Abstract
Thomson and Rutherford's1 initial investigations of the saturation characteristics of a parallel plate ionization chamber were followed by theoretical treatments by Thomson2, Mie3, Seeliger4 and others. More recently, Boag and Wilson5 have shown by dimensional analysis that the collection efficiency, f (that is, the ratio of the measured current, i, to the ideal saturation current, is), is a function of d2q½V−1 where d is the distance between the plates, q is the rate of ionization and V is the applied voltage. Through the introduction of certain assumptions, they derived the following equation for the generalized saturation characteristic: 
k1 and K2 are the mobilities of the positive and negative ions respectively (that is, it is assumed that the current carried by electrons is negligible); α is the recombination coefficient; e is the charge per ion; m is Boag's constant.
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References
Thomson, J. J., and Rutherford, E., Phil. Mag., 42, 392 (1896).
Thomson, J. J., Phil. Mag., 47, 253 (1899).
Mie, G., Ann. Phys. (Liepzig), 13, 857 (1904).
Seeliger, R., Ann. Phys. (Liepzig), 33, 319 (1910).
Boag, J. W., and Wilson, T., Brit. J. App. Phys., 3, 222 (1952).
Greening, J. R., Phys. Med. Biol., 9, 143 (1964).
Boag, J. W., Radiation Dosimetry, second ed. (Academic Press, New York, in the press).
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BURLIN, T., HUSAIN, S. Saturation Characteristics of a Spherical Ionization Chamber and a Determination of Boag's Constant for Air. Nature 204, 670–672 (1964). https://doi.org/10.1038/204670b0
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DOI: https://doi.org/10.1038/204670b0
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