ライフサイエンスコーパス: exfoliation

1 he interlayer cations, resulting in the fast exfoliation.

2 sceptible to sonochemical degradation during exfoliation.

3 underwent caspase-1-associated cytolysis and exfoliation.

4 two-dimensional (2D) nanosheets using liquid exfoliation.

5 and quantitation of epithelial recovery from exfoliation.

6 roviding unique structural insights into the exfoliation.

7 ned by molecular beam epitaxy and mechanical exfoliation.

8 a, and it illuminates mechanistic aspects of exfoliation.

9 N-based heterostructures involve transfer or exfoliation.

10 fragments, resulting in their degradation or exfoliation.

11 e, and expanding the van der Waals gap until exfoliation.

12 surfactant-mediated synthesis and subsequent exfoliation.

13 ap, but the latter has only been produced by exfoliation.

14 pic monolayers from conventional Scotch tape exfoliation.

15 2)Te(4)] and [Bi(2)Te(3)] layers possible by exfoliation.

16 these nanomaterials, such as in liquid-phase exfoliation.

17 contributing to disrupted tooth movement and exfoliation.

18 OER electrocatalysts by water-plasma-enabled exfoliation.

19 widely synthesized using techniques such as exfoliation(1-3) and vapour-phase growth(4,5), it is sti

20 The MD difference values were higher in the exfoliation (- 3.17 dB) than in the primary open-angle (

21 induced differences in Gibbs free energy of exfoliation; (3) dispersion of MoS2 in aqueous solution

22 The difference was higher in the exfoliation (- 7.65%) than in the primary open (- 1.90%)

23 formation on graphene during electrochemical exfoliation, a series of reducing agents as additives (e

24 with the help of liquid surfactants or solid exfoliation agents, as ball milling of bulk precursor ma

25 um unit plays the pivotal role for both self-exfoliation and antibacterial property against both Gram

26 was prepared by graphite sonication-assisted exfoliation and characterized by transmission electron m

27 s changes from sulphur vacancy in mechanical exfoliation and chemical vapour deposition samples to mo

28 al observations and models of fatigue-driven exfoliation and demonstrate how crack propagation via th

29 ynthesized by a liquid ultrasonication-based exfoliation and deposited on fiber device by an in-situ

30 the most effective solvent for liquid phase exfoliation and dispersion of a range of 2D materials in

31 We have studied the exfoliation and dispersion of hexabenzocoronene (HBC) in

32 ished interlayer interactions that favor the exfoliation and dispersion of individual layers in organ

33 This consists of vacuum-assisted thermal exfoliation and floatation of functional graphenes at el

34 ar are created by an arduous micromechanical exfoliation and manual restacking process(5), which-alth

35 In particular, we discuss the mechanisms of exfoliation and methods that are employed for graphene c

36 planar interface between layers isolated by exfoliation and micromechanically stacked in the desired

37 PD resulted in parallel events of dead cell exfoliation and migration of intact neighbouring cells t

38 The sonochemical exfoliation and modified Hummer's technique for the synt

39 Exfoliation and open-angle glaucoma were defined based o

40 oduction method based on surfactant-assisted exfoliation and postprocessing of black phosphorus in de

41 rsibility of h-BN in water, which limits its exfoliation and preparation of colloidal solutions.

42 r infection induces more rapid and extensive exfoliation and reduced bladder bacterial burdens.

43 lvey uncover the mechanism that induces this exfoliation and reintroduce the pore-forming toxin, hemo

44 Liquid phase exfoliation and size selection were successfully perform

45 aterials have relied on the low-yield manual exfoliation and stacking of individual 2D TMD layers, wh

46 In parallel with the exfoliation and stacking of intrinsically layered crysta

47 ts of borophene through a novel liquid-phase exfoliation and the reduction of borophene oxide is demo

48 o overcome these problems in the traditional exfoliation and then organic modification strategy, an o

49 he GPA showed progression in 58% of cases in exfoliation, and 13% in primary open glaucoma group (Chi

50 w with three key steps: i) pretreatment, ii) exfoliation, and iii) separation.

