ライフサイエンスコーパス: sintering

1 y coordinated particles and decreases during sintering.

2 heats of interaction were stabilized against sintering.

3 ole of interparticle neck growth in photonic sintering.

4 les with the silicate and poor resistance to sintering.

5 e-regulated rapid solidification followed by sintering.

6 nt insights into the mechanisms that lead to sintering.

7 copic polymeric materials by selective laser sintering.

8 etic deposition followed by high-temperature sintering.

9 pacity even in the course of electrochemical sintering.

10 lusters, limiting growth and suppressing the sintering.

11 olved in, for example, nanoparticle catalyst sintering.

12 gglomerates (mostly ash-bearing) by favoring sintering.

13 modular detector device produced by 3D laser sintering.

14 ured with powder processing and spark plasma sintering.

15 d through high pressure-induced nanoparticle sintering.

16 roximately 850 degrees C without significant sintering.

17 s lower the reaction temperatures to prevent sintering.

18 es as low as 1,150 degrees C by spark-plasma sintering.

19 phy shear-planes and oxygen vacancies during sintering.

20 vol.%) were synthesized here by spark plasma sintering.

21 ysis, such as calcination, which can lead to sintering.

22 processes such as alloying and spark plasma sintering.

23 s with pre-ceramic polymers and spark plasma sintering.

24 y phenomena for material processing by flash sintering.

25 y vapour diffusion in ice-rich layers, or by sintering.

26 ically enhance their stability against metal sintering.

27 al control and less structure shrinkage upon sintering.

28 lent as samples made by conventional thermal sintering.

29 he CuZn alloy catalysts due to no noticeable sintering.

30 ia high-energy ball milling and spark plasma sintering.

31 e possibility of continuous throughput flash sintering.

32 de substrate followed by cold compaction and sintering.

33 ernal cavities and microchannels before full sintering.

34 ene on flaky Cu powders and vacuum hot-press sintering.

35 We have used high-temperature, solid-state sintering (1500 degrees C), as well as excursions throug

36 sensitive to the type of cations used as the sintering additives.

37 mperature processing step through the use of sintering agents such as copper oxide.

38 cing the content of light-scattering alumina sintering aid or incorporating a component of optically

39 with final grain sizes < or =500 nm without sintering aids.

40 al and physical transformations occur during sintering and a cellular vesicular glass-ceramic composi

41 monolayers exhibited enhanced resistance to sintering and CO poisoning, achieving an order of magnit

42 The hollow capsules prevent sintering and detachment of the nanoparticles, and their

43 posites were fabricated via plasma activated sintering and followed by a peak aged (T6) heat treatmen

44 classical" porous glass monoliths, including sintering and fusion of alkali borosilicate initial glas

45 the binders were subsequently burnt off via sintering and hot pressing.

46 he deactivation of conventional catalysts by sintering and leaching.

47 xceptional fatigue strength via the hydrogen sintering and phase transformation (HSPT) process.

48 pores also protects clusters against thermal sintering and prevents poisoning of active sites by orga

49 The mechanisms of selected laser sintering and stereo lithographic apparatus and the prop

50 effectively pin the surface and inhibit both sintering and the transformation to alpha-Al(2)O(3).

51 analyze the thermal runaway nature of flash sintering and to experimentally address the challenge of

52 ns such as microwave sintering, spark plasma sintering, and additive manufacturing are also reviewed.

53 ionic transport, radiation damage evolution, sintering, and aging.

54 partially prevent the formation of WC after sintering, and graphene was uniformly distributed on the

55 ple, be achieved by reducing coke formation, sintering, and loss of metal through diffusion in the su

56 s the grain growth/shrinkage kinetics during sintering are quantified grain by grain for the first ti

57 ensification, with lower temperatures during sintering, as compared to larger nanoparticles.

58 d at the tips of the carbon nanofibers after sintering at 1500 degrees C and atmospheric pressure.

