Abstract: The present invention relates to a method for laser cladding and forming of a metal or alloy under partial atmosphere protection. Including: transporting a metal or alloy powder beam by an inert carrier gas to move on a machined surface with a focused laser beam; and forming at least one layer of inert protective gas at the outer periphery of the metal or alloy powder beam. The inert protective gas includes first inert protective gas, and the first inert protective gas is at the outer periphery of the focused laser beam. The problems of limited size, high cost and difficulty in moving a cladding and forming system and the like during part forming are solved by forming the inert protective gas at the outer periphery of the focused laser beam. Compared with the prior art, the convenient, fast and economical method is provided for on-site part forming and repair.

Abstract: Preparing a low dielectric constant thin film layer used in an integrated circuit includes: extracting gas out of a furnace; when the vacuum level within the furnace is less than 10?3 Pa, starting a 13.36 MHz radio frequency power supply and a matcher; sending the exhaust nitrogen gas, used to remove remaining gas out of the furnace by a third gas inlet pipe, into the furnace through a second pressure gas mixing tank and a second nozzle sequentially; uniformly mixing octamethyl cyclotetrasiloxane and cyclohexane, and introducing same into a pressure stainless steel tank, and, respectively by first and second gas inlet tubes, introducing bubbled nitrogen gas and inert gas into the furnace sequentially through a first pressure gas mixing tank, the pressure stainless steel tank and a first nozzle; after deposition, transferring the deposited thin film layer to the furnace's heating zone for annealing, obtaining a low dielectric constant thin film layer.

Abstract: An organic compound has the following chemical structure: wherein R is different from R*; R and R* are independently hydrogen, halogen, nitro or methoxyl; and R1 is a C1-C6 alkyl or a phenyl group. A quaternary data storage device includes a bottom electrode, a top electrode, and the organic film layer sandwiched between the bottom electrode and the top electrode.

Abstract: A method for optimizing an optical network includes: obtaining a lightpath demand set including multiple lightpath demands; generating multiple lightpath demand sequences with different orders from the lightpath demand set; obtaining results of the respective lightpath demand sequences in parallel by multiple processing terminals; obtaining all the results, and comparing the results to obtain an optimum result. In this embodiment, by generating multiple lightpath demand sequences with different orders for the lightpath demand set and obtaining many results, the optimum result can be selected out from the results. Furthermore, multiple processing terminals may obtain the result in parallel, thus improving an operation efficiency.