Abstract: A hybrid photovoltaic device (1) comprising a thin film solar cell (2) disposed in a first layer (21) comprising an array of vertically aligned nanowires (25), said nanowires having a junction with a first band gap corresponding to a first spectral range. The nanowires (25) form absorbing regions, and non-absorbing regions are formed between the nanowires. A bulk solar cell (3) s disposed in a second layer (31), positioned below the first layer (21), having a junction with a second band gap, which is smaller than said first band gap and corresponding to a second spectral range. The nanowires are provided in the first layer with a lateral density selected a such that a predetermined portion of an incident photonic wave-front will pass through the non-absorbing regions without absorption in the first spectral range, into the bulk solar cell for absorption in both the first spectral range and the second spectral range.

Abstract: A gas phase nanowire growth apparatus including a reaction chamber (200), a first input and a second input (202 B, 202 A). The first input is located concentrically within the second input and the first and second input are configured such that a second fluid delivered from the second input provides a sheath between a first fluid delivered from the first input and a wall of the reaction chamber.

Abstract: The solar cell structure according to the present invention comprises a nanowire (205) that constitutes the light absorbing part of the solar cell structure and a passivating shell (209) that encloses at least a portion of the nanowire (205). In a first aspect of the invention, the passivating shell (209) of comprises a light guiding shell (210), which preferably has a high- and indirect bandgap to provide light guiding properties. In a second aspect of the invention, the solar cell structure comprises a plurality of nanowires which are positioned with a maximum spacing between adjacent nanowires which is shorter than the wavelength of the light which the solar cell structure is intended to absorbing order to provide an effective medium for light absorption. Thanks to the invention it is possible to provide high efficiency solar cell structures.

Abstract: The present invention provides a method and a system for forming wires (1) that enables a large scale process combined with a high structural complexity and material quality comparable to wires formed using substrate-based synthesis. The wires (1) are grown from catalytic seed particles (2) suspended in a gas within a reactor. Due to a modular approach wires (1) of different configuration can be formed in a continuous process. In-situ analysis to monitor and/or to sort particles and/or wires formed enables efficient process control.

Abstract: A gas phase nanowire growth apparatus including a reaction chamber (200), a first input and a second input (202 B, 202 A). The first input is located concentrically within the second input and the first and second input are configured such that a second fluid delivered from the second input provides a sheath between a first fluid delivered from the first input and a wall of the reaction chamber. An aerosol of catalyst particles may be used to grow the nanowires.

Abstract: The present invention provides a method and a system for forming wires (1) that enables a large scale process combined with a high structural complexity and material quality comparable to wires formed using substrate-based synthesis. The wires (1) are grown from catalytic seed particles (2) suspended in a gas within a reactor. Due to a modular approach wires (1) of different configuration can be formed in a continuous process. In-situ analysis to monitor and/or to sort particles and/or wires formed enables efficient process control.

Abstract: The present invention provides a method for aligning nanowires which can be used to fabricate devices comprising nanowires that has well-defined and controlled orientation independently on what substrate they are arranged on. The method comprises the steps of providing nanowires and applying an electrical field over the population of nanowires, whereby an electrical dipole moment of the nanowires makes them align along the electrical field. Preferably the nanowires are dispersed in a fluid during the steps of providing and aligning. When aligned, the nanowires can be fixated, preferably be deposition on a substrate. The 10 electrical field can be utilised in the deposition. Pn-junctions or any net charge introduced in the nanowires may assist in the aligning and deposition process. The method is suitable for continuous processing, e.g. in a roll-to-roll process, on practically any substrate materials and not limited to substrates suitable for particle assisted growth.

Abstract: The present invention relates to light emitting diodes comprising at least one nanowire. The LED according to the invention is an upstanding nanostructure with the nanowire protruding from a substrate. A bulb with a larger diameter than the nanowire is arranged in connection to the nanowire and at an elevated position with regards to the substrate. A pn-junction is formed by the combination of the bulb and the nanowire resulting in an active region to produce light.

Abstract: The present invention provides a method for aligning nanowires which can be used to fabricate devices comprising nanowires that has well-defined and controlled orientation independently on what substrate they are arranged on. The method comprises the steps of providing nanowires (1) and applying an electrical field (E) over the population of nanowires (1), whereby an electrical dipole moment of the nanowires makes them align along the electrical field (E). Preferably the nanowires are dispersed in a fluid during the steps of providing and aligning. When aligned, the nanowires can be fixated, preferably be deposition on a substrate (2). The electrical field can be utilized in the deposition. Pn-junctions or any net charge introduced in the nanowires (1) may assist in the aligning and deposition process. The method is suitable for continuous processing, e.g. in a roll-to-roll process, on practically any substrate materials and not limited to substrates suitable for particle assisted growth.