59 position heat treatments trigger nanocrystal sintering at approximately 200 degrees C, before a subst

60 nsient solvent to effect densification (i.e. sintering) at temperatures between room temperature and

61 Examination of the sintering behaviour of 45 European examples reveals that

62 We further show that such accelerated sintering can be evoked by design in other nanocrystalli

63 h ligands are quickly removed in air, before sintering can cause changes in the size and shape of the

64 esults indicate that solely laser peening or sintering can only moderately improve the thin film qual

65 wn for deactivation from copper nanoparticle sintering, can show greatly enhanced activity and stabil

66 t prevent their fast deactivation because of sintering, carbon deposition and phase changes have prov

67 be a novel chemical-exfoliation spark-plasma-sintering (CE-SPS) nano-structuring process, which trans

68 flash sintering, in which contactless flash sintering (CFS) is achieved using plasma electrodes.

69 eometrical configuration and low-temperature sintering characteristic render the Ag micro dendrites w

70 The material was fabricated by sintering chloride-capped CdTe nanocrystals into polycry

71 Laser sintering comprises the second step, where a nanosecond

72 were synthesized by conventional solid-state sintering (CSSS) and spark plasma sintering (SPS) method

73 ens with nanoscale grains, produced during a sintering cycle involving no applied stress.

74 ansport.Diffusion plays an important role in sintering, damage tolerance and transport.

75 s existing between bloating/shrinkage during sintering, density and water adsorption/absorption.

76 of SiC powder in an industrial spark plasma sintering device.

77 nted, immediately loaded, direct metal laser sintering (DMLS) mini-implants.

78 stem alternates or combines direct resistive sintering (DRS) and indirect resistive sintering (IRS).

79 Sintering was carried out via spark plasma sintering, during which the perovskite phase (Ca0.4Ce0.4

80 Electric current activated/assisted sintering (ECAS) techniques, such as electrical discharg

81 AS) techniques, such as electrical discharge sintering (EDS) or resistive sintering (RS), have been i

82 Instead of direct sintering for the conventional nanocrystals, this study

83 Here, a Flash Spark Plasma Sintering (FSPS) process has been applied to a Dy-free N

84 and ambient condition operation of photonic sintering has elicited significant interest for this pur

85 is work show enhanced stability toward metal sintering in a variety of industrial conditions, includi

86 fectively reduced deactivation by coking and sintering in high-temperature applications of heterogene

87 s paper presents a novel derivative of flash sintering, in which contactless flash sintering (CFS) is

88 nanoparticle aggregation, reorientation, and sintering into a high density array of oriented Au nanow

89 th, because the capillary driving forces for sintering (involving surfaces) and grain growth (involvi

90 stive sintering (DRS) and indirect resistive sintering (IRS).

91 It is shown that photonic sintering is an inherently self-damping process, i.e., t

92 Acceleration of sintering is desirable to lower processing temperatures

93 ew ultra-rapid process of flash spark plasma sintering is developed.

94 Here we show that markedly enhanced sintering is possible in some nanocrystalline alloys.

95 Sintering is the process whereby interparticle pores in

96 Preheating, a usual precondition for flash sintering, is provided by the arc electrodes which heat

97 xperiments show that this catalyst undergoes sintering less readily than previously reported catalyst

98 however, when coupled together as laser peen sintering (LPS), the electrical conductivity enhancement

99 ificial LWA particles were formed by rapidly sintering (<10 min) waste glass powder with clay mixes u

100 3D reconstruction by using a selective laser sintering machine.

101 compaction, graphite burnout during partial sintering, machining in a conventional machine tool, and

102 ic permittivity is nearly independent of the sintering method and starting powder used.

103 A new flash (ultra-rapid) spark plasma sintering method applicable to various materials systems

104 f 60 nm can be prepared by a simple two-step sintering method, at temperatures of about 1,000 degrees

105 photonic heating is coupled to an analytical sintering model, to examine the role of interparticle ne

106 ication as compared to conventional photonic sintering models.