51 can only be produced by mechanical or liquid exfoliation, and it is still a significant challenge to

52 es, supramolecular preorganization assembly, exfoliation, and template-free synthesis routes, (2) fun

53 echanisms, including micturition, epithelial exfoliation, and the influx of polymorphonuclear leukocy

54 thicknesses of 60-450 nm by micromechanical exfoliation, and their crystalline orientations are iden

55 The microwave-assisted exfoliation approach presents us with a possibility for

56 Similar kinetics of exfoliation are also found in these solvents without fer

57 While their growth on a substrate and their exfoliation are well developed, the colloidal synthesis

58 arve out the chemical changes occurring upon exfoliation, as well as to determine the nanosheet thick

59 hanical and electronic properties, including exfoliation, blue-shifted UV-vis absorption, altered lum

60 CEs then thicken, likely facilitating exfoliation by increasing corneocyte rigidity.

61 2020) find that Neisseria gonorrhoeae blocks exfoliation by producing nitric oxide at the bacterial-h

62 a combined process of chemical or mechanical exfoliation (C/ME) followed by a rapid densification and

63 f the graphene production rate, we show that exfoliation can be achieved in liquid volumes from hundr

64 of MoS(2) nanosheets fabricated by chemical exfoliation (ceMoS(2)) and surfactant dispersion (sMoS(2

65 MoS(2) that cover techniques such as liquid exfoliation, chemical vapour deposition, mechanical exfo

66 Localized photodamage resulted in rapid cell exfoliation coincident with migration of neighbouring ce

67 pplication to the most concentrated graphene exfoliation data available supports these assumptions an

68 model appears to quantitatively fit graphene exfoliation data, and it illuminates mechanistic aspects

69 Recent developments in the exfoliation, dispersion, and processing of pristine grap

70 r Merwe regime growth, while allowing facile exfoliation due to the absence of interfacial forces as

71 Due to the high exfoliation efficiency of this process, the resulting ph

72 d sulfur (S) vacancies intrinsic to chemical exfoliation enables simultaneous modulation of active si

73 tip and surface is enhanced relative to the exfoliation energy of graphite, friction can increase as

74 s on the ratio of tip-sample adhesion to the exfoliation energy of graphite.

75 To validate our criterion, we calculated the exfoliation energy of the suggested layered materials, a

76 ration, crypt abscesses, and epithelial cell exfoliation, erosion, and ulceration.

77 Exfoliation follows highly activated diffusion-controlle

78 eavage energy than graphite, suggesting easy exfoliation for TiS3 .

79 ls and the substrates enables such efficient exfoliation, for which we identify a gold-assisted exfol

80 table, has a low cleavage energy calling for exfoliation from layered Tl2O bulk, and has a very small

81 al ES degeneration, which leads to germ cell exfoliation from the seminiferous epithelium.

82 several parallel mechanisms that orchestrate exfoliation from the surface of normal human skin.

83 diagnoses were open-angle glaucoma (1.61%), exfoliation glaucoma (0.20%), unspecified glaucoma (0.17

84 diagnosis codes for exfoliation syndrome or exfoliation glaucoma (366.11 or 365.52, respectively).

85 egies for primary prevention are lacking for exfoliation glaucoma (EG), which is the most common type

86 isk factor for exfoliation syndrome (ES) and exfoliation glaucoma (EG).

87 It greatly increases risk of exfoliation glaucoma (XFG), a major worldwide cause of i

88 often presents with ocular hypertension and exfoliation glaucoma (XFG).

89 s, of the 54 in the open-angle and 74 in the exfoliation glaucoma group.

90 Exfoliation glaucoma or EGS was strongly age related wit

91 erage consumption in relation to the risk of exfoliation glaucoma or exfoliation glaucoma suspect (EG

92 young adulthood was associated with risk of exfoliation glaucoma or exfoliation glaucoma suspect, su

93 New-diagnosed exfoliation glaucoma patients must be controlled and tre

94 ation to the risk of exfoliation glaucoma or exfoliation glaucoma suspect (EG/EGS).

95 ociated with risk of exfoliation glaucoma or exfoliation glaucoma suspect, supporting an etiologic ro

96 ts with new-diagnosed primary open-angle and exfoliation glaucoma.

97 angle glaucoma, and 106 patients (34.2%) had exfoliation glaucoma.

98 sc hemorrhage, and 35 eyes (18 patients) had exfoliation glaucoma.

99 the first isolation of graphene, mechanical exfoliation has been a key to provide high-quality two-d

100 nkylosis and root resorption up to the tooth exfoliation have occurred frequently.

