A method for in-situ generation of microbubbles is disclosed. The method includes preparing an electrochemical apparatus, where the electrochemical apparatus includes a substrate and an integrated three-electrodes array patterned on the substrate. The integrated three-electrodes array includes a working electrode, a reference electrode, and a counter electrode. The method further includes growing a nano-structured layer on the working electrode of the integrated three-electrodes array, putting the electrochemical apparatus in contact with a medium fluid, electrolyzing the medium fluid by applying an instantaneous electrical potential to the electrochemical apparatus, and generating a plurality of microbubbles around the electrochemical apparatus in contact with the medium fluid responsive to electrolyzing of the medium fluid.

Disclosed herein is a method of preparing a white light-emitting material. The method of preparing a white light-emitting material includes the steps of: (a) depositing a metal for the formation of a blue light-emitting material on a substrate by performing thermal evaporation; (b) forming a material in which green and blue light-emitting materials are hybridized by placing the substrate, on which the metal film is deposited in step (a), in a plasma-enhanced chemical vapor deposition (PECVD) reactor and exposing the substrate to silicon (Si) and oxygen (O) in a plasma state; and (c) forming a red light-emitting material in the material formed in step (b) by annealing the material formed in step (b) so that the red, green and blue light-emitting materials are hybridized.

A method of making an enhanced aluminium mirror for vacuum ultraviolet (VUV) optics includes depositing a reflective coating comprising aluminium metal to at least one surface of a substrate through physical vapor deposition (PVD) to produce a mirror comprising the substrate and the reflective coating. The method further includes removing aluminium oxides from an outer surface of the reflective coating by conducting atomic layer etching (ALE) in an Atomic Layer Deposition (ALD) system to produce an etched surface of the reflective coating and depositing an ALD protective layer onto the etched surface of the reflective coating by conducting atomic layer deposition in the ALD system to produce the enhanced aluminium mirror. The enhanced aluminium mirror includes the substrate, the reflective coating deposited on the substrate, and the ALD protective layer covering the etched surface of the reflective coating.

A method for nanoparticle fabrication deposits a seed layer of a transparent conductive oxide onto a substrate and deposits a layer of a plasmonic metal onto the transparent conductive oxide layer. The method forms nanoparticles from the deposited metal by transporting the substrate along a transport path and, as the substrate is moving, energizing one or more flash lamps disposed along the transport path to apply a plurality of light pulses that impart a dewetting energy to the deposited metal layer.

An electrochemical probe for in-vivo measurement of H.sub.2O.sub.2 oxidation within a living tissue. The electrochemical probe includes a sensing part and a handle. The sensing part includes a working electrode including a first biocompatible conductive needle, a counter electrode including a second biocompatible conductive needle, and a reference electrode including a third biocompatible conductive needle. The working electrode, the counter electrode, and the reference electrode are configured to put in contact with the living tissue by inserting the sensing part into the living tissue. The handle includes an insertion part that may be configured to insert the sensing part into the living tissue. The sensing part is attached to the insertion part.

The present application provides a method for preparing a perovskite film, and a related perovskite film, solar cell and solar cell device thereof. The preparation method may include the steps of (1) providing a target material comprising the following elements: lead, a halogen, and one or more alkali metals; (2) sputtering using the target material in step (1), where a process gas is a noble gas, optionally, argon, so as to obtain a film; (3) subjecting the film obtained in step (2) to a chemical bath treatment, wherein the chemical bath is a solution of AX, A is selected from one or more of formamidine or methylamine, and X is a halogen; and (4) sputtering on the film obtained in step (3) using a tin metal, where a process gas comprises a noble gas, optionally, a mixture of argon and a halogen gas, so as to obtain the perovskite film.

The invention relates to a method for synthesis of films made of light-absorbing material with perovskite-like structure which can be used for fabrication of perovskite solar cells. The method for synthesis of films made of light-absorbing material with perovskite-like structure with a structural formula ACB.sub.3 is characterized by sequential deposition of a layer of a reagent C onto a layer of a reagent AB with a thickness determined by stoichiometry of the reaction followed by the immersion of the layers in a liquid or gaseous medium containing reagent B.sub.2 where component A states for CH.sub.3NH.sub.3.sup.+, (NH.sub.2).sub.2CH.sup.+, C(NH.sub.2).sub.3.sup.+, Cs.sup.+ or a mixture thereof, component B states for Cl.sup., Br.sup., I.sup. or a mixture thereof, component C states for metals Sn, Pb, Bi, or their melts, oxides, salts. The technical result achieved using the claimed invention is a simple and fast method for fabrication of a layer of light-absorbing organic-inorganic material with a perovskite-like structure which is homogeneous due to the formation of a film of the intermediate phase AB-B.sub.2 with improved morphology on the surfaces of a large area due to rapid crystallization, which allows the obtained material to be used in solar cells of large area.

The invention relates to a metallic foam body, comprising (a) a metallic foam body substrate made of at least one metal or metal alloy A; and (b) a layer of a metal or metal alloy B present on at least a part of the surface of the metallic foam body substrate (a), wherein A and B differ in their chemical composition and/or in the grain size of the metal or metal alloy, and wherein the metal or metal alloy A and B is selected from a group consisting of Ni, Cr, Co, Cu, Ag, and any alloy thereof; obtainable by a process comprising the steps (i) provision of a porous organic polymer foam; (ii) deposition of at least one metal or metal alloy A on the porous organic polymer foam; (iii) burning off of the porous organic polymer foam to obtain the metallic foam body substrate (a); and (iv) deposition by electroplating of the metallic layer (b) of a metal or metal alloy B at least on a part of the surface of the metallic foam body (a). The invention moreover relates to a process for the production of the metallic foam body and a use of the metallic foam body.

A thin film formation method according to an embodiment of the present invention includes depositing a lithium metal film on a base material in a vacuum chamber. A surface of the lithium metal film is oxidized in the vacuum chamber. The oxidized surface of the lithium metal film is carbonized in the vacuum chamber.

A method of manufacturing three-dimensional thin-film nitinol (NiTi) devices includes: depositing multiple layers of nitinol and sacrificial material on a substrate. A three-dimensional thin-film nitinol device may include a first layer of nitinol and a second layer of nitinol bonded to the first layer at an area masked and not covered by the sacrificial material during deposition of the second layer.