This study has investigated the electron transfer behaviour of dye sensitized solar cells (DSSC) and perovskite solar cell (PSC) using a range of time-resolved and steady state techniques. The enhanced understanding of these processes was then utilized to develop unique strategies to circumvent performance limitations associated with injection or recombination, thereby improving the power conversion efficiencies of the devices. In this study, four characterization techniques have been reported, transient photocurrent and photovoltage decay measurements, charge extraction measurement, photoinduced absorption spectroscopy and transient absorption spectroscopy. This thesis provide an account of each technique about its operating principle, experimental setup and data analysis. The transient photoelectric measurements, are obtained under short-circuit and open-circuit conditions, respectively, and the electron diffusion coefficients and electron lifetimes are extracted from fitting the decay curves accordingly. For the photoinduced absorption spectroscopy, which is useful in the characterization of long-lived (> μs) non-radiative excited states and used as the first step for transient absorption measurement. As case studies for each technique, examples are given to rationalize the observed potential shift, decay coefficients of electron transport and of charge recombination in relation to the corresponding photovoltaic performance of the device. For porphyrin dyes and organic dyes, by using the transient photoelectric measurements to understand the charge recombination process and TiO2 potential shift; for TiO2 nanostructure, we measured the charge transport kinetics with different morphology TiO2. For perovskite solar cell, we used these techniques to study the charge transport kinetics of the devices.