101 tion, chemical vapour deposition, mechanical exfoliation, hydrothermal reaction, and Van Der Waal epi

102 ng fault lines during chemical oxidation and exfoliation in agitated solutions.

103 Furthermore, exfoliation in aqueous and organic solutions is presente

104 roduced via ultrasonic assisted liquid phase exfoliation in isopropyl alcohol (IPA) using polyvinyl p

105 ted the mechanism and dynamics of urothelial exfoliation in the early acute stages of infection.

106 Exfoliation in these electrolytes leads to graphene with

107 ine imide), PTI, followed by one-step liquid exfoliation in water.

108 The GNs produced by anodic exfoliation increase the MFC peak power density by over

109 and weak out-of-plane interactions enabling exfoliation into two-dimensional layers of single unit c

110 Mechanical exfoliation is a convenient and effective approach to de

111 hrough weak Lewis acid intercalation enabled exfoliation is developed to produce ultralarge FL-BP sin

112 Therefore, the exfoliation is necessary to expose more active sites.

113 The correlation between intercalation and exfoliation is understood at atomic level by DFT calcula

114 Exfoliation is used as a mechanism to remove bacterially

115 ation of graphite to graphene oxide promotes exfoliation, it requires harsh oxidants and leaves the g

116 2) and 2D layers prepared from postsynthesis exfoliation (ITQ-2).

117 rockfalls mainly occur along cliff-parallel exfoliation joints, with rock bridges playing a key role

118 ed on the scotch tape approach, liquid-phase exfoliation (LPE) methods are becoming more and more int

119 tum dots are synthesized via one-step liquid exfoliation method and biosurfactant was used as a funct

120 ne-step and universal Au-assisted mechanical exfoliation method and demonstrate its effectiveness by

121 via the facile, scalable, and mild chemical exfoliation method are further exfoliated to produce thi

122 sions are synthesized by a simple ultrasonic exfoliation method from graphite, where reaggregation is

123 LDH) nanosheet dispersions using a non-toxic exfoliation method in aqueous amino acid solution.

124 Here we demonstrate a universal mechanical exfoliation method of producing freestanding single-crys

125 ation, for which we identify a gold-assisted exfoliation method that underpins a universal route for

126 dots (AMQDs) was developed by a novel liquid exfoliation method.

127 MoS(2) nanosheets were prepared by chemical exfoliation method.

128 in bulk quantity using a liquid-based shear-exfoliation method.

129 escribe a variety of successful liquid-phase exfoliation methods by categorizing them into two major

130 Although solution-based exfoliation methods hold promise for scalable production

131 eview we summarize the current available LDH exfoliation methods.

132 layers called COFene can be derived from the exfoliation of 2D COFs, generating new properties for ap

133 extracted, produced via simple liquid-phase exfoliation of a layered bulk material, g-C3N4.

134 Manganese oxide NS were synthesized via the exfoliation of a layered material, birnessite.

135 ctinomycetemcomitans attachment and enhanced exfoliation of attached P. gingivalis but had no influen

136 rk connecting the Bi(2)O(2)Se units to allow exfoliation of Bi(4)O(4)SeCl(2) to 1.4 nm height.

137 values of graphite, which indicates that the exfoliation of BiI3 is highly feasible.

138 ) data; its accuracy is demonstrated for the exfoliation of black and violet phosphorus (yielding mon

139 strategies have been developed for scalable exfoliation of black phosphorus, these techniques have t

140 The facile exfoliation of bulk CaCuSi(4)O(10) into nanosheets is es

141 red h-BN nanosheets (BNNS) using a novel gas exfoliation of bulk h-BN in liquid N2 (L-N2 ).

142 r few-layered TMDs - obtained either through exfoliation of bulk materials or bottom-up syntheses - a

143 astasis of OvCa involves direct extension or exfoliation of cells and cellular aggregates into the pe

144 al ovarian cancer (EOC) metastasis occurs by exfoliation of cells and multicellular aggregates (MCAs)

145 Exfoliation of COF layers was simultaneously observed wi

146 g(-1) specific surface area are prepared by exfoliation of crystalline KxMnO2 and subsequent reassem

147 phene sheets were produced by dispersion and exfoliation of functionalized graphite in ethylene glyco