107 ructively and in three-dimensions during the sintering of a simple copper powder sample at 1050 degre

108 ntering (SPS) is described, which allows the sintering of any refractory ceramic material in less tha

109 demonstrate that laser peening coupled with sintering of CdTe nanowire films substantially enhances

110 Ceramics were formed by high-temperature sintering of compacted yttrium silicate powders doped wi

111 ial venue for future investigations of flash sintering of complex shapes.

112 g WCu alloys using spark plasma infiltrating sintering of copper-coated graphene (Cu@Gr) composite po

113 es in net shape are obtained through viscous sintering of glass microbeads.

114 Pressureless sintering of loose or compacted granular bodies at eleva

115 Both sintering of MoC3 and accumulation of large hydrocarbons

116 nanostructures through high pressure-driven sintering of nanoparticle assemblies at room temperature

117 High pressure (HP) can drive the direct sintering of nanoparticle assemblies for Ag/Au, CdSe/PbS

118 Sintering of nanoparticle inks over large area-substrate

119 Sintering of nanoparticles (NPs) of Ni supported on MgAl

120 A new approach for predicting the long-term sintering of NPs is presented wherein microscopic observ

121 thermal decomposition) can easily induce the sintering of NPs, greatly hampering their use in synthes

122 Sintering of powders is a common means of producing bulk

123 ture evolution and densification in photonic sintering of silver nanoparticle inks, as a function of

124 lattice phase transformation, which induced sintering of silver nanoparticles into micron-length sca

125 stic behaviour and interfacial geometries in sintering of smectic liquid crystals might pave the way

126 d on stress-induced phase transformation and sintering of spherical Ag nanoparticle superlattices.

127 hat some metals (Fe, Co, and Sn) inhibit the sintering of the active Pd metal phase, while others (Ni

128 d mayenite framework, thus retarding thermal sintering of the material.

129 degrees C can be reached without significant sintering of the noble metal.

130 nk formulation that exploits electrochemical sintering of Zn microparticles in aqueous solutions at r

131 ion-condensation-mediated laser printing and sintering of Zn nanoparticle is reported.

132 Laser sintering of Zn nanoparticles has been technically diffi

133 sizes were fabricated by either conventional sintering or spark plasma sintering using micro- and nan

134 The idea of flash spark plasma sintering (or flash hot pressing - FHP) stems from the c

135 cases to prepare nanocrystalline ceramics by sintering, owing to the concurrent nature of densificati

136 talline, respectively, due to differences in sintering parameters during sample preparation.

137 he Ti powder-based skeleton, and the optimum sintering parameters for full densification were determi

138 rmation-related morphological changes of the sintering particles.

139 When processed with spark plasma sintering, PbS samples with 1.0 mol % Bi(2)S(3) dispersi

140 experimental results demonstrate that flash sintering phenomena can be realized using conventional S

141 The sintering process involves dissolution of a surface pass

142 segmented, and the necessary low-temperature-sintering process is harmful to the dimension-stability

143 This Spark Plasma Sintering process may provide a new route for diamond sy

144 conditions by the stabilization of the flash sintering process through the application of the externa

145 fected by the microstructural design and the sintering process used in their manufacture.

146 Electrochemical sintering process where small Si nanoparticles react and

147 ntering this new approach is named the "Cold Sintering Process" (CSP).

148 acuum spark, via a pulsed DC in Spark Plasma Sintering process, plays a critical role in the low temp

149 d circuits were drastically improved without sintering process.

150 ost and environmentally benign pressure-less-sintering process.

151 ticles followed by conventional pressureless sintering process.

152 But these final-stage sintering processes are always accompanied by rapid grai

153 nk, CdCl3(-) ligands act as surface ligands, sintering promoters, and dopants.

154 tarting powders and dopants, with innovative sintering protocols and associated surface treatments, a

155 dge is crucial to accurately model long-term sintering rates of metal nanoparticles in catalysts.

