Undoped and yttrium-doped manganese selenide thin films were synthesized via spray pyrolysis deposition technique for photovoltaic  purposes by utilizing manganese (II) acetate tetrahydrate, selenium (iv) oxide and yttrium. The deposited samples were characterized  with instruments such as X-ray diffractometry, Uv-Vis spectrophotometry, four-point probe and SEM/EDX for structural, optical, electrical  and morphological analysis. The X-ray diffraction pattern for both undoped and Y-doped MgSe samples shows the presence of crystal  peaks along (111), (200), (210), (211) and (300) planes indicating polycrystalline and hexagonal structural nature. Optical analysis reveals a  decrease in absorbance and an increase in transmittance as the wavelength increases for all the samples. The addition of a higher  percentage (0.04 mol%) of yttrium dopant narrowed the bandgap energy (1.15 eV) of the undoped MnSe, making these materials  promising for solar cell fabrication. Electrical analysis reveals that as yttrium dopant concentration in MnSe increases from 0 to 0.04  mol%, the film thickness increases from 110.0 nm to 115.13 nm with increasing resistivity and decreasing conductivity of 11.68 x 10^-4 to  11.68 x 10^-4 Ω.m and 8.561 x 10² to 8.467 x 10² (Ω.m)-1 respectively. The overall electrical result of both undoped and y-doped MnSe  conforms to that of a typical semiconductor. For the morphology result, the addition of yttrium dopant altered the microstructure of  undoped MnSe. For undoped MnSe a smooth dense layer was observed while Y-doped MnSe reveals an agglomeration with no defined  shape but is also dense. EDX result confirms the growth of a novel yttrium manganese selenide (YMnSe) thin material. YMnSe films offer  features like narrowed band gap energy, improved charge transport characteristics and enhanced light trapping, making them potential  materials for photovoltaic applications.