Abstract Magnesium-doped lithium niobate substrates are used for the design and fabrication of waveguides on a 5 mm long segment-chirped grating structure. Green laser of wavelength 532 nm is obtained by the quasi-phase matching second harmonic generation (QPM-SHG), when launched with an incident laser of wavelength 1064nm. On the part of waveguide fabrication, two waveguides are fabricated by zinc-and-nickel co-diffusion and gallium diffusion in this thesis. The zinc-and-nickel co-diffusion waveguides have linewidth of 160 μm and film thickness of 100 nm, which were diffused for 3 hr at 880 ˚C. The gallium diffusion waveguides have linewidth of 160 μm and film thickness of 120 nm, which were diffused for 2 hr at 980 ˚C. TM and TE modes are supported in the zinc-and-nickel co-diffusion waveguides, but only TM modes are supported in the gallium diffusion waveguides, which agrees quite well with those reported previously. On the part of green laser measurement, an incident laser of maximum power 8mW with wavelength 1064 nm is launched into the sample. The sample without waveguides have temperature bandwidth of 60 ˚C, and green laser conversion efficiencies of 9.9%. The zinc-and-nickel co-diffusion waveguides have a larger temperature bandwidth of 80 ˚C, and a higher green laser conversion efficiencies of 15.4%. Similarly, the gallium diffusion waveguides have a larger temperature bandwidth of 85 ˚C, and a higher green laser conversion efficiencies of 13.9%. Experimental results show the temperature bandwidth and conversion efficiencies are both increased owing to the proposed waveguide structures provided better optical confinement.