Development of a hydrogenated amorphous silicon carbide-based biosensor for E. coli detection

“…Application areas for a-SiC are also expected to increase, with recent results in ultrahard materials [ 126 ], as a platform for functionalization in biosensors [ 135 ], and as a platform for photoelectrochemical CO 2 conversion [ 136 ]. Furthermore, new characterization techniques for C-based materials and amorphous materials could open up new possibilities for optimization, such as thermal-optic effects studied using two-wave mixing [ 137 ], bandgap measurements using Kelvin force microscopy [ 138 ], structural determination using atomic resolution electron tomography [ 139 ], and material simulations using molecular dynamics [ 140 , 141 ].…”

Amorphous SiC Thin Films Deposited by Plasma-Enhanced Chemical Vapor Deposition for Passivation in Biomedical Devices

“…Application areas for a-SiC are also expected to increase, with recent results in ultrahard materials [ 126 ], as a platform for functionalization in biosensors [ 135 ], and as a platform for photoelectrochemical CO 2 conversion [ 136 ]. Furthermore, new characterization techniques for C-based materials and amorphous materials could open up new possibilities for optimization, such as thermal-optic effects studied using two-wave mixing [ 137 ], bandgap measurements using Kelvin force microscopy [ 138 ], structural determination using atomic resolution electron tomography [ 139 ], and material simulations using molecular dynamics [ 140 , 141 ].…”

Amorphous SiC Thin Films Deposited by Plasma-Enhanced Chemical Vapor Deposition for Passivation in Biomedical Devices