Current available methods for WLEDs are mostly based on expensive rare-earth elements (REEs) doped phosphors, which would cause a tremendous harm to the environment. Although quantum dots (QDs) and nanocrystals (NCs) have been proposed as promising alternatives, these materials still have environmental concerns due to containing cadmium. Moreover, the strong quantum confinement effect in these nanoscale materials causes their efficient excitation wavelength to be limited in UV region, and this situation hinders these nanomaterials from integrating with commercial blue-LEDs. In this work, we develop a novel technique to synthesize environmental benign ZnSe:Mn nanoparticles with little quantum-confinement effect. The research can be separated into three parts. In the first part, we successfully synthesized ZnSe:Mn nanoparticles with little quantum-confined effect. The excitation wavelength of the nanoparticles is larger than 445 nm, which matches the commercial blue LEDs. In the second part, we aim to improve the efficiency of the nanoparticles. By optimizing the concentration of cations and Mn2+, and adding surfactant and citric acid, the quantum efficiency can reach 84.5%. In the third part, we focus on enhancing the drying process of the nanoparticles by changing rinse solvent, drying time, and drying pressure. Finally, we measure the luminous efficacy of the nanoparticles. Therefore, ZnSe:Mn nanoparticles featuring rare-earth-free and cadmium-free can sever as another promising candidate for luminescence conversion of white-LEDs.