A　comparative　study　of　the　high-temperature　oxidation　behavior　and　mechanism　of　0Cr25Ni20　austenitic　heat-resistant　stainless　steel　(AHSS)　and　0Cr18AlSi　ferritic　heat-resistant　stainless　steel　(FHSS)　at　800°C,　900°C,　and　1000°C　in　air　up　to　140 h　was　performed　using　isothermal　oxidation　tests.　The　oxidation　kinetics　of　0Cr25Ni20　AHSS　and　0Cr18AlSi　FHSS　followed　the　parabolic　law.　The　oxide　films　on　0Cr25Ni20　AHSS　were　composed　of　continuous　and　dense　Cr2O3,　MnCr2O4,　and　a　small　amount　of　NiMn2O4,　whereas　silicon　exhibited　internal　oxidation　and　deteriorated　the　adhesion　between　the　oxide　film　and　substrate.　Nickel-free　0Cr18AlSi　FHSS　exhibited　good　oxidation　resistance　at　800°C　and　900°C　due　to　dense,　continuous,　and　well-adhered　multicomponent　oxide　films　containing　Al2O3,　Cr2O3,　MnCr2O4,　and　a　small　amount　of　MnFe2O4.　The　oxidation　resistance　of　0Cr18AlSi　FHSS　declined　at　1000°C,　mainly　due　to　the　formation　of　nonprotective　Fe2O3　and　severe　internal　oxidation　of　aluminum.　©　2019,　The　Minerals,　Metals　&　Materials　Society.