Charge Transfer Upon Contact Between Metals and Insulators

Ostenburg, D. O. Van; Montgomery, D. J.

doi:10.1177/004051755802800103

Cited by 24 publications

(4 citation statements)

References 6 publications

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“…None of the findings conflict seriously with recently announced concepts of the transfer of charge due to friction [33,76) . However, the observation that appreciable amounts of one fiber abrade under the conditions of experiment and cling to the other fiber, thereby surely influence ing the net charge transfer, suggests caution in proposing a purely electronic or ionic mechanism of triboelectricity on the basis of experiments of this type.…”

Section: Discussioncontrasting

confidence: 61%

“…Further theoretical treatment based on this model has been given by Van Ostenburg and Montgomery [ 76 ) . Levy and Dillon [ 44 ] , using the Hersh-Montgomery apparatus with certain modifications, gave preliminary results at variance with one of the conclusions of Hersh and Montgomery [ 32 ) ; i.e., under certain conditions the charge developed by rubbing insulator on insulator increased with increasing velocity.…”

Section: Introductionmentioning

confidence: 99%

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Relation of Charge to Frictional Work in the Static Electrification of Filaments

Levy

Wakelin

Kauzmann

et al. 1958

Textile Research Journal

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A study of the generation of electrical charge on fibrous materials was carried out using the apparatus of Hersh and Montgomery, in which a fiber is held fixed in an insulated lower yoke while a second fiber in a grounded upper yoke is rubbed across it under controlled ambient and mechanical conditions. The original apparatus was modified to permit measurement of the frictional work of rubbing as well as the charge.Precautions were taken to discharge both fibers with a radioactive source after each measurement.It was found that, at any one velocity, several thousand rubs were required before steady values of charge transferred and frictional work of rubbing were obtained.It was also found that the velocity of rubbing affected strongly both the charge transferred and the frictional work of rubbing, the former being found to decrease and the latter to increase with increasing velocity. This has been explained in terms of local heating, plastic junctions, and material transfer which occur during rubbing. An empirical relationship relating the velocity of rub, the frictional work of rubbing, and the charge transferred was found to hold in the great majority of the cases examined.From the experimental data obtained it was possible to calculate the mechanical energy expended in any one rub and to estimate the resulting electrical energy. Thus for any pair of fibers under a given set of conditions it was possible to calculate the efficiency of the process of converting mechanical energy to triboelectrical energy. At 30° C. and 33% RH, measured efficiencies were very low (0.00-0.42%); at a very low humidity, efficiencies as high as 2.0% were found.The presence of a lubricant on the fiber surfaces during rubbing was found in most cases to cause a decrease in both the charge and frictional work of rubbing.

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Section: Discussioncontrasting

confidence: 61%

Section: Introductionmentioning

confidence: 99%

Relation of Charge to Frictional Work in the Static Electrification of Filaments

Levy

Wakelin

Kauzmann

et al. 1958

Textile Research Journal

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“…We note that such calculations have been made for trapless insulators by Van Ostenburg and Montgomery (1958) and Harper (1967). As pointed out by Harper, the screening length for the transferred charge to a trap-free insulator is too large for that model to have any practical value.…”

Section: Contact Charging For An Insulator With a Continuous Distribu...mentioning

confidence: 94%

The role of bulk traps in metal-insulator contact charging

Chowdry

Westgate

1974

J. Phys. D: Appl. Phys.

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Metal-insulator contact charging models are presented for insulators having (a) traps uniformly distributed in the energy gap and (b) discrete traps in the energy gap. It is shown that in the former case the relationship between the magnitude of the charge transferred and the workfunction difference is linear, while in the latter case it ranges from an exponential to a quadratic depending on the band bending and the energetic position of the traps. Screening lengths are calculated for the two cases, and it is shown that the thickness of the insulator is usually not the limiting factor in contact charging, even for thin-film insulators. Finally, it is shown that the times required for the charge transfer can be short.

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“…A number of authors have calculated the charge transferred when a metal and an insulator are brought into contact, assuming that the charge transfer is due to electrons (Van Ostenberg and Montgomery 1958, Davies 1969, Chowdry and Westgate 1974, Carton 1974, Duke and Fabish 1978, Nordhage and Backstrom 1975. Most of these calculations are based on thermodynamics, and have not been concerned with the detailed mechanism of charge transfer.…”

Section: Introductionmentioning

confidence: 99%

Tunnelling between metals and insulators and its role in contact electrification

Lowell¹

1979

J. Phys. D: Appl. Phys.

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Tunnelling of electrons between a metal and localised states in an insulator is considered, with a view to determining the charge that an insulator can acquire by this mechanism when it is contacted to a metal, and also the extent to which it can lose charge by back-tunnelling during separation. Traps at a single energy are considered primarily, but some attention is given to traps distributed over a range of energy. Back-tunnelling is likely to be significant only at the very highest observed charge densities.

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Charge Transfer Upon Contact Between Metals and Insulators

Cited by 24 publications

References 6 publications

Relation of Charge to Frictional Work in the Static Electrification of Filaments

Relation of Charge to Frictional Work in the Static Electrification of Filaments

The role of bulk traps in metal-insulator contact charging

Tunnelling between metals and insulators and its role in contact electrification

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