A catalytically active substance includes a copper (I) sulfide mineral particle, and an alkyne functionalized molecule bound to a surface of the copper (I) sulfide mineral particle. In an example method, a copper (I) sulfide mineral is reacted with an alkyne functionalized molecule to form a catalytically active substance. The catalytically active substance is reacted with an azide functionalized molecule to couple the catalytically active substance with the azide functionalized molecule.

A method for producing a nucleic acid array which includes: a step of forming a resist film using a positive resist composition containing a photo acid generator for generating an acid as a result of being exposed to light on a solid phase which has a molecule immobilized thereon and having functional groups protected by an acid-decomposable protective group; a step of exposing a desired position of the resist film to light; a step of developing the resist film which has been subjected to development using a developing liquid; and a step of bringing the solid phase including the resist film which has been subjected to development into contact with a nucleotide derivative having an acid-decomposable protective group is provided.

A method of making a multicomponent photocatalyst, includes inducing precipitation from a pre-cursor solution comprising a pre-cursor of a plasmonic material and a pre-cursor of a reactive component to form co-precipitated particles; collecting the co-precipitated particles; and annealing the co-precipitated particles to form the multicomponent photocatalyst comprising a reactive component optically, thermally, or electronically coupled to a plasmonic material.

A nanoparticle screening chip and a method using said chip allowing for determining physical properties of nanoparticles, wherein the screening chip comprises a substrate having a working surface divided into a plurality of areas, wherein (1) each of these areas presents different surface properties defined by surface energy component (d,b,a), the total free energy .sub.TOT of the surface of each area being defined as follows: .sub.TOT=.sub.LW+2(.sub.+.sub.).sup.0.5, wherein the components are: .sub.LW=dispersive component=d, .sub.+=electron acceptor component=b, .sub.=electron donor component=a; and (2) each of these areas comprises a plurality of subareas, each subarea comprising an array of sub-micrometric holes or elongated grooves with a different aperture size (S1, S2, S3, . . . ).

An exothermic reaction of hydrogen/deuterium loaded into a metal or alloy is triggered by controlling the frequency of a hydrogen/deuterium plasma in a reaction chamber. The plasma frequency is controlled by adjusting its electron density, which in turn is controlled by adjusting the pressure within the reaction chamber. An exothermic reaction is generated at certain discrete plasma frequencies, which correspond to the optical phonon modes of D-D, H-D, and HH bonds within the metal lattice. For example, in palladium metal, the frequencies are 8.5 THz, 15 THz, and 20 THz, respectively.

A chip and a method for producing the chip with a plurality of measurement regions which are provided with electrodes for electrically detecting reactions in which, in order to reliably separate the individual measurement regions from one another, a monolayer of a fluorosilane is formed on the chip surface which has strongly hydrophobic properties. Therefore, during spotting with a liquid, the drops of liquid applied by spotting can be reliably prevented from coalescing, and thus, causing mixing of the substances in the drops of liquid which are supposed to be immobilized in the measurement regions.

An exothermic reaction assembly includes a reaction chamber and a generator operative to generate an AC electrical signal and apply the signal to the reaction chamber by superimposing the AC signal over a DC signal. A gas manifold and controller is operative to connect a vacuum pump and one or more gas chambers to the reaction chamber and to control a pressure of the reaction chamber. The signal generator is operative to create a plasma in the reaction chamber by superimposing the AC electrical signal to the reaction chamber over the DC signal. The gas manifold and controller are operative to adjust the pressure within the reaction chamber to achieve a predetermined plasma frequency.

An apparatus for optically-verified de novo DNA synthesis includes a microfluidic system that has channels leading in and out of a synthesis chamber having a functionalized region on a floor thereof on which a single-strand of DNA to which a nucleotide is to be attached can be fixed. The chamber is in optical communication with both an illumination system, which excites an electron in a fluorophore that is attached to the DNA strand, a detection system, which detects a signature photon emitted as the excited electron decays into its ground state.

Contemplated microfluidic devices and methods are drawn to protein arrays in which distinct and detergent-containing antigen preparations are deposited onto an optical contrast layer in a non-specific and non-covalent manner. Detection of binding a is carried out using a dye that precipitates or agglomerates to so form a visually detectable signal at a dynamic range of at least three orders of magnitude.

A multicomponent photocatalyst includes a reactive component optically, electronically, or thermally coupled to a plasmonic material. A method of performing a catalytic reaction includes loading a multicomponent photocatalyst including a reactive component optically, electronically, or thermally coupled to a plasmonic material into a reaction chamber, introducing molecular reactants into the reaction chamber, and illuminating the reaction chamber with a light source.