Abstract: The embodiments of the disclosure provide a method for determining an exercise parameter if the exercise data is reliable. The exercise data is reliable if the criterion set is met by the exercise data. The method comprises: acquiring exercise data; confirming whether a criterion set is met by a judgement parameter set determined based on the exercise data or not; and using the exercise data to determine an estimation of the exercise parameter if the criterion set is met by the judgement parameter set.

Abstract: The present invention discloses in detail a semiconductor device and a patterning method for the plated electrode thereof. By using the laser ablation method according to the prior art, the semiconductor substrate below the ARC is damaged by direct destructive burning. According to the present invention, an additional protection layer is inserted between the ARC and the semiconductor substrate. Then a laser is used for heating and liquefying the protection layer below the ARC, and thus separating the ARC from the liquefied protection layer underneath and forming pattered openings. Afterwards, by a plating process, nickel and copper can plated.

Abstract: The present invention discloses in detail a semiconductor device and a patterning method for the plated electrode thereof. By using the laser ablation method according to the prior art, the semiconductor substrate below the ARC is damaged by direct destructive burning. According to the present invention, an additional protection layer is inserted between the ARC and the semiconductor substrate. Then a laser is used for heating and liquefying the protection layer below the ARC, and thus separating the ARC from the liquefied protection layer underneath and forming pattered openings. Afterwards, by a plating process, nickel and copper can plated.

Abstract: The present invention relates to a preparation method for patternization of metal electrodes in silicon solar cells. After disposing an amorphous silicon layer on a silicon substrate processed by diffusion, laser light is projected on the amorphous silicon layer for patternization, and transforming the amorphous silicon with low optical conductivity into polysilicon with high optical conductivity thanks to the recrystallization process of the laser light. Then, after immersing the amorphous silicon layer in plating liquid, metal electrode can be formed accurately at the spots of the amorphous silicon layer patterned by laser light. No external voltage is required; plating reaction is induced by illumination directly.

Abstract: A simple and fast light induced nickel plating method for p-type silicon wafer and n/p silicon solar cell material is revealed. When a n/p solar cell or p-Si semiconductor substrate, which is subjected to metallization with metal contact on the rear side, is immersed in a plating bath, metal ions are reduced on the front surface of semiconductor as soon as illumination starts on the front. The mechanism of nickel plating in this invention is nickel electroplating under the reduction reaction with the use of interfacial potential between the nickel plating bath and the metal surface. It does not need any surface catalytic processing and extra voltage. Instead, it can carry out the nickel deposition on the specific surface with a high nickel plating rate, a simple process and a low production cost.

Abstract: Disclosed is a method for making a nickel film for use as an electrode of an n-p diode or solar cell. A light source is used to irradiate an n-type surface of the n-p diode or solar cell, thus producing electron-hole pairs in the n-p diode or solar cell. For the electric field effect at an n-p interface, electrons drift to and therefore accumulate on the n-type surface. With a plating agent, the diode voltage is added to the chemical potential for electroless plating of nickel on the n-type surface. The nickel film can be used as a buffer layer between a contact electrode and the diode or solar cell. The nickel film reduces the contact resistance to prevent a reduced efficiency of the diode or solar cell that would otherwise be caused by diffusion of the atoms of the electrode in following electroplating.

Abstract: There is disclosed a method for making solar cells with sensitized quantum dots in the form of nanometer metal crystals. Firstly, a first substrate is provided. Then, a silicon-based film is grown on a side of the first substrate. A pattern mask process is executed to etch areas of the silicon-based film. Nanometer metal particles are provided on areas of the first substrate exposed from the silicon-based film. A metal electrode is attached to an opposite side of the first substrate. A second substrate is provided. A transparent conductive film is grown on the second substrate. A metal catalytic film is grown on the transparent conductive film. The second substrate, the transparent conductive film and the metal catalytic film together form a laminate. The laminate is inverted and provided on the first substrate. Finally, electrolyte is provided between the first substrate and the metal catalytic film.

Abstract: There is disclosed a method for making solar cells with sensitized quantum dots in the form of nanometer metal crystals. Firstly, a first substrate is provided. Then, a silicon-based film is grown on a side of the first substrate. A pattern mask process is executed to etch areas of the silicon-based film. Nanometer metal particles are provided on areas of the first substrate exposed from the silicon-based film. A metal electrode is attached to an opposite side of the first substrate. A second substrate is provided. A transparent conductive film is grown on the second substrate. A metal catalytic film is grown on the transparent conductive film. The second substrate, the transparent conductive film and the metal catalytic film together form a laminate. The laminate is inverted and provided on the first substrate. Finally, electrolyte is provided between the first substrate and the metal catalytic film.

Abstract: There is disclosed a method for coating nanometer metal particles. The step includes three steps. At the first step, a substrate is provided. At the second step, the substrate is coated with a metal layer. At the third step, the metal layer is annealed so that the metal layer is transformed into nanometer metal particles.