148 The findings on exfoliation of graphene sheets and related adsorption pr

149 Here we report a prompt electrochemical exfoliation of graphene sheets into aqueous solutions of

150 ve and scalable method based on liquid-phase exfoliation of graphite (LPE) holds potential for applic

151 phene oxide (GO), is the product of chemical exfoliation of graphite and has been known for more than

152 al cosolvent concentration for the effective exfoliation of graphite and molybdenum disulphide in wat

153 hrough the sonochemical method, simultaneous exfoliation of graphite and the reduction of gold chlori

154 te in styrene results in the mechanochemical exfoliation of graphite flakes to single-layer and few-l

155 hough GO can be easily prepared by oxidation-exfoliation of graphite in agitated solutions, the size

156 thod based on the controlled electrochemical exfoliation of graphite in aqueous ammonium sulfate elec

157 Efficient exfoliation of graphite in solutions to obtain high-qual

158 Thus, HCG and HCNDG were prepared by exfoliation of graphite in the presence of liquid-phase,

159 The latter occurs via exfoliation of graphite into graphene.

160 eral, this robust method for electrochemical exfoliation of graphite offers great promise for the pre

161 Graphene powders are prepared by the exfoliation of graphite or the reduction of graphene oxi

162 efficiencies of the top-down electrochemical exfoliation of graphite, the electrochemical reduction o

163 ed to improve the efficiency of liquid-phase exfoliation of graphite, with the photochromic molecules

164 l groups that are introduced during chemical exfoliation of graphite.

165 ayer graphene films prepared by liquid phase exfoliation of graphite.

166 The controlled exfoliation of hexagonal boron nitride (h-BN) into singl

167 This novel gas exfoliation of high surface area BNNS not only opens up

168 layer graphene created during nanomechanical exfoliation of highly oriented pyrolytic graphite.

169 id recruitment of neutrophils and subsequent exfoliation of infected bladder cells.

170 ltaneous anodic and cathodic electrochemical exfoliation of iso-molded graphite electrodes.

171 Recent research has focused on the exfoliation of layered materials and then restacking the

172 ochemical modification is shown to influence exfoliation of layered materials in NMP and the optical

173 Exfoliation of layered materials such as graphite and tr

174 Our study provides critical insight into the exfoliation of layered materials, and defines a rational

175 ional design of a cosolvent approach for the exfoliation of layered materials.

176 nmentally friendly pathway to the high yield exfoliation of layered materials.

177 red using a multi-step approach based on the exfoliation of layered MFI, followed by centrifugation t

178 This paper reports a thermal exfoliation of metal-organic framework crystals with int

179 ared the most stable 1T-MoS2 by hydrothermal exfoliation of MoS2 nanosheets vertically rooted into ri

180 Surfactant mediated exfoliation of multilayer graphene and its effects on ph

181 groups in water, facilitating the effective exfoliation of single-layer nanosheets in aqueous soluti

182 eld sonication-assisted aqueous liquid phase exfoliation of size-selected nanomaterials.

183 Micromechanical exfoliation of the dye-modified crystals results in thin

184 ladder immune responses, including extensive exfoliation of the epithelium.

185 r Waals heterostructures, demonstrate direct exfoliation of the highly crystalline and oriented 2DP f

186 Exfoliation of the hybrid material in organic solvents s

187 me cations, for example, Ni(2+) , facilitate exfoliation of the layers, providing a facile synthetic

188 an association between exfoliation syndrome (exfoliation of the lens capsule) and pelvic organ prolap

189 Exfoliation of the semiconducting nanotube bundles occur

190 Exfoliation of the superficial epithelial layer acts to

191 spersed suspension of zeolite nanosheets via exfoliation of their lamellar precursors have been hampe

192 The liquid-phase exfoliation of tin(II) sulfide to produce SnS nanosheets

193 stacking becomes weak, resulting in the easy exfoliation of TPA-COF into ultrathin 2D NSs.

194 d facile method for effective layer-by-layer exfoliation of transition metal dichalcogenides (TMDs) a

195 Exfoliation of two-dimensional materials is key to obtai

196 n, a simple top-down approach for the liquid-exfoliation of ultra-small germanene quantum dots (GeQDs

197 Gold-mediated exfoliation of ultralarge optoelectronically perfect mon

198 anomaterials has been largely limited to the exfoliation of van der Waals solids.

