Graphene　has　become　a　research　focus　in　recent　years　owing　to　its　excellent　characteristics,　and　glass　is　a　commonly　used　material　with　high　transparency　and　low　cost.　Graphene　glass　combines　the　excellent　properties　of　both　graphene　and　glass;　graphene　glass　has　not　only　high　thermal　conductivity,　high　electrical　conductivity,　and　good　surface　hydrophobicity　but　also　exhibits　superior　electrothermal　conversion　and　wide-spectrum　high-light-transmittance　characteristics.　Therefore,　the　study　of　graphene　glass　films　is　of　theoretical　value　and　practical　significance.　In　this　study,　a　high-purity　glass-based　(JGS1　quartz　glass)　multilayer　graphene　film　was　developed　based　on　an　atmospheric-pressure　chemical　vapor　deposition　(APCVD)　method,　and　its　electrical　characteristics,　light　transmittance,　and　electrical　heating　characteristics　were　experimentally　investigated　in　detail.　The　results　show　that　graphene　glass　with　different　surface　resistance　values　obtained　through　direct　growth　on　a　high-purity　quartz　glass　substrate　using　the　APCVD　method,　not　only　has　excellent　uniformity　and　quality,　but　also　has　considerably　flat　and　high　transmittance　across　the　entire　visible　light　region　and　exhibits　excellent　heating　performance　and　fast　response　time.　For　graphene　glass　with　a　surface　resistance　of　1500　Omega.sq(-1),　the　light　transmittance　can　reach　74%,　and　the　saturation　temperature　can　rise　to　185　degrees　C　by　applying　a　bias　voltage　of　40　V.　In　addition,　when　the　resistance　value　of　the　graphene　glass　is　420　Omega.sq(-1),　the　graphene　glass　reaches　a　high　saturation　temperature　of　325　degrees　C　in　40　s,　and　the　corresponding　heating　rate　can　exceed　18　degrees　C.s(-1),　achieving　a　significantly　higher　heating　rate　than　other　heating　films　at　the　same　voltage.　Compared　with　the　polyethylene-terephthalate-　(PET-)　based　and　silicon-based　graphene　films　obtained　by　the　transfer,　graphene　glass　has　a　higher　saturation　temperature,　shorter　thermal　response　time,　and　faster　heating　rate.　Furthermore,　graphene　glass　exhibits　better　heating　cycle　stability　and　longer-term　heating　stability　at　a　constant　voltage.　In　addition,　an　experiment　using　the　graphene　glass　to　thermally　tune　the　wavelength　of　a　vertical-cavity　surface-emitting　laser　was　conducted　and　gave　good　results.　The　position　of　the　laser　peak　controlled　by　the　graphene　glass　was　red-shifted　by　1.78　nm　by　applying　a　voltage　of　20　V,　and　the　wavelength　tuning　efficiency　reached　0.059　nm.degrees　C-1.　Compared　with　PET-based　and　silicon-based　graphene　films,　the　actual　electrical　heating　capacity　of　graphene　glass　increased　by　195%.　These　experimental　findings　demonstrate　that　graphene　glass　transparent　films　with　excellent　electric　heating　characteristics　can　be　used　in　various　transparent　electric　heating　fields　and　have　relatively　wide　application　prospects.