156 odes closer together, and also underlies the sintering resistance of these clusters during the hydrog

157 h a catalyst not only demonstrated excellent sintering resistance with high activity after calcinatio

158 lemental polycrystalline Bi via spark plasma sintering results in 'double-decoupling' (simultaneous d

159 rical discharge sintering (EDS) or resistive sintering (RS), have been intensively investigated for l

160 In a nanostructured W-Cr alloy, sintering sets on at a very low temperature that is comm

161 or biomedical applications such as microwave sintering, spark plasma sintering, and additive manufact

162 ally insulated graphite die for Spark Plasma Sintering (SPS) is described, which allows the sintering

163 )O(3)/SWNT composites using the spark-plasma sintering (SPS) method.

164 olid-state sintering (CSSS) and spark plasma sintering (SPS) methods.

165 recursors using either reactive spark plasma sintering (SPS) synthesis in a mere 20 min at 320 degree

166 tal composites were obtained by spark plasma sintering (SPS) using ZrO2 and lamellar metallic powders

167 to 0.7 W/m.K by Sb alloying and spark plasma sintering (SPS), which introduce additional phonon scatt

168 wever, current TMC synthesis methods lead to sintering, support degradation, and surface impurity dep

169 acets, inspiring the rational design of anti-sintering supported platinum group catalysts.

170 s that arise from the use of selective laser sintering surgical guides for flapless dental implant pl

171 solid" carbon nanofibers with a Spark Plasma Sintering system under low temperature and pressure (eve

172 ere fabricated by a homemade selective laser sintering system.

173 f the exfoliated layers via the spark-plasma-sintering technique (SPS).

174 revious reports describe an energy-intensive sintering technique as an alternative technique for proc

175 This paper describes a sintering technique for ceramics and ceramic-based compo

176 es were powder-processed by the spark plasma sintering technique, which introduces mesoscale-structur

177 flash hot pressing (ultra-rapid spark plasma sintering) technique.

178 All the samples can be well densified at sintering temperature about 720 degrees C.

179 and AFM measurements indicated that both the sintering temperature and compression force played an im

180 better captures the experimentally observed sintering temperature and densification as compared to c

181 on of choice in this work due to its reduced sintering temperature and increased lithium ion conducti

182 To emphasize the incredible reduction in sintering temperature relative to conventional thermal s

183 the particle size of the starting powder and sintering temperature.

184 ility in reducing atmospheres and lowers the sintering temperature.

185 th nanocrystalline alumina (Al2O3) matrix at sintering temperatures as low as 1,150 degrees C by spar

186 Steam present during calcination promotes sintering that produces a sorbent morphology with most o

187 er strategies based on liquid phase (fusion) sintering that requires both oxide-free metal surfaces a

188 A films with free surface in the process of sintering, that is, reshaping at elevated temperatures.

189 In addition, a method was developed for sintering the universal support directly into a filter p

190 After high-temperature sintering, the (100)Mo formed a hard, adherent layer tha

191 In spark plasma sintering, the DC pulse current helps in controlling the

192 Sintering this bi-constituent foam yields solid closed-c

193 temperature relative to conventional thermal sintering this new approach is named the "Cold Sintering

194 ulting in homogeneous microstructures within sintering times of 8-35 s.

195 nucleation of h-BN magic clusters and their sintering to form compact triangular islands to the grow

196 presented new method allows: extending flash sintering to nearly all materials, controlling sample sh

197 ystals, unlike MSCs, require in-film thermal sintering to reinforce electronic contact between partic

198 ither conventional sintering or spark plasma sintering using micro- and nano-sized powders.

199 nt compared with those from the conventional sintering using the undoped WCu powders.

200 full density and translucency by solid-state sintering was an important milestone for modern technica

201 Sintering was carried out via spark plasma sintering, du

202 (6) S/m (12% of bulk Au) were attained after sintering was conducted at plastic-compatible 200 degree

203 Fe foams fabricated by freeze-casting and sintering were electrochemically anodized and directly u

204 the resulting halide salt byproduct prevents sintering, which further permits dispersion of the nanos

205 ls to make the structure more stable against sintering while the number of active sites is not sacrif