Abstract: An ohmic contact of semiconductor and its manufacturing method are disclosed. The present invention provides a low resistivity ohmic contact so as to improve the performance and reliability of the semiconductor device. This ohmic contact is formed by first coating a transition metal and a noble metal on a semiconductor material; then heat-treating the transition metal and the noble metal in an oxidizing environment to oxidize the transition metal. In other words, this ohmic contact primarily includes a transition metal oxide and a noble metal. The oxide in the film can be a single oxide, or a mixture of various oxides, or a solid solution of various oxides. The metal of the film can be a single metal, or various metals or an alloy thereof. The structure of the film can be a mixture or a laminate or multilayered including oxide and metal. The layer structure includes at least one oxide layer and one metal layer, in which at least one oxide layer is contacting to semiconductor.

Abstract: An ohmic contact of semiconductor and its manufacturing method are disclosed. The present invention provides a low resistivity ohmic contact so as to improve the performance and reliability of the semiconductor device. This ohmic contact is formed by first coating a transition metal and a noble metal on a semiconductor material; then heat-treating the transition metal and the noble metal in an oxidizing environment to oxidize the transition metal. In other words, this ohmic contact primarily includes a transition metal oxide and a noble metal. The oxide in the film can be a single oxide, or a mixture of various oxides, or a solid solution of various oxides. The metal of the film can be a single metal, or various metals or an alloy thereof. The structure of the film can be a mixture or a laminate or multilayered including oxide and metal. The layer structure includes at least one oxide layer and one metal layer, in which at least one oxide layer is contacting to semiconductor.

Abstract: A semiconductor laser structure is provided, which has an increased catastrophic optical damage (COD) level that allows the laser diode to have an increased life time of use. This semiconductor laser structure is characterized in the forming of a current-blocking structure proximate to the facets of the laser diode, which can help reduce the injected current into the facets, thereby increasing the COD level of the resulted laser diode. As a result, the resulted laser diode can operate at a high output power and nonetheless have an increased life time of use. Moreover, the forming of the current-blocking layers proximate to the facets can be performed simply by incorporating an additional photomask step in the fabrication without having equipment such as epitaxial equipment or vacuum equipment in the case of the prior art.

Abstract: This specification discloses a gallium nitride-based III-V Group compound semiconductor device. Its p-type electrode consists of a semiconductor oxide film and a transparent conductive film. With the good ohmic contact between the former film and the p-type semiconductor layer, the latter one can homogeneously distribute the current to the surface of the whole p-type semiconductor layer. Since both the semiconductor oxide film and the transparent conductive film can be easily penetrated by light, the p-type electrode is a transparent structure with a transparency over 75% within the visible light range. Therefore, this invention can greatly increase the efficiency of the light-emitting devices. Moreover, the manufacturing procedure of this invention being simple and reliable, the yield and device reliability can thus be greatly raised. The production cost is lowered with simplified manufacturing steps at the same time.

Abstract: An ohmic contact of semiconductor and its manufacturing method are disclosed. The present invention provides a low resistivity ohmic contact so as to improve the performance and reliability of the semiconductor device. This ohmic contact is formed by first coating a transition metal and a noble metal on a semiconductor material; then heat-treating the transition metal and the noble metal in an oxidizing environment to oxidize the transition metal. In other words, this ohmic contact primarily includes a transition metal oxide and a noble metal. The oxide in the film can be a single oxide, or a mixture of various oxides, or a solid solution of various oxides. The metal of the film can be a single metal, or various metals or an alloy thereof. The structure of the film can be a mixture or a laminate or multilayered including oxide and metal. The layer structure includes at least one oxide layer and one metal layer, in which at least one oxide layer is contacting to semiconductor.

Abstract: A method of forming oxide from nitride, in which the oxidation is enhanced by illuminating the nitride material with UV light. This method produces a rapid growth of oxide and allows for the monitoring of the oxide thickness in situ. The method comprises the steps of (i) placing the nitride material on an illuminating holder; (ii) dipping the nitride material and the illuminating holder in an electrolyte; and (iii) illuminating the nitride material with a light having an energy larger than the energy gap of the nitride material. The nitride material can be connected to a conductive electrode located in the electrolyte via a galvanometer to monitor a photo current generated by the oxidation of the nitride material so as to monitor the thickness of the oxide formed on the nitride material in situ. A metal coating can be coated on the nitride material to define the oxide forming region. The pH value of the electrolyte is in a range of approximately 3 to 10, and is preferably about 3.5.

Abstract: A method of fabricating a ridge waveguide semiconductor light-emitting device is provided in which an oxide semiconductor having a heavy carrier concentration serves as the interface of the metal layer and the epitaxial layer to make the current flow through the ridge waveguide. This invention forms an oxide semiconductor having a heavy carrier concentration thereon after finishing the basic structure of a ridge waveguide semiconductor light-emitting device, then forms a metal layer to conduct current. Since the carrier concentration at the surface of the ridge waveguide is higher than that at the inner portion, the current primarily flows through the interface of the oxide semiconductor having a heavy carrier concentration and the vertex of the ridge waveguide. Thus the current is restricted to only flow through the vertex of the ridge waveguide.

Abstract: A method for etching nitride is provided, by which the etching rate and the roughness of the etching surface can be powerfully controlled, and by which the etching depth can be in-situ monitored. The etching method comprises the steps of: (i) coating a first electrode on a nitride chip; (ii) mounting the nitride chip on a holding device; (iii)dipping the holding device, the nitride chip and the first electrode in electrolysis liquid; (iv) irradiating the nitride chip with a UV light having a wavelength shorter than 254 nm; and (v) connecting the first electrode to a second electrode dipped in the electrolysis liquid by a galvanometer to in-situ monitor the etching current, so as to in-situ control the etching depth.