@article { 5322334, title = {An appraisal of the one-flux method for treating carrier transport in modern semiconductor devices}, journal = {Solid-State Electron. (UK)}, volume = {39}, number = {6}, year = {1996}, note = {one-flux method;carrier transport;semiconductor devices;short-base bipolar transistors;carrier mobility;forward-biased barrier;continuity equation;drift-diffusion equations;low-level injection;short-base transport;dc conditions;ac conditions;boundary conditions;backscattering coefficients;diffusivity;numerical analysis;}, pages = {827 - 32}, type = {article}, abstract = {McKelvey's one-flux method, which has been used to investigate transport in short-base bipolar transistors and to specify the carrier mobility in a forward-biased barrier, is put into perspective by a comparison with the usual continuity and drift-diffusion equations. For a bulk semiconductor region in which a small electric field is present, and under typical operating conditions, it is shown that the use of the time-dependent flux method is equivalent to solving the usual continuity and drift-diffusion equations under low-level injection. It is then shown that recent one-flux analyses of short-base transport, for both dc and ac conditions, are equivalent to solving the continuity and drift-diffusion equations with appropriate boundary conditions. It is pointed out that the use of the flux method to resolve the long-standing issue of specifying the carrier mobility within a forward-biased barrier is impeded by a lack of knowledge of the required backscattering coefficients. Recent suggestions for these backscattering coefficients are carefully examined; the physical basis for the choices made, and hence the resulting values of mobility and diffusivity, are questioned}, keywords = {bipolar transistors;Boltzmann equation;boundary-value problems;carrier lifetime;carrier mobility;semiconductor device models;}, URL = {http://dx.doi.org/10.1016/0038-1101(95)00273-1}, author = { Vaidyanathan, M. and Pulfrey, D.L.} }