In recent years, microelectromechanical system has attracted much attention in engineering society. With miniaturization, we could not only reduce the cost of many existing applications but also have many possibilities for developing new applications. However, the mass production of microcomponents for micromachinery is always an issue. In this study, we synthesized magnetic glass microgears by using the stop-flow lithography and sol-gel process. The microgears with complex shape were polymerized in a PDMS microchannel by photolithography. The prepolymer solution consisted of tetraethyl orthosilicate(TEOS) as the precursor of silicon-dioxide, poly(ethylene glycol) diacrylate (PEGDA 700) as the monomer, Darocur 1173 as the photoinitiator, 3-(Trimethoxysilyl)propyl methacrylate(MEMO) as the bridge monomer and magnetic particles as the source of the magnetism. The polymerized particles were then sintered to generate the glass microgears. These heating steps allowed polymer to burn out and TEOS would condense to SiO2. The resulting microgears were found to have great mechanical strength and can be controlled remotely by an external magnetic field. With these special features, we expect that the magnetic glass microgears have great potential to be used in the applications of micromachines in the future.