Abstract: Principles for reliable manufacturing carbon-based electrodes with arbitrary sensitivity and homogeneity are provided. Specifically, the sensitivity of carbon-based electrodes can be engineered by changing the density of sp2 type defects present in a multilayer graphene film. The engineered carbon-based electrodes can be used as a passive sensing element in electrochemical measurement of a target analyte. Carbon-based electrodes are also disclosed that have sp2 hybridization and can include multilayer graphene films. The disclosed carbon-based electrodes have a density of zero-dimensional defects (i.e., point-like defects) which provides enhanced area-normalized sensitivity when used in sensing applications. The maximum area-normalized sensitivity is achieved at the point defect density of 4-5×1012 cm?2.

Abstract: Systems and methods for measuring electrophysiological and electrochemical signals in a portion of a body of a subject are provided. The structure includes an array of electrochemical sensors made of miniaturized multi-layer graphene, an array of electrophysiological electrodes, an integrated front-end readout circuit, and narrow silicon shafts with metal spines. The sensor arrays offer significantly higher sensitivity than conventional methods and enable simultaneous, multi-site measurement of chemical and electrophysiological. The front-end circuit contains features that allow significant improvement in detection of the resulting electrochemical current produced by the electrochemical sensing electrodes. The silicone probes allow measurements deep in the body.

Abstract: Principles for reliable manufacturing carbon-based electrodes with arbitrary sensitivity and homogeneity are provided. Specifically, the sensitivity of carbon-based electrodes can be engineered by changing the density of sp2 type defects present in a multilayer graphene film. The engineered carbon-based electrodes can be used as a passive sensing element in electrochemical measurement of a target analyte. Carbon-based electrodes are also disclosed that have sp2 hybridization and can include multilayer graphene films. The disclosed carbon-based electrodes have a density of zero-dimensional defects (i.e., point-like defects) which provides enhanced area-normalized sensitivity when used in sensing applications. The maximum area-normalized sensitivity is achieved at the point defect density of 4-5×1012 cm?2.

Abstract: An energy storage device containing a carbon-based electrode composed of graphitic film having a density of specific types of structural defects is explained. The carbon-based electrode may be used as an electrode in a supercapacitor or as an anode layer of a rechargeable battery. A distributed model is developed that predicts the area-normalized apparent capacitance from the density of point and line defects in the graphitic film. From this model, one can engineer the apparent capacitance by controlling the density of point and line defects.

Abstract: Systems and methods for measuring electrophysiological and electrochemical signals in a portion of a body of a subject are provided. The structure includes an array of electrochemical sensors made of miniaturized multi-layer graphene, an array of electrophysiological electrodes, an integrated front-end readout circuit, and narrow silicon shafts with metal spines. The sensor arrays offer significantly higher sensitivity than conventional methods and enable simultaneous, multi-site measurement of chemical and electrophysiological. The front-end circuit contains features that allow significant improvement in detection of the resulting electrochemical current produced by the electrochemical sensing electrodes. The silicone probes allow measurements deep in the body.