This disclosure provides systems, methods, and apparatus related to thermoelectric polymer aerogels. In one aspect, a method includes depositing a solution on a substrate. The solution comprises a thermoelectric polymer. Solvent of the solution is removed to form a layer of the thermoelectric polymer. The layer is placed in a polar solvent to form a gel comprising the thermoelectric polymer. The gel is cooled to freeze the polar solvent. The gel is placed in a vacuum environment to sublimate the polar solvent from the gel to form an aerogel comprising the thermoelectric polymer.

A flexible display device and a method for manufacturing the flexible display device are provided by embodiments of the present application, which solve problems that a module of a flexible active-matrix organic light emitting diode has a poor moisture and oxygen blocking effect on a side, and an edge is prone to fracture or be peeled off when bent. A flexible display device provided by an embodiment of the application includes a display substrate, and an encapsulating film layer disposed on a surface of the display substrate. An edge of the encapsulating film layer includes a concave-convex sawtooth structure.

Generally, this disclosure provides systems, devices and methods for improved electrical coupling of multiple ground planes of a device. The device may include a plurality of ground planes and an electrically conductive ground clip. The ground clip may include a base portion configured to secure the ground clip to the device and a plurality of spring fingers. Each of the spring fingers may be configured to contact and electrically couple to one of the plurality of ground planes, wherein the ground clip is to provide a conduction path between each of the spring fingers. One of the spring fingers may pass through an opening or cut-through in a first ground plane to contact a second ground plane. The device may be a mobile communication or computing platform.

A thermoelectric generation module having: a base material; a plurality of electrodes disposed on the base material; and a thermoelectric conversion layer that coats each of the electrodes individually leaving a portion of the electrode to which a wiring is to be connected, wherein the thermoelectric conversion layer adheres to the base material around the electrode excluding the portion of the electrode to which the wiring is to be connected.

An embodiment of the present disclosure is directed to a thermoelectric polymer composite. The composite comprises: at least one polymer selected from semiconducting polymers and conducting polymers; and at least one particle inclusion having one or more dimensions of 1 millimeter or less and at least one dimension of 10 nanometer or more. A sufficient amount of the particle inclusion is distributed within the polymer so that the power factor of the composite is greater that the power factor of either the polymer or the particle inclusion separately.

A thermoelectric material comprising carbon nanotubes and lignin. The carbon nanotubes are present as fibres and the lignin is present in pores and/or voids in the carbon nanotube fibres. The lignin may act as a dopant to increase the thermoelectric efficiency of the carbon nanotubes, multi-walled carbon nanotubes in particular. A method of forming a thermoelectric material involving impregnating fibres of carbon nanotubes with lignin, is also provided. A thermoelectric element, a fabric and a thermoelectric device comprising the thermoelectric material are also provided. The thermoelectric material may be particularly useful for the production of wearable thermoelectric devices.

A display device includes a substrate having a display area, in which an image is displayed, and a non-display area, in which no image is displayed. The non-display area is disposed on at least one side of the display area. A plurality of pixels is disposed in the display area. An encapsulation layer is disposed on the plurality of pixels. Adam unit is disposed in the non-display area. The dam unit includes a body part and a plurality of protrusions. Each of the plurality of protrusions protrudes from the body part.

A display device includes: a substrate on which a plurality of islands and a plurality of bridges connecting the plurality of islands to each other are defined; a plurality of pixels disposed in each of the plurality of islands; and a wire disposed in each of the plurality of bridges and connected to the plurality of pixels, where the plurality of islands and the plurality of bridges are defined based on cutout portions of the substrate, and a vertex of a cutout portion between one of the plurality of islands and a bridge connected to the one of the plurality of islands is an intersection of a straight line and a curved line.

Disclosed is an organic light emitting display device including an anode, a cathode, a plurality of organic layers and a partition member. The plurality of organic layers is disposed between the anode and the cathode, where at least one layer is separated to minimize current leakage into neighboring pixels. The partition member is disposed between the neighboring pixels and configured to separate the plurality of organic layers. The least one separated layer includes a charge generation layer. Because at least one layer is separated, current leakage into neighboring pixels can be minimized. Accordingly, defects resulting from light leakage and the mixing of colors of light from neighboring pixels may be reduced and display quality is enhanced.

Provided is a compound which is mixed with a thermoelectric conversion material matrix as a phonon scattering material. The compound is represented by the following formula: ##STR00001##
(In the above formula, G.sup.1 represents a functional group capable of binding to the thermoelectric conversion material matrix; G.sup.2 independently represents G.sup.1 or CH.sub.3; 0≦m≦5; 0≦m′≦5; 6≦n≦1000; and 1/1000<(the number of G.sup.1/n)≦1).