The single layer compressive substrate force sensor may include electrode patterns formed directly on a first side and second side of the compressive substrate. At least some of the electrode patterns are configured to provide a change in capacitance proportional with a compressive force applied to at least one of the electrode patterns, which compresses the compressive substrate. The single layer compressive substrate force sensor may include a first top electrode and a second top electrode pattern separated by an insulator to void contact between the electrode patterns. In operation, the first top electrode pattern and the second top electrode pattern are configured to provide projective capacitance, and thus provide detection of light touches or hover actions by an object.

The present invention relates to enhancement of detectable emissions from carbon nanodots or variants thereof by using the techniques of MEF to further enhance carbon nanodot brightness, photostability, and thus, potentially detectability in biological imaging applications by using plasmon supporting materials, such as silver island films and positioning of the carbon nanodots an optimal distance from the plasmon supporting materials.

The present invention discloses nanotechnology clothing in the form of a glove, shirt, pants or suit that can be worn to track the motion of different parts of a user's body. This tracking is utilized to provide the computer system with an immediate input representing an interaction with a computer application or a 3D simulation of the user's body motion. The present invention is used with computers, mobile phones, and head-mounted computer displays serving a variety of gaming, entertainment, sports and medical applications.

The present invention relates to enhancement of detectable emissions from carbon nanodots or variants thereof by using the techniques of MEF to further enhance carbon nanodot brightness, photostability, and thus, potentially detectability in biological imaging applications by using plasmon supporting materials, such as silver island films and positioning of the carbon nanodots an optimal distance from the plasmon supporting materials.

A terminal device for fingerprint identification may include a control component and a screen. The screen may include a screen cover, a display component, a fingerprint detection element, and a plurality of touch signal detection elements. The fingerprint detection element and the plurality of touch signal detection elements may be between the screen cover and a top surface of the display component; the fingerprint detection element may be in a free area among different touch signal detection elements; and the control component may be electrically connected with the fingerprint detection element and configured to acquire detection signal of the fingerprint detection element, generate fingerprint data based on the detection signal of the fingerprint detection element, compare the fingerprint data with reference fingerprint data stored in advance, and execute a preset control instruction if the fingerprint data matches the reference fingerprint data.

Disclosed is a method of manufacturing an electroconductive nanowire network using an electron beam, the method comprising: forming a nanowire network using electroconductive nanowires; and welding junctions of the electroconductive nanowires by irradiating an electron beam on the nanowire network, wherein the electroconductive nanowires comprise silver (Ag) nanowires and the forming of the nanowire network comprises forming the nanowire network by spin-coating a suspension in which isopropyl alcohol (IPA) and the Ag nanowires are mixed.

A device produces an electrical signal in response to a stimulus. The device is formed of a flexible substrate including a layer of fibers, for example, paper, and a solution of dispersed carbon nanotubes coated onto and within the fibers, the solution evaporated to leave carbon nanotubes intertwined within the layer of fibers. The carbon nanotubes are functionalized to be optimized for producing an electrical signal for a particular stimulus, where the stimulus includes exposure of the device to a particular gas or vapor. A number of such devices, some or all of which can be different, are housed together, for producing a complex electronic signal, or for sensing any of a wide variety of stimulus.

A composition comprising discrete functionalized carbon nanotubes attached to microfibrillated fibers and a plurality of the discrete carbon nanotubes are opened ended is disclosed. The composition may further comprise electroactive, photoactive, magnetic or catalyst particles. These new compositions can be used in energy storage or energy collection devices such as batteries, capacitors, photovoltaics and sensors.

The present invention relates to enhancement of detectable emissions from carbon nanodots or variants thereof by using the techniques of MEF to further enhance carbon nanodot brightness, photostability, and thus, potentially detectability in biological imaging applications by using plasmon supporting materials, such as silver island films and positioning of the carbon nanodots an optimal distance from the plasmon supporting materials.

A modular platform unit comprising a plurality of sensors for the combined sensing of pressure, temperature and humidity. In particular, the sensors are composed of a layer of metallic-capped nanoparticles (MCNP) casted on a flexible substrate or a rigid substrate. Integration of the platform unit for artificial or electronic skin applications is disclosed.