Abstract: Methods and systems for generating a circuit identification number include determining a propagation time delay across a scan chain of known length; comparing the propagation time delay to a threshold associated with the scan chain length; storing an identifier bit based on the result of the comparison; repeating the steps of determining, comparing, and storing until a number of stored identifier bits reaches a threshold number; and outputting the stored identifier bits.

Abstract: Increased protection of areas of a chip are provided by both a mask structure of increased robustness in regard to semiconductor manufacturing processes or which can be removed with increased selectivity and controllability in regard to underlying materials, or both. Mask structures are provided which exhibit an interface of a chemical reaction, grain or material type which can be exploited to enhance either or both types of protection. Structures of such masks include TERA material which can be converted or hydrated and selectively etched using a mixture of hydrogen fluoride and a hygroscopic acid or organic solvent, and two layer structures of similar or dissimilar materials.

Abstract: According to an aspect of the present principles, there is provided a method and an authentication apparatus. The method includes arranging a plurality of graphene resistors in parallel or series. The method further includes forming a unique identification code based on respective temperatures emanating from or respective voltages output from the plurality of graphene resistors when the plurality of graphene resistors are in a powered state.

Abstract: An interconnect structure includes a patterned and cured dielectric layer located directly on a surface of a patterned permanent antireflective coating. The patterned and cured dielectric layer and the permanent antireflective coating form shaped openings. The shaped openings include an inverse profile which narrows towards a top of the shaped openings. A conductive structure fills the shaped openings wherein the patterned and cured dielectric layer and the permanent antireflective coating each have a conductively filled region.

Abstract: A device having a physical unclonable function includes an integrated circuit and a phase change memory embedded in the integrated circuit and including a plurality of cells, where the phase change memory is set in a manner that creates a phase variation over the plurality of cells, and where the phase variation comprises the physical unclonable function. In another embodiment, a device having a physical unclonable function includes a phase change memory embedded in the device and comprising a plurality of cells, where the phase change memory is set in a manner that creates a phase variation over the plurality of cells, and where the phase variation comprises the physical unclonable function, and a measurement circuit for extracting the physical unclonable function from the phase change memory.

Abstract: Increased protection of areas of a chip are provided by both a mask structure of increased robustness in regard to semiconductor manufacturing processes or which can be removed with increased selectivity and controllability in regard to underlying materials, or both. Mask structures are provided which exhibit an interface of a chemical reaction, grain or material type which can be exploited to enhance either or both types of protection. Structures of such masks include TERA material which can be converted or hydrated and selectively etched using a mixture of hydrogen fluoride and a hygroscopic acid or organic solvent, and two layer structures of similar or dissimilar materials.

Abstract: Hall effect devices and field effect transistors are formed incorporating a carbon-based nanostructure layer such as carbon nanotubes and/or graphene with a sacrificial metal layer formed there over to protect the carbon-based nanostructure layer during processing.

Abstract: An interconnect structure is provided which comprises a semiconductor substrate; a patterned and cured photoresist wherein the photoresist contains a low k dielectric substitutent and contains a fortification layer on its top and sidewall surfaces forming vias or trenches; and a conductive fill material in the vias or trenches. Also provided is a method for fabricating an interconnect structure which comprises depositing a photoresist onto a semiconductor substrate, wherein the photoresist contains a low k dielectric constituent; imagewise exposing the photoresist to actinic radiation; then forming a pattern of vias or trenches in the photoresist; surface fortifying the pattern of vias or trenches proving a fortification layer on the top and sidewalls of the vias or trenches; curing the pattern of vias or trenches thereby converting the photoresist into a dielectric; and filling the vias and trenches with a conductive fill material.

Abstract: Interconnect structures including a graphene cap located on exposed surfaces of a copper structure are provided. In some embodiments, the graphene cap is located only atop the uppermost surface of the copper structure, while in other embodiments the graphene cap is located along vertical sidewalls and atop the uppermost surface of the copper structure. The copper structure is located within a dielectric material.

Abstract: Methods, systems and devices related to authentication of chips using physical physical unclonable functions (PUFs) are disclosed. In accordance one such method, a test voltage is applied to a PUF system including a first subset of PUF elements that are arranged in series and a second subset of PUF elements that are arranged in series, where the first subset of PUF elements is arranged in parallel with respect to the second subset of PUF elements. In addition, the PUF system is measured to obtain at least one differential of states between the first subset of PUF elements and the second subset of PUF elements. Further, the method includes outputting an authentication sequence for the circuit that is based on the one or more differentials of states.

Abstract: Mechanisms are provided for chip (e.g., semiconductor chip) identification (e.g., low cost secure identification). In one example, a method of manufacturing for implementing integrated chip identification is provided. In another example, a method of using a chip with an integrated identification is provided.

