This invention relates generally to uses of novel nanomaterial composition and the systems in which they are used, and more particularly to nanomaterial compositions generally comprising carbon and a metal, which composition can be exposed to pulsed emissions to react, activate, combine, or sinter the nanomaterial composition. The nanomaterial compositions can alternatively be utilized at ambient temperature or under other means to cause such reaction, activation, combination, or sintering to occur.

The disclosure discloses a packaging method and a packaging device for a PCBA board. The PCBA board comprises a printed circuit board and an electronic element arranged on the printed circuit board; the maximum height of the electronic element relative to surface of the printed circuit board is less than 1 cm. The packaging method comprising: during glue spraying process, controlling a glue spraying assembly to spray UV glue liquid to a target spraying area of the PCBA board by moving back and forth in a straight line in a horizontal direction. The packaging method for a PCBA board provided by the present disclosure realizes packaging and protection of electronic components by spraying UV glue liquid to an area of the PCBA board that needs protection by the glue spraying assembly.

A method for producing an electrically conductive thin film on a substrate is disclosed. Initially, a reducible metal compound and a reducing agent are dispersed in a liquid. The dispersion is then deposited on a substrate as a thin film. The thin film along with the substrate is subsequently exposed to a pulsed electromagnetic emission to chemically react with the reducible metal compound and the reducing agent such that the thin film becomes electrically conductive.

The disclosure relates to thermosetting reinforced resin compositions and methods of forming boards, sheets and/or films using of porous particulates impregnated with embedded live monomer and/or oligomer and/or polymer configured to partially leach out a functional terminal end of the live monomer and/or oligomer and/or polymer and react with a cross-linking agent and photoinitiated polymer radicals to form a reinforced board, sheet and/or film of hybrid interpenetrating networks.

A method of fabricating a composite conductive film is provided. The method includes providing, as a matrix, a layer of cross-linkable polymer, where the cross-linkable polymer is in a non-cross-linked state. The method further includes introducing inorganic nanowires upon a surface of the layer of cross-linkable polymer. The inorganic nanowires are, in isolated form, characterized by a first conductivity stability temperature. The method further includes embedding at least some of the inorganic nanowires into the layer of cross-linkable polymer to form an inorganic mesh, thereby forming the composite conductive film. The method further includes cross-linking the polymer within a surface portion of the composite conductive film. Cross-linking the polymer within the surface portion of the composite conductive film results in the surface portion having a second conductivity stability temperature that is greater than the first conductivity stability temperature.

The present invention discloses a carrying device, a wet etching apparatus and a usage method thereof. The carrying device comprises a carrying body and a heating unit both disposed under a to-be-processed substrate, the carrying body is used for carrying the to-be-processed substrate such that the to-be-processed substrate is placed inclined; the heating unit is used for heating the to-be-processed substrate, such that temperature of the to-be-processed substrate rises gradually from a top portion to a bottom portion thereof. In the technical solution of the present invention, by disposing the heating unit under the to-be-processed substrate, the temperature of the to-be-processed substrate rises gradually from the top portion to the bottom portion thereof, thus etch rate of the etchant on the bottom portion of the to-be-processed substrate can be increased, and uniformity of etch rate in the inclined wet etching process is improved.

The present invention has as its object the provision of a desmear treatment device and a desmear treatment method capable of sufficiently removing smear remaining in a to-be-treated object in a short amount of time. The desmear treatment device of the present invention includes: a treatment chamber in which a to-be-treated object is disposed; a light source unit in which an ultraviolet lamp for irradiating the to-be-treated object with ultraviolet rays is housed; a light transmissive window that is disposed between the treatment chamber and the light source unit and that transmits the ultraviolet rays from the ultraviolet lamps; and treatment gas supply means for supplying a treatment gas containing a source of active species to the treatment chamber. The treatment gas supply means includes a treatment gas supply source and a control unit for controlling a supplied amount of the treatment gas from the treatment gas supply source. The control unit has a function of controlling the treatment gas from the treatment gas supply source to be supplied as a purge gas when irradiating the to-be-treated object with ultraviolet rays.

A composite conductive film is provided that includes a layer of cross-linked polymer having a surface and an inorganic mesh comprising a plurality of nanowires of an inorganic material. The nanowires are, in isolated form, characterized by a first conductivity stability temperature. Further, the plurality of nanowires is embedded within at least a region of the layer of cross-linked polymer, where the region is continuous from the surface of the layer of cross-linked polymer. The layer of cross-linked polymer and the inorganic mesh are arranged to form the composite conductive film having a second conductivity stability temperature that is greater than the first conductivity stability temperature.

An integrated circuit that includes a substrate having a shape memory material (SMM), the SMM is in a first deformed state and has a first crystallography structure and a first configuration, the SMM is able to be deformed from a first configuration to a second configuration, the SMM changes to a second crystallography structure and deforms back to the first configuration upon receiving energy, the SMM returns to the first crystallography structure upon receiving a different amount of energy; and an electronic component attached to substrate. In other forms, the SMM is in a first deformed state and has a first polymeric conformation and a first configuration, the SMM changes from a first polymeric conformation to a second polymeric conformation and be deformed from a first configuration to a second configuration, the SMM changes returns to the first polymeric conformation and deforms back to the first configuration upon receiving energy.

An integrated circuit that includes a substrate having a shape memory material (SMM), the SMM is in a first deformed state and has a first crystallography structure and a first configuration, the SMM is able to be deformed from a first configuration to a second configuration, the SMM changes to a second crystallography structure and deforms back to the first configuration upon receiving energy, the SMM returns to the first crystallography structure upon receiving a different amount of energy; and an electronic component attached to substrate. In other forms, the SMM is in a first deformed state and has a first polymeric conformation and a first configuration, the SMM changes from a first polymeric conformation to a second polymeric conformation and be deformed from a first configuration to a second configuration, the SMM changes returns to the first polymeric conformation and deforms back to the first configuration upon receiving energy.