Abstract: The present disclosure is directed towards systems and methods for transferring graphene from the surface of one substrate to another. In one particular embodiment, the graphene layer is grown on a surface of a first substrate, where the bottom of the first substrate is then affixed to the surface of a second substrate. The second substrate may include material made of a rigid or semi-rigid composition to provide structural support and backing to the first substrate. The graphene layer may then be delaminated from the first substrate and transferred to a target surface, such as the surface of an electronic device or biosensor.

Abstract: Embodiments of the disclosed technology include patterning a graphene sheet for biosensor and electronic applications using lithographic patterning techniques. More specifically, the present disclosure is directed towards the method of patterning a graphene sheet with a hard mask metal layer. The hard mask metal layer may include an inert metal, which may protect the graphene sheet from being contaminated or damaged during the patterning process.

Abstract: Embodiments of the disclosed technology include depositing a passivation layer onto a surface of a wafer that may include a graphene layer. The passivation layer may protect and isolate the graphene layer from electrical and chemical conditions that may damage the graphene layer. As such, the passivation layer may further protect the graphene sensor from being damaged and impaired for its intended use. Additionally, the passivation layer may be patterned to expose select areas of the graphene layer below the passivation layer, thus creating graphene wells and exposing the graphene layer to the appropriate chemicals and solutions.

Abstract: A chemically differentiated sensor array system includes a plurality of environmentally-gated transistors and an environmental gate, wherein the environmental gate includes a liquid solution and each environmentally-gated transistor includes a drain, a source, and a Carbon-based substrate channel, the drain electrically couples to a first location on the substrate channel, the source electrically couples to a second location on the substrate channel separated by a gap from the first location on the substrate channel, the environmental gate covers and contacts the substrate channel, a first insulating layer covers and separates the drain from the environmental gate, and a second insulating layer covers and separates the source from the environmental gate.

Abstract: A DNA sequencing and blood chemistry analysis device is provided including one or more sensor chips and one or more sample wells, wherein each sample well is configured to form a seal with one of the sensors. The one or more sensor chips may comprise Graphene transistors, and each transistor having an associated sequencing probe. The sensor chips interact with a biological sample introduced into the sample well, wherein changes in the current, transconductance, and resistance of the Graphene transistors are indicative of a DNA binding process. Based on the associated sequencing probes, the DNA sequence present in a biological sample can be identified.

Abstract: A biological sample analysis device includes a casing that encloses a biological sample delivery system hydraulically coupled to a sensor, wherein the sensor includes a plurality of Graphene transistors and each transistor covalently bonds with a biomarker causing the electrical properties of the transistor to measurably change when the biomarker is exposed to corresponding antibodies within an infected biological sample.

Abstract: A chemically differentiated sensor array system includes a plurality of environmentally-gated transistors and an environmental gate, wherein the environmental gate includes a liquid solution and each environmentally-gated transistor includes a drain, a source, and a Carbon-based substrate channel, the drain electrically couples to a first location on the substrate channel, the source electrically couples to a second location on the substrate channel separated by a gap from the first location on the substrate channel, the environmental gate covers and contacts the substrate channel, a first insulating layer covers and separates the drain from the environmental gate, and a second insulating layer covers and separates the source from the environmental gate.

Abstract: A biological sample analysis device includes a casing that encloses a biological sample delivery system hydraulically coupled to a sensor, wherein the sensor includes a plurality of Graphene transistors and each transistor covalently bonds with a biomarker causing the electrical properties of the transistor to measurably change when the biomarker is exposed to corresponding antibodies within an infected biological sample.

Abstract: A DNA sequencing and blood chemistry analysis device is provided including one or more sensor chips and one or more sample wells, wherein each sample well is configured to form a seal with one of the sensors. The one or more sensor chips may comprise Graphene transistors, and each transistor having an associated sequencing probe. The sensor chips interact with a biological sample introduced into the sample well, wherein changes in the current, transconductance, and resistance of the Graphene transistors are indicative of a DNA binding process. Based on the associated sequencing probes, the DNA sequence present in a biological sample can be identified.

Abstract: A biological sample analysis device includes a casing that encloses a biological sample delivery system hydraulically coupled to a sensor, wherein the sensor includes a plurality of Graphene transistors and each transistor covalently bonds with a biomarker causing the electrical properties of the transistor to measurably change when the biomarker is exposed to corresponding antibodies within an infected biological sample.