An electromagnetic shielding assembly may include a transparent substrate layer and a transparent active layer positioned with respect to the substrate, wherein the active layer is configured to absorb electromagnetic radiation having a first wavelength and emit electromagnetic radiation having a second wavelength, the second wavelength being different than the first wavelength, the active layer includes fluorescent molecules combined with a base material, the fluorescent molecules being configured to absorb electromagnetic radiation having the first wavelength and emit the electromagnetic radiation having the second wavelength, wherein the first wavelength is in a visible electromagnetic spectrum and the second wavelength is in a non-visible electromagnetic spectrum.

The present invention realizes an electric-wave absorber of a so-called electric-wave interference type, which can favorably absorb absorption electric waves of a desired frequency even when a protective layer for protecting an electric resistance film is formed on the surface of the electric resistance film, and a manufacturing method for the electric-wave absorber. In an electric-wave absorber of an electric-wave interference type, which is formed by sequentially stacking an electric resistance film 1, a dielectric layer 2, and an electric-wave shielding layer 3, absorption electric waves to be absorbed by the electric-wave absorber are waves in a high frequency band in or above a millimeter-wave band, a protective layer 4 is included on the electric resistance film, and a thickness of the dielectric layer is smaller than a reference thickness dst obtained according to the frequency of the absorption electric waves and the permittivity of the dielectric layer.

Am RF/EMF radiation shielding device with a transparent film layer embedded or covered with radiation-blocking material configured to absorb or deflect RF/EMF/E3 F7 radiation with the ability to utilize the mobile device's touchscreen. Formed on the radiation-blocking material are partitions or gaps where the radiation blocking areas are absent. The partitions divide the radiation-blocking material into a plurality of isolated blocking areas. In one embodiment, the shielding device is a single film layer; in another, two or more film layers are stacked, registered, and separated by an insulated layer.

Methods, systems, and apparatuses for electromagnetic interference (EMI) shielding are provided. An apparatus comprises a plurality of electrical components coupled to a substrate. The plurality of electrical components comprises a first electrical component coupled to a first region of the substrate and at least one other electrical component coupled to at least one other region of the substrate. The first electrical component is configured to emit electromagnetic waves. The apparatus also comprises an EMI shield forming a conductive envelopment around the first region. The first electrical component is inside the conductive envelopment and the one other electrical component is outside of the conductive envelopment. The EMI shield comprises an aperture positioned above the first electrical component. The apparatus further comprises a lens coupled to the EMI shield. The lens is positioned above the first electrical component and is substantially aligned with the aperture.

Methods, systems, and apparatuses for electromagnetic interference (EMI) shielding are provided. An apparatus comprises a plurality of electrical components coupled to a substrate. The plurality of electrical components comprises a first electrical component coupled to a first region of the substrate and at least one other electrical component coupled to at least one other region of the substrate. The first electrical component is configured to emit electromagnetic waves. The apparatus also comprises an EMI shield forming a conductive envelopment around the first region. The first electrical component is inside the conductive envelopment and the one other electrical component is outside of the conductive envelopment. The EMI shield comprises an aperture positioned above the first electrical component. The apparatus further comprises a lens coupled to the EMI shield. The lens is positioned above the first electrical component and is substantially aligned with the aperture.

A transparent conductive film (TCF) and methods for creating the TCF. The TCF includes a substrate having a surface, a metal mesh layer over at least a portion of the surface of the substrate, and a conductive layer over the metal mesh layer. The conductive layer includes carbon nanotubes and a binder.

A semiconductor element according to embodiment of the inventive concept may include a first glass plate having a first surface and a second surface opposing the first surface, a metal frame surrounding an edge of the first glass plate, the metal frame being electrically connected to a ground line, a first transparent conductive layer provided on the first surface of the first glass plate, and a circuit block provided on the first surface of the first glass plate and spaced apart from the first transparent conductive layer. The first transparent conductive layer may have a lattice structure in which first unit lattices are arranged along one line, and an entire length of the one line may be about 0.25 times to about 0.50 times a wavelength of an electromagnetic wave to be blocked.

Methods, systems, and apparatuses for electromagnetic interference (EMI) shielding are provided. An apparatus comprises a plurality of electrical components coupled to a substrate. The plurality of electrical components comprises a first electrical component coupled to a first region of the substrate and at least one other electrical component coupled to at least one other region of the substrate. The first electrical component is configured to emit electromagnetic waves. The apparatus also comprises an EMI shield forming a conductive envelopment around the first region. The first electrical component is inside the conductive envelopment and the one other electrical component is outside of the conductive envelopment. The EMI shield comprises an aperture positioned above the first electrical component. The apparatus further comprises a lens coupled to the EMI shield. The lens is positioned above the first electrical component and is substantially aligned with the aperture.

A self-adaptive shielding device is suitable for a lens or a window of a piece of equipment provided with an electrically conductive enclosure containing an optical or RF sensor. The device includes a shielding screen having a switchable RF shielding mesh of micrometric pitch at least partially surrounded by a border of insulator-metal transition material arranged between the mesh and an electrically conductive envelope. A susceptor element is arranged facing the insulator-metal transition material and transforms incident electromagnetic energy (RFH) into activation heat for the insulator-metal transition material. The susceptor element causes a transition to the conductive state of the insulator-metal transition material under the action of the electromagnetic energy so as to electrically connect the mesh to the electrically conductive envelope when the incident electromagnetic energy exceeds a given threshold.