Abstract: A method of depositing metal on an exposed surface of a p-type semiconductor region of a semiconductor device comprising a p-n junction is disclosed, the method comprising: immersing the exposed surface of the p-type semiconductor region on which the metal is to be deposited in a solution of metal ions; producing an electric field in the semiconductor device such that the p-n junction is forward biased; electrochemically depositing the metal on the exposed surface of the p-type semiconductor region of the semiconductor device by reduction of metal ions in the solution.

Abstract: A monolithically integrated system of silicon solar cells. A system having a silicon substrate and a plurality of solar cells formed on the silicon substrate. Each solar cell can have an emitter portion and a base portion. The system can also have a plurality of intermediate regions, each intermediate region having a polarity and electrically separating at least two portions of adjacent solar cells from one another such that the polarity of the intermediate region is opposite to a polarity of at least one of the separated portions of the adjacent solar cells.

Abstract: A solar cell and a method of forming a contact structure on a solar cell having a p-n junction formed between a first semiconductor region of a first dopant polarity and a second semiconductor region of a second dopant polarity opposite to the first dopant polarity. The method comprises: forming a plurality of contact points on a surface of the solar cell, whereby the contact points provide an electrical connection to the first semiconductor region; and locating a plurality of conducting wires over the solar cell to make electrical connection to the contact points. The contact points are either an exposed silicon surface or a silicon surface over which metal pads are formed. The metal pads may comprise a plated layer of a low-melting temperature metal and/or may have a thickness of less than 5 microns.

Abstract: A method of hydrogenation of a silicon photovoltaic junction device is provided, the silicon photovoltaic junction device comprising p-type silicon semiconductor material and n-type silicon semiconductor material forming at least one p-n junction. The method comprises: i) ensuring that any silicon surface phosphorus diffused layers through which hydrogen must diffuse have peak doping concentrations of 1×1020 atoms/cm3 or less and silicon surface boron diffused layers through which hydrogen must diffuse have peak doping concentrations of 1×1019 atoms/cm3 or less; ii) Providing one or more hydrogen sources accessible by each surface of the device; and iii) Heating the device, or a local region of the device to at least 40° C.

Abstract: A surface region of a semiconductor material on a surface of a semiconductor device is doped during its manufacture, by coating the surface region of the semiconductor material with a dielectric material surface layer and locally heating the surface of the semiconductor material in an area to be doped to locally melt the semiconductor material with the melting being performed in the presence of a dopant source. The heating is performed in a controlled manner such that a region of the surface of the semiconductor material in the area to be doped is maintained in a molten state without refreezing for a period of time greater than one microsecond and the dopant from the dopant source is absorbed into the molten semiconductor. The semiconductor device includes a semiconductor material structure in which a junction is formed and may incorporate a multi-layer anti-reflection coating.

Abstract: A method for creating an inwardly extending impurity distribution profile in a substrate comprising crystalline silicon material having a background doping of a first impurity type, comprising: a) providing one or more additional impurity sources with at least two different types of impurity atoms within the substrate or in proximity to the surface of the substrate, with each of these impurity atoms having different diffusion coefficients or segregation coefficients; b) locally melting a point on the surface of the substrate with a laser, whereby the at least two different types of impurity atoms are incorporated into the melted silicon material; c) removing the laser to allow the silicon material to recrystallize; d) controlling a rate of application and/or removal of the laser to control the creation of the impurity distribution profile, with different distribution profiles for each of the at least two types of impurity atoms in the recrystallized material.

Abstract: Disclosed are various embodiments for displaying content. A display area includes multiple information regions presenting content. Visual characteristics associated with the information regions adjust according to values corresponding to the to the information regions. For example, the sizes or positions of the information regions may adjust according to the values.

Abstract: A surface region of a semiconductor material on a surface of a semiconductor device is doped during its manufacture, by coating the surface region of the semiconductor material with a dielectric material surface layer and locally heating the surface of the semiconductor material in an area to be doped to locally melt the semiconductor material with the melting being performed in the presence of a dopant source. The heating is performed in a controlled manner such that a region of the surface of the semiconductor material in the area to be doped is maintained in a molten state without refreezing for a period of time greater than one microsecond and the dopant from the dopant source is absorbed into the molten semiconductor. The semiconductor device includes a semiconductor material structure in which a junction is formed and may incorporate a multi-layer anti-reflection coating.

Abstract: The trailer 10 is a trailer 10 for a folding camper wherein an accommodation space is arranged to be folded out of the trailer 10 at a final destination. The present invention provides a modular hoist 40 which is stored within a hoist storage compartment 50 mounted on the trailer 10. The modular hoist 40 can be mounted to and secured to the trailer 10 and it can then be used to raise and lower the auxiliary equipment to or from upper securement rails 20, 22. In use, a motorbike or other auxiliary equipment is initially secured within a transportation frame 60 on the ground adjacent to the trailer 10. This may comprise locating the wheels of the motorbike in or on a bogey 62 and then securing an upper frame 66 and straps 68 to a lower frame 61. Once secured, attachment means 49 located on the end of a flexible hoist member 48 can be secured to the upper frame 66. Once secured, the modular hoist 40 can then be operated to raise the auxiliary equipment and the transportation frame 60 to the required height.

Abstract: Disclosed are various embodiments for displaying content associated with a merchant selling items through an electronic commerce system. A display area includes multiple information regions presenting content associated with the merchant. Visual characteristics associated with the information regions adjust according to values corresponding to the to the information regions. For example, the sizes or positions of the information regions may adjust according to the values.

