Ferritic stainless steels have recently been received increasing interest for application in the solar water heater panels and hot-water tank, due to the low thermal expansion coefficient, excellent resistance to high-temperature oxidation, and stress corrosion cracking. The objective of this study is to demonstrate the feasibility of CO2 laser welding for joining of SUS 444 ferritic stainless steel by different welding speeds. Microstructures and precipitations of the welds will be examined using optical microscopy (OM) and scanning electron microscopy (SEM). This experiment performs micro-hardness measurement in accordance with welding areas after CO2 laser welding. Moreover, the specimens have been cut vertical to weld pass after welding and then perform tensile test using universal material testing machine in order to explore the joining quality of welding joints. At the same time, SEM has been used to observe the fractured surface of the tensile testing specimens. Finally, electrochemistry experiments were performed in an aqueous solution of 3% NaCl to explore the Pitting corrosion resistance of the welds. The experimental results have found that microstructure of 444 stainless steel welds is completely ferrite single-phase structure, including base metal and welding path. However, the welding fusion zones present coarse columnar structure when the specimens have lower welding speed, which will result in the mechanical properties degradation of weldments. With the increase of welding speed, the solidification zones have fine columnar structure and the weldments show higher microhardness in the welding fusion zone. At the same time, the tensile strength and elongation have been promoted, and the fracture site appears in the base metal. Furthermore, the lower welding speed will result in the aggregation of Nb-contained precipitations in the grain boundaries of heat-affected zone, which will bring the pitting corrosion resistance degradation of weldments.