199 This spreading, or exfoliation, of graphite at an oil/water interface stabi

200 tability, possible restacking prevents their exfoliation on to few thin layered CONs from crystalline

201 loss under homeostatic conditions and after exfoliation or appendage amputation.

202 s that can be activated during physiological exfoliation or artificial extraction.

203 t established procedures (such as mechanical exfoliation or chemical vapour deposition) are not ideal

204 Self-exfoliation phenomenon has been supported by molecular d

205 molybdenum disulphide prepared by mechanical exfoliation, physical and chemical vapour deposition.

206 , which can be referred to as a pulsed laser exfoliation (PLE) process.

207 A programmed exfoliation procedure was further employed to orderly la

208 nosheets as a tool to indirectly monitor the exfoliation process and carve out the chemical changes o

209 the fundamental factors governing the liquid exfoliation process and the rational design of a cosolve

210 First is the consistency of its exfoliation process in increasing the yield and in produ

211 The protein exfoliation process is carefully investigated with vario

212 raphene is selectively removed with a second exfoliation process with a Au film, resulting in a monol

213 functionalization during the electrochemical exfoliation process.

214 liminate these radicals and thus control the exfoliation process.

215 tructure in metastable phases induced by the exfoliation process.

216 ighlighting the need for stable solvents and exfoliation processes to minimise the influence of solve

217 Lithiation-exfoliation produces single to few-layered MoS2 and WS2

218 Solvent-induced exfoliation provides monolayer sheets of the 2DP.

219 eration, including nanomaterial synthesis or exfoliation, purification, separation, assembly, hybrid

220 foliates larger flakes and that the graphene exfoliation rate and flake dimensions are strongly corre

221 iate larger graphene flakes which causes the exfoliation rate to decrease as a function of sonication

222 ultrasonication strategies resulting in low exfoliation rates, low material yields and wide flake si

223 and to eliminate the need for postsynthesis exfoliation, respectively.

224 Remarkably, TEMPO-assisted exfoliation results in large graphene sheets (5-10 mum o

225 acing of the lamellar mesostructure; further exfoliation results in nanobelts with minimum sizes arou

226 during which a physician collected cervical-exfoliation samples for conventional cytology and sexual

227 Solution-phase exfoliation seems to address the scalability issues and

228 signatures for the surfaces of two granitic exfoliation sheets, consistent with the expectation that

229 role in the stability of partially detached exfoliation sheets.

230 The described electrochemical exfoliation shows great promise for the industrial-scale

231 Here, we describe a novel chemical-exfoliation spark-plasma-sintering (CE-SPS) nano-structu

232 ene colloidal stability is distinct from the exfoliation step and is dependent upon graphene interact

233 n strategy, an organic modification and then exfoliation strategy was explored in this work for prepa

234 compounds make them ultimate precursors for exfoliation studies, thus paving a way toward two-dimens

235 res through the interface engineering of the exfoliation substrate using a sub-5 nm polymeric film.

236 al phases electrical conductivity, degree of exfoliation, surface functionalization, strong photolumi

237 LOXL1 is a major genetic risk factor for exfoliation syndrome (ES) and exfoliation glaucoma (EG).

238 The presence of an association between exfoliation syndrome (exfoliation of the lens capsule) a

239 investigated as part of the Utah Project on Exfoliation Syndrome (UPEXS).

240 r exposure may be important risk factors for exfoliation syndrome (XFS) but, to our knowledge, detail

241 PDR1, CHAT, GLIS3, FERMT2, DPM2-FAM102); and exfoliation syndrome (XFS) glaucoma (CACNA1A).

242 Exfoliation syndrome (XFS) is a common, age-related, sys

243 Exfoliation syndrome (XFS) is the most common known risk

244 Exfoliation syndrome (XFS) is the most common recognizab

245 ssociate with a dramatic increase in risk of exfoliation syndrome (XFS), a systemic fibrillopathy, wh

246 Exfoliation syndrome (XFS), the most common recognizable

247 bjective: To examine the association between exfoliation syndrome and pelvic organ prolapse using the

248 The pathophysiology behind exfoliation syndrome appears to involve both genetic and

249 In substudy B, the risk of incident exfoliation syndrome from January 1, 1995, to December 3

250 patients with pelvic organ prolapse (without exfoliation syndrome history) compared with unaffected c

251 ssociated with a 1.56-fold increased risk of exfoliation syndrome in Medicare beneficiaries (OR, 1.56

