The present disclosure provides a display panel and an encapsulating method thereof, the display panel includes: a first substrate; a second substrate; and an adhesive layer disposed between the first substrate and the second substrate; the adhesive layer is located in a peripheral region of the first substrate and the second substrate for sealing the first substrate and the second substrate, wherein the adhesive layer is uniformly mixed with light emitting materials, so that light intensity of the light emitting materials at different positions in the adhesive layer is detected by a detecting device.

Provided herein are polysiloxane-based composite materials comprising a high weight percentage of elemental components (e.g., elemental boron, elemental copper, elemental bismuth, elemental lead) and low levels of carbon nanofibers. The elemental components may be present in the composite materials at levels greater than 25% by weight. Also provided herein are methods of forming the composite materials that have desirable flexibility and shielding properties. The invention provides a versatile composite material that is compliant and moldable, while still comprising high levels of the elemental shielding components. The materials are particularly useful for applications in which radiation shielding or neutron capture are desired.

It is related to a metal/polymer nanocomposite film comprising gold nanoparticle which has gold mirror feature, comprises acrylic based oligomer, acrylic based monomer, 2-mercapto thioxanthone which is an one-component type II. radicalic photoinitiator and chloroauric acid.

An inventive composition and process for formation of a conductive bonding film are disclosed. The invention combines adhesive bonding sheet technologies (e.g. die attach films, or DAFs) with the electrical and thermal conductivity performance of transient liquid phase sintered paste compositions. The invention films are characterized by high bulk thermal and electrical conductivity within the film as well as low and stable thermal and electrical resistance at the interfaces between the inventive film and metallized adherends.

Provided is a bismuth golf ball with improved carry distance and fracture strength by adding a nano bismuth reformed by using plasma or a nano bismuth alloy manufactured by using the nano bismuth to a resin composition as a base material as compared with a bismuth golf ball in the related art. Since the nano bismuth golf ball has a more densified internal structure due to a higher content of bismuth as compared with the bismuth golf ball, the resilient elasticity is improved, and thus, the carry distance is increased.

Disclosed herein is a sliding member that has a coating layer serving as a sliding surface thereof so that even when foreign matter enters between the coating layer and a partner member, smoothness between them is maintained to prevent the occurrence of seizing. When the coating layer has an elastic recovery ratio of less than 60%, foreign matter that has entered between the coating layer and the sliding surface of a partner member is efficiently embedded in the coating layer. When the coating layer is formed of a resin composition, the resin composition contains a binder resin, a solid lubricant, and metal particles having a Young's modulus of 10 GPa or more but 100 GPa or less.

A method can include polymerizing a blend of materials where the materials include polymeric material and a degradable alloy material; and forming a degradable component from the polymerized blend of materials. Such a method can include exposing the degradable component to water where the degradable alloy material reacts with the water to at least in part degrade the component.

A conductive composition includes a mono-acid hybrid that includes an unprotected, single reactive group. The mono-acid hybrid may include substantially non-reactive groups elsewhere such that the mono-acid hybrid is functional as a chain terminator. Methods and devices using the compositions are also disclosed.

The present disclosure provides a method for preparing a MnBi based resin magnet, which can provide a MnBi based resin magnet with excellent magnetic properties by forming a polymer coating on the surface of a MnBi based magnetic phase powder, and a MnBi based resin magnet prepared therefrom.

A thermally conductive composition including a curable component, a curing agent configured to cure the curable component, and a metallic filler is provided. The metallic filler contains thermally conductive particles and low-melting-point metallic particles. A volume average particle diameter of the thermally conductive particles is greater than a volume average particle diameter of the low-melting-point metallic particles. A melting point of the low-melting-point metallic particles is lower than a thermal curing treatment temperature of the thermally conductive composition.