Abstract: A system for exposing a resist layer to an image that includes a layer reflective to imaging tool radiation and a resist layer having a region of photosensitivity over the reflective layer. An imaging tool projects radiation containing an aerial image onto the resist layer, with a portion of the radiation containing the aerial image passing through the resist and reflecting back to the resist to form an interference pattern of the projected aerial image through the resist layer thickness. The thickness and location of the resist layer region of photosensitivity are selected to include from within the interference pattern higher contrast portions of the interference pattern in the direction of the resist thickness, and to exclude lower contrast portions of the interference pattern in the resist thickness direction from said resist layer region of photosensitivity, to improve contrast of the aerial image in said resist layer region of photosensitivity.

Abstract: The present disclosure relates to integrated circuits having tamper detection and response devices and methods for manufacturing such integrated circuits. One integrated circuit having a tamper detection and response device includes at least one photovoltaic cell and at least one memory cell coupled to the at least one photovoltaic cell. When the at least one photovoltaic cell is exposed to radiation, the at least one photovoltaic cell generates a current that causes an alteration to a memory state of the at least one memory cell. Another integrated circuit having a tamper detection and response device includes at least one photovoltaic cell and a reactive material coupled to the at least one photovoltaic cell, wherein a current from the at least one photovoltaic cell triggers an exothermic reaction in the reactive material.

Abstract: The present disclosure relates to an antifuse for preventing a flow of electrical current in an integrated circuit. One such antifuse includes a reactive material and a silicon region thermally coupled to the reactive material, where an electrical current to the reactive material causes the reactive material to release heat which transitions the silicon region from a high resistance state to a low resistance state. Another such antifuse includes a reactive material, at least one metal and a silicon region adjacent to the at least one metal and thermally coupled to the reactive material, where an electrical current to the reactive material causes the reactive material to release heat which transitions the silicon region from a high resistance state to a low resistance state.

Abstract: A method of manufacturing a secure device having a physical unclonable function includes embedding a phase change memory in the secure device, where the phase change memory includes a plurality of cells, and setting the phase change memory in a manner that results in a phase variation over the plurality of cells, wherein the phase variation is the physical unclonable function. A method for retrieving a cryptographic key from an integrated circuit, wherein the cryptographic key is stored in the integrated circuit, includes measuring a property of a phase change memory embedded in the integrated circuit, wherein the phase change memory includes a plurality of cells and the property is a function of a phase variation over the plurality of cells, deriving a signature from the property, and deriving the cryptographic key from the signature.

Abstract: A method for transfer of a two-dimensional material includes forming a spreading layer of a two-dimensional material on a substrate, the spreading layer having a monolayer. A stressor layer is formed on the spreading layer, and the stressor layer is configured to apply stress to a closest monolayer of the spreading layer. The closest monolayer is exfoliated by mechanically splitting the spreading layer wherein the closest monolayer remains on the stressor layer.

Abstract: Hall effect devices and field effect transistors are formed incorporating a carbon-based nanostructure layer such as carbon nanotubes and/or graphene with a sacrificial metal layer formed there over to protect the carbon-based nanostructure layer during processing.

Abstract: The present disclosure relates to integrated circuits having tamper detection and response devices and methods for manufacturing such integrated circuits. One integrated circuit having a tamper detection and response device includes at least one reactive material and at least one memory cell coupled to the at least one reactive material. An exothermic reaction in the at least one reactive material causes an alteration to a memory state of the at least one memory cell. Another integrated circuit having a tamper detection and response device includes a substrate, at least one gate on the substrate, and a reactive material between a first well and a second well of the at least one gate. A reaction in the reactive material causes a short in the gate.

Abstract: Systems for reliability testing include a picometer configured to measure a leakage current across a device under test (DUT); a camera configured to measure optical emissions from the DUT based on a timing of the measurement of the leakage current; and a test system configured to apply a stress voltage to the DUT and to correlate the leakage current with the optical emissions using a processor to determine a time and location of a defect occurrence within the DUT by locating instances of increased noise in the leakage current that correspond in time with instances of increased optical emissions.

Abstract: The present disclosure relates to secure devices having a physical unclonable function and methods of manufacturing such secure devices. One device includes at least one graphene layer representing a physical unclonable function and a measurement circuit for measuring at least one property of the at least one graphene layer. Another device includes at least a first graphene layer and a second graphene layer representing a physical unclonable function, where one of the graphene layers has been subjected to a variability enhancement such that a measurable property is different for each of the layers. A method includes providing a substrate for a secure device and providing at least one graphene layer on the substrate, the at least one graphene layer representing a physical unclonable function. The providing of the at least one graphene layer includes applying at least one variability enhancement to the at least one graphene layer.