252 We observed a 48% increased incident risk of exfoliation syndrome in women aged 30 to 65 years at bas

253 ssociation between pelvic organ prolapse and exfoliation syndrome in women enrolled in Medicare in Ut

254 Exfoliation syndrome is a progressive age-related condit

255 Exfoliation syndrome is the most common identifiable cau

256 iseases, Ninth Revision, diagnosis codes for exfoliation syndrome or exfoliation glaucoma (366.11 or

257 Main Outcomes and Measures: Exfoliation syndrome outcome was defined by Internationa

258 azards models were used to estimate incident exfoliation syndrome risk in patients with pelvic organ

259 regression models were used to estimate the exfoliation syndrome risk in women with pelvic organ pro

260 Conclusions and Relevance: The diagnosis of exfoliation syndrome was more frequent in women with pel

261 rp1 and Gpnmb mutations, and mice resembling exfoliation syndrome with a Lyst mutation were compared

262 resource, thus supporting an association of exfoliation syndrome with a nonocular systemic condition

263 Importance: Exfoliation syndrome, an inherited systemic disorder of

264 LOXL1 dysregulation, thought to occur in exfoliation syndrome, may be a contributing factor.

265 e, may share common biological pathways with exfoliation syndrome.

266 ss, baseline intraocular pressure (IOP), and exfoliation syndrome.

267 s albinism, pigment dispersion syndrome, and exfoliation syndrome.

268 the viability and reproducibility of such an exfoliation technique for TMD nanolabels for the develop

269 we utilize a solution-based electrochemical exfoliation technique with bipolar electrodes to manufac

270 N = 1,2,3,...8 prepared using the mechanical exfoliation technique.

271 ) materials together with recent advances in exfoliation techniques have set the foundations for the

272 l dichalcogenide, are isolated with standard exfoliation techniques, and investigated with electron d

273 quent and faster visual field progression in exfoliation than in primary open-angle glaucoma patients

274 m overlying the lymphatic plexuses underwent exfoliation that increased during doxycycline exposure.

275 We present a simple kinetic model for exfoliation that is readily solved analytically.

276 also capable of inducing elongate spermatid exfoliation through its disruptive effects on the organi

277 e stabilizing liquids results in large-scale exfoliation to give dispersions of graphene nanosheets.

278 r Waals crystals facilitate their mechanical exfoliation to monolayer and few-layer two-dimensional m

279 We have developed a simple model that shows exfoliation to occur once the local shear rate exceeds 1

280 Here we utilize mechanical exfoliation to produce a two-dimensional form of a miner

281 Here, we use liquid exfoliation to produce monolayer PbI(2) nanodisks (30-40

282 produced in large quantities by liquid phase exfoliation under ambient conditions in solvents such as

283 ientation of FG layers facilitates its rapid exfoliation upon mixing during composite formation.

284 re visual field progression in new-diagnosed exfoliation versus open-angle glaucoma patients.

285 at orchestrates the infected epithelial cell exfoliation via cytolytic granules.

286 alled carbon nanotubes, following outer wall exfoliation via oxidation and high-temperature reaction

287 e cases the currently accepted criterion for exfoliation was satisfied.

288 To address the cellular basis for normal exfoliation, we compared changes in lamellar bilayer arc

289 In addition, exfoliation weakened the competition between phenanthren

290 s highly activated and undergoes spontaneous exfoliation when reacted with diazonium ions to produce

291 mation of a tribofilm on the worn surface by exfoliation; whereas CNTs contributed to the improvement

292 a coli (UPEC) induce bladder epithelial cell exfoliation, which eliminates infected cells and promote

293 solate single-polymer strands via mechanical exfoliation, which makes it possible to study individual

294 s (BP NPs) by solution based electrochemical exfoliation with bipolar electrodes, which induces oppos

295 MoS2 nanosheets fabricated by chemical exfoliation with n-butyl-lithium are a mixture of 1T (pr

296 process connects the scalability of chemical exfoliation with the simplicity of solution processing,

297 that solution processing based on programmed exfoliation would be a powerful tool to produce new conf

298 o known oxidants, but at the cost of limited exfoliation yield and flake size distribution.

299 e oxide with large lateral dimensions has an exfoliation yield of ~100%, but it has not been possible

300 molecular size has an important role in the exfoliation yield, attributed to the larger steric repul