transition toward a more stable active glassy state.

275 that surface-melted inorganic NPs are in a 'glassy' state that is an intermediate dynamical state be

276 r findings offer the possibility of creating glassy states and observing super-relaxation in real sys

277 l phase diagrams encompassing fluid, gel and glassy states and offer the possibility to study new pha

278 centration exhibits crossovers among the two glassy states and spin solid.

279 Two different glassy states are distinguished with evolving waiting ti

280 tatistical mechanical theory to identify the glassy states in a protein's dynamics, and we discuss th

281 (HDA and LDA), which could correspond to the glassy states of high- (HDL) and low-density liquid (LDL

282 e, the study of the properties of metastable glassy states requires thermalizing the system in the su

283 ly and directly quantified for amorphous and glassy states that are inaccessible to existing methods.

284 over a temperature range spanning liquid to glassy states.

285 perature range can result in a transition to glassy states.

286 he wax models resemble splash-form tektites, glassy stones formed from molten rock ejected from aster

287 disentangle Mermin-Wagner fluctuations from glassy structural relaxations.

288 buted to nucleotides that form a disordered, glassy structure.

289 hed to room temperature, exhibits a distinct glassy structure.

290 y wires and closed-packed "crystalline" and "glassy" structures in the presence and absence of electr

291 describe how measures developed for studying glassy systems allow quantitative measurement of interfa

292 gy change caused by thermal fluctuations) in glassy systems by a systematic low-temperature expansion

293 During this progress toward equilibrium, glassy systems exhibit a history dependence that has com

294 complicated electron-charge distributions in glassy systems, making a detailed investigation challeng

295 dings break ground for analytical studies of glassy systems, marking an important step towards unders

296 cleation under indentation, even for brittle glassy systems.

297 in the density and molecular orientation of glassy thin films during light irradiation.

298 In a glassy trehalose matrix the Tm for the doubly labeled T4

299 nt stonework, leading to the preservation of glassy walls called 'vitrified forts'.

300 eview the recent research on supercooled and glassy water, focusing on the possible origins of its co