Abstract: A method of photoplating a metal contact onto a surface of a cathode of a photovoltaic device is provided using light induced plating technique. The method comprises: a) immersing the photovoltaic device in a solution of metal ions, where the metal ions are a species which is to be plated onto the surface of the cathode of the photovoltaic device; and b) illuminating the photovoltaic device, using a light source of time varying intensity. This results in nett plating which is faster in a direction normal to the surface of the cathode than in a direction in a plane of the surface of the cathode.

Abstract: A method of hydrogenation of a silicon photovoltaic junction device is provided, the silicon photovoltaic junction device comprising p-type silicon semiconductor material and n-type silicon semiconductor material forming at least one p-n junction. The method comprises: i) ensuring that any silicon surface phosphorus diffused layers through which hydrogen must diffuse have peak doping concentrations of 1×1020 atoms/cm3 or less and silicon surface boron diffused layers through which hydrogen must diffuse have peak doping concentrations of 1×1019 atoms/cm3 or less; ii) Providing one or more hydrogen sources accessible by each surface of the device; and iii) Heating the device, or a local region of the device to at least 40° C.

Abstract: A method of hydrogenation of a silicon photovoltaic junction device is provided, the silicon photovoltaic junction device comprising p-type silicon semiconductor material and n-type silicon semiconductor material forming at least one p-n junction. The method comprises: i) ensuring that any silicon surface phosphorus diffused layers through which hydrogen must diffuse have peak doping concentrations of 1×1020 atoms/cm3 or less and silicon surface boron diffused layers through which hydrogen must diffuse have peak doping concentrations of 1×1019 atoms/cm3 or less; ii) Providing one or more hydrogen sources accessible by each surface of the device; and iii) Heating the device, or a local region of the device to at least 40° C.

Abstract: A photovoltaic device is provided in which a contact structure is formed having a plurality of heavily doped semi-conductor channels formed on a surface of a region to be contacted. The heavily doped semiconductor channels are of the same dopant polarity as the region to be contacted, and form lateral conduction paths across the surface of the region to be contacted. Contact metallization comprising conductive fingers are formed over the surface of the region to be contacted, and each conductive finger crosses at least some of the heavily doped channels to make electrical contact therewith. The contact structure is formed by forming a layer of dopant source material over the surface to be contacted, and laser doping heavily doped channels in the surface to be contacted. The contact metallization is then formed as conductive fingers formed over the surface to be contacted and may be screen printed, metal plated or may be formed as buried contacts.

Abstract: A method for creating an inwardly extending impurity distribution profile in a substrate comprising crystalline silicon material having a background doping of a first impurity type, comprising: a) providing one or more additional impurity sources with at least two different types of impurity atoms within the substrate or in proximity to the surface of the substrate, with each of these impurity atoms having different diffusion coefficients or segregation coefficients; b) locally melting a point on the surface of the substrate with a laser, whereby the at least two different types of impurity atoms are incorporated into the melted silicon material; c) removing the laser to allow the silicon material to recrystallise; d) controlling a rate of application and/or removal of the laser to control the creation of the impurity distribution profile, with different distribution profiles for each of the at least two types of impurity atoms in the recrystallised material.

Abstract: A method of depositing metal on an exposed surface of a p-type semiconductor region of a semiconductor device comprising a p-n junction is disclosed, the method comprising: immersing the exposed surface of the p-type semiconductor region on which the metal is to be deposited in a solution of metal ions; producing an electric field in the semiconductor device such that the p-n junction is forward biased; electrochemically depositing the metal on the exposed surface of the p-type semiconductor region of the semiconductor device by reduction of metal ions in the solution.

Abstract: A method of forming an oxide layer on an exposed surface of a semiconductor device which contains a p-n junction is disclosed, the method comprising: immersing the exposed surface of the semiconductor device in an electrolyte; producing an electric field in the semiconductor device such that the p-n junction is forward-biased and the exposed surface is anodic; and electrochemically oxidising the exposed surface to form an oxide layer.

Abstract: A dielectric, structure and a method of forming a dielectric structure for a rear surface of a silicon solar cell are provided. The method comprises forming a first dielectric layer over the rear surface of the silicon solar cell, and then depositing a layer of metal such as aluminum over the first dielectric layer. The metal layer is then anodized to form a porous layer and a material layer is deposited over a surface of the porous layer such that the material deposits on the surface of the porous layer without contacting the silicon surface.

Abstract: A method of forming contacts on a surface emitter of a silicon solar cell is provided. In the method an n-type diffusion of a surface is performed to form a doped emitter surface layer that has a sheet resistance of 10-40 ?/?. The emitter surface layer is then etched back to increase the sheet resistance of the emitter surface layer. Finally the surface is selectively plated. A method of fabrication of a silicon solar cell includes performing a front surface emitter diffusion of n-type dopant and then performing a dielectric deposition on the front surface by PECVD. The dielectric deposition comprises: a. growth of a thin silicon oxide; b. PECVD deposition of silicon nitride to achieve a silicon nitride. The silicon is then annealed to drive hydrogen from the silicon nitride layer into the silicon to passivate the silicon.

Abstract: A system is provided for creating a sound profile that matches sounds produced by a patient during a physical examination, such as a cardiac or pulmonary examination. A user selects multiple sounds from a library and combines them to form the profile which may then be modified by the addition of further sounds, adjustments to their relative timing, duration, loudness, and so forth. The refinement continues iteratively, and after each change the profile is provided by the system to the user, for example, as a phonocardiogram for comparison against the sounds observed during the examination.