Charge and recombination

Fig. 29 Fit to experimental current-voltage data circles) using electric field-dependent polaron pair dissociation, drift, and diffusion broken line) and additionally including space-charge and recombination solid line), a The high-field part (Vo- a > 10°) of the log-log I-V curve allows the determination of charge distance in the polaron pair, b The same data shown on a linear scale. (Reprinted with permission from [59], 2005, American Physical Society)...

The non-linearity is due to the apparent standard free-energy of hydrogen adsorption. Under these conditions, the Frumkin-Temkin (F-T) corrections should be applied to both, the discharge and the recombination currents [18,19]. The modified set of charging and recombination currents are ... 

Clearly additional layers may be used to accomplish other benefits, tailoring the energy profiles and mobilities across the entire organic stack. Splitting the transport layer(s) into two separate layers permits the optimization of injection into the layer nearest the electrode (sometimes called the injection layer), and transport in the farther layer [101]. Layers of insulator (charge confinement layers) have also been used in an attempt to control the motion of the charges and ensure recombination in the desired region [102]. 

The processes of charge injection, transport, and recombination dictate the recombination efficiency h(/), which is the fraction of injected electrons that recombine to give an exciton. The recombination efficiency, which is a function of the device current, plays a primaty role in determining the amount of emitted light, therefore determining the OLED figurcs-of-meril. For example, the quantum efficiency /y(/) (fraction of injected electrons that results in the emission of a photon from the device) is, to a first approximation, given by ... 

Frequently, electrochemical information can be interpreted better in the presence of additional nonelectrochemical information. Typically, however, there is one significant restriction electrochemical and spectroscopic techniques often do not detect exactly the same mechanisms. With spectroscopic measurements (e.g., infrared spectroscopy), products that are formed by electrochemical processes may be detected. In other cases (luminescence techniques) mechanisms may be found by which charge carriers are trapped and recombine. Other techniques (electroreflection studies) allow the nature of electronic transitions to be determined and provide information on the presence or absence of an electric field in the surface of an electrode. With no traditional technique, however, is it... 

Figure 13. Numerically calculated PMC potential curves from transport equations (14)—(17) without simplifications for different interfacial reaction rate constants for minority carriers (holes in n-type semiconductor) (a) PMC peak in depletion region. Bulk lifetime 10" s, combined interfacial rate constants (sr = sr + kr) inserted in drawing. Dark points, calculation from analytical formula (18). (b) PMC peak in accumulation region. Bulk lifetime 10 5s. The combined interfacial charge-transfer and recombination rate ranges from 10 (1), 100 (2), 103 (3), 3 x 103 (4), 104 (5), 3 x 104 (6) to 106 (7) cm s"1. The flatband potential is indicated.

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