This study demonstrates the fabrication of chiral silver nanostructures using circularly polarized laser light. The laser, passed through a circular polarizer and focused in a microscope system, irradiates a silver nitrate and ascorbic acid solution. The plasmonic effect of the reduced atomic clusters in the solution generates hot electrons, which further drive the photochemical reduction process. Simultaneously, the optical forces of the circularly polarized light drive the self-assembly of silver atom clusters, and the optical torque causes them to distribute helically, forming chiral three-dimensional nanostructures. These structures are applied for surface-enhanced Raman spectroscopy (SERS) measurements. The experiments are conducted at room temperature (25°C) and one atmosphere pressure. The morphology of the silver nanostructures is controlled by adjusting the pre-reaction time of the solution, laser power, irradiation time, and wavelength. FE-SEM images show that irradiating the solution after a 5-minute pre-reaction produces finer nanostructures. Increasing the pre-reaction time reduces the influence of photochemical reduction due to the completion of the pure chemical reduction reaction, affecting the complexity of the microstructure and decreasing its SERS efficiency. For SERS measurements, different concentrations of R6G (Rhodamine 6G) are used as test samples. The results indicate that these three-dimensional silver structures can detect R6G at concentrations ranging from 10-6 M to 10-10 M. The experiment demonstrates that circularly polarized laser-driven photochemical reduction can produce chiral three-dimensional silver nanostructures, enhancing SERS sensitivity. Additionally, their circular dichroism (CD) can be applied to detect chiral L- or D-type molecules.