Effect of an electric field on the flame propagation over a solid material surface

ABSTRACTReports of enhanced sintering rates associated with microwave heating may be due to nonthermal lattice fluctuation statistics. Recent theoretical analyses reviewed in this paper confirm the feasibility of this phenomenon for a wide variety of situations involving very different microwave absorption mechanisms. For materials with weak microwave absorption coefficients, the effect is expected to be uniformly distributed throughout the volume. For strongly absorbing materials, however, the effect is expected to be concentrated near the material surface, with a characteristic exponential penetration depth of Lnt ∼ 10 - 100 μm. An “observable” nonthermal effect depends on the relative magnitude of the microwave electric field strength |E| and the lattice ion energy relaxation rate γ with the most pronounced effects occurring for larger values of |E| and smaller values of γ.

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Effects of Electric Field on the SHS Flame Propagation of the Si-C System, Examined by the Use of the Heterogeneous Theory

Journal of Combustion ◽

10.1155/2013/752068 ◽

2013 ◽

Vol 2013 ◽

pp. 1-8 ◽

Cited By ~ 1

Author(s):

Atsushi Makino

Keyword(s):

Electric Field ◽

Heat Loss ◽

Flame Propagation ◽

Analytical Study ◽

Essential Feature ◽

Experimental Comparison ◽

Exothermic Reactions ◽

High Temperature Synthesis ◽

Insight Into ◽

Fair Degree

Relevant to the self-propagating high-temperature synthesis (SHS) process, an analytical study has been conducted to investigate the effects of electric field on the combustion behavior because the electric field is indispensable for systems with weak exothermic reactions to sustain flame propagation. In the present study, use has been made of the heterogeneous theory which can satisfactorily account for the premixed mode of the bulk flame propagation supported by the nonpremixed mode of particle consumption. It has been confirmed that, even for the SHS flame propagation under electric field, being well recognized to be facilitated, there exists a limit of flammability, due to heat loss, as is the case for the usual SHS flame propagation. Since the heat loss is closely related to the representative sizes of particles and compacted specimen, this identification provides useful insight into manipulating the SHS flame propagation under electric field, by presenting appropriate combinations of those sizes. A fair degree of agreement has been demonstrated through conducting an experimental comparison, as far as the trend and the approximate magnitude are concerned, suggesting that an essential feature has been captured by the present study.

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Physical origin of a complicated tactile sensation: ‘ shittori feel'

Royal Society Open Science ◽

10.1098/rsos.190039 ◽

2019 ◽

Vol 6 (7) ◽

pp. 190039 ◽

Cited By ~ 5

Author(s):

Kana Kikegawa ◽

Rieko Kuhara ◽

Jinhwan Kwon ◽

Maki Sakamoto ◽

Reiichiro Tsuchiya ◽

...

Keyword(s):

Surface Roughness ◽

Regression Analysis ◽

Physical Properties ◽

Multiple Regression Analysis ◽

Multiple Regression ◽

Solid Material ◽

Tactile Sensation ◽

Material Surface ◽

Physical Origin ◽

The Relationship

Shittori feel is defined as a texture that is moderately moisturized; however, many people experience ‘ shittori feel’ when they touch a dry solid material containing little liquid. Here, shittori feel was evaluated for 12 materials. We found that the highest score of shittori feel was achieved by powders. Multiple regression analysis showed that shittori feel is a complex sense of moist and smooth feels. We analysed the relationship between the physical properties and the moist/smooth feels to show how subjects felt certain feels simultaneously. The moist and smooth feels are related to the surface roughness and friction characteristics of the materials. The moist and smooth feels can be perceived when the finger starts to move on the material surface and when the finger moves and rubs the material surface, respectively.

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