This paper presents the results of an experimental investigation on the deposition of multiply charged particles on wire screens by the combined mechanisms of diffusion and image force. Experiments were performed with particles having diameters between 25 and 65 nrn (transition regime), carrying 0, + 1, +2 or +3 elementary charges, and using three different flow rates, two types of wire screen, and two types of test aerosol. The single fiber efficiencies for the mechanisms of image force, eta(IM), and diffusion, eta(D), are of the same order of magnitude and, furthermore, they are both much smaller than one. Under these conditions, the total capture efficiency can be approximated as the sum of the efficiencies by diffusion and image force deposition. Theoretically,)eta(IM) is proportional to the square root of a dimensionless number, K-IM, which includes all the relevant parameters cited above (i.e., particle size and charge, aerosol flow rate and screen geometry). The available correlations for eta(IM), obtained from experiments with particles carrying a large number of elementary charges (K-IM > 10(-5)), predict that image force should not have any effect in the case of the small particles with very few number of charges that we have tested in our experiments (in our experimentation, KIM ranged between 10(-7) and 10(-5)). Our results, the only ones available to date for this particle size range, show that there is indeed a clear. measurable effect. Although our experimental results are best fitted by the correlation eta(IM) = 29.7K(IM)(0.59), it is shown that the expression eta(IM) = 9.7 root K-IM, which is in agreement with the theoretical 1/2 exponent for K-IM, also reproduces reasonably well the measured values. (c) 2007 Elsevier Ltd. All rights reserved.