Solid-state white light-emitting electrochemical cells (LECs) have received intense scientific attention owing to their potential applications in display and lighting. Although device efficiencies of white LECs have been improved significantly in recent years, further improvements are still required for practical applications. In this work, we demonstrate enhancing device efficiencies of white LECs by employing waveguide coupling. Two transparent photoresist (TPR) layers doped with TiO2 nanoparticles (NPs) are inserted between indium tin oxide (ITO) layer and glass substrate. By tuning the doping concentration of 25-nm TiO2 NPs in the upper TPR layer to adjust the refractive index, effective waveguide coupling between ITO layer and the lower TPR layer can be achieved. Since the lower TPR layer contains 250-nm TiO2 NPs, electroluminescence (EL) outcoupled from ITO layer can be scattered and redirected into the forward direction. Furthermore, the EL trapped in glass substrate can also transmit into the lower TPR layer and then is scattered to the forward direction. When the EL trapped in ITO layer and glass substrate can be effectively recycled into the forward direction, the peak external quantum efficiency and power efficiency obtained in white LECs employing waveguide coupling are up to 19.4 % and 34.1 lm W–1, respectively. These efficiencies are among the highest reported for white LECs and thus confirm that waveguide coupling would be useful for realizing highly efficient white LECs. In addition to enhanced device efficiencies, improved color migration of EL spectra, which is desired in lighting applications, can be obtained in white LECs with scattering waveguide layers since EL of different angles can be mixed in the forward direction.