The hexagonal WO₃ nanostructures were synthesized by varying the reaction time of hydrothermal treatment as 2,4,6 and 8 h and characterized using X-ray diffractometer (XRD), absorption spectroscopy, scanning electron microscopy(SEM) and Raman spectroscopy. The hexagonal structure of prepared WO₃ was confirmed from XRD pattern in figure I. Lattice strain is calculated and their variation with different hydrothermal studies has been studied. The reaction time induced lattice strain was calculated. The absorption peak is obtained at 290 nm and the bandgap is varying from 2.9 to 3.1 eV. The role of reaction time in the evolution of morphology has been studied from the SEM image. It shows the evolution of stacked-layer structure to the flower-like morphology and then distorted to form a rod when reaction time increases are shown in figure IV. Raman spectra have been recorded for all three samples and are shown in figure III. It has been noted that the FWHM and peak position of stretching vibration mode varies with reaction time. The variation of strain calculated from XRD, FWHM and peak position is shown in figure II. The change in Raman laser energy violates the vibration of the bonds, influences the vibrational spectra and causes a shift and broadening in the Raman bands. The surface temperature has calculated from Raman stokes and anti-stokes lines intensity ratio with increasing laser power. The absorption in the UV region around 290 nm makes it a suitable candidate for UV photodetector applications. IV measurement of a prepared sample in dark and UV modes shows high responsivity and sensitivity.