Abstract: The present invention relates to providing layers of different thickness on vertical and horizontal surfaces (15, 20) of a vertical semiconductor device (1). In particular the invention relates to gate electrodes and the formation of precision layers (28) in semiconductor structures comprising a substrate (10) and an elongated structure (5) essentially standing up from the substrate. According to the method of the invention the vertical geometry of the device (1) is utilized in combination with either anisotropic deposition or anisotropic removal of deposited material to form vertical or horizontal layers of very high precision.

Abstract: A radial nanowire Esaki diode device includes a semiconductor core of a first conductivity type and a semiconductor shell of a second conductivity type different from the first conductivity type. The device may be a TFET or a solar cell.

Abstract: A gas phase nanowire growth apparatus including a reaction chamber (200), a first input and a second input (202 B, 202 A). The first input is located concentrically within the second input and the first and second input are configured such that a second fluid delivered from the second input provides a sheath between a first fluid delivered from the first input and a wall of the reaction chamber.

Abstract: The invention regards a method of manufacturing a structure adapted to be transferred to a non-crystalline layer. The method comprises the steps of providing a substrate having a crystal orientation, providing a plurality of elongate nanostructures (nanowires) on said substrate, said nanostructures extending from the substrate such that the angle defined by the axis of elongation of each nanostructure and the surface normal of the substrate is smaller than 55 degrees, depositing at least one layer of material such that at least the exposed regions of the substrate are covered by said material, removing the substrate such that the deposited layer becomes lowermost layer and exposing at least the extremity of the respective nanostructure of the plurality of nanostructures. Invention also regards a structure manufactured using said method.

Abstract: The present invention relates to growth of III-V semiconductor nanowires (2) on a Si substrate (3). Controlled vertical nanowire growth is achieved by a step, to be taken prior to the growing of the nanowire, of providing group III or group V atoms to a (111) surface of the Si substrate to provide a group III or group V 5 surface termination (4). A nanostructured device including a plurality of aligned III-V semiconductor nanowires (2) grown on, and protruding from, a (111) surface of a Si substrate (3) in an ordered pattern in compliance with a predetermined device layout is also presented.

Abstract: A method for forming wires, including providing catalytic seed particles suspended in a gas, providing gaseous precursors that comprise constituents of the wires to be formed and growing the wires from the catalytic seed particles. The wires may be grown in a temperature range between 425 and 525 C and may have a pure zincblende structure. The wires may be III-V semiconductor nanowires having a Group V terminated surface and a <111>B crystal growth direction.

Abstract: The present invention relates to providing layers of different thickness on vertical and horizontal surfaces (15, 20) of a vertical semiconductor device (1). In particular the invention relates to gate electrodes and the formation of precision layers (28) in semiconductor structures comprising a substrate (10) and an elongated structure (5) essentially standing up from the substrate. According to the method of the invention the vertical geometry of the device (1) is utilized in combination with either anisotropic deposition or anisotropic removal of deposited material to form vertical or horizontal layers of very high precision.

Abstract: The present invention provides a photodiode comprising a p-i-n or pn junction at least partly formed by first and second regions (2) made of semiconductor materials having opposite conductivity type, wherein the p-i-n or pn junction comprises a light absorption region (11) for generation of charge carriers from absorbed light. One section of the p-i-n or pn junction is comprises by one or more nanowires (7) that are spaced apart and arranged to collect charge carriers generated in the light absorption region (11). At least one low doped region (10) made of a low doped or intrinsic semiconductor material provided between the nanowires (7) and one of said first region (1) and said second region (2) enables custom made light absorption region and/or avalanche multiplication region of the active region (9).

Abstract: The present invention relates to epitaxial growth of nanowires on a substrate. In particular the invention relates to growth of nanowires on an Si-substrate without using Au as a catalyst. In the method according to the invention an oxide template is provided on a passivated surface of the substrate. The oxide template defines a plurality of nucleation onset positions for subsequent nanowire growth. According to one embodiment a thin organic film is used to form the oxide template.

Abstract: The present invention relates to an apparatus and a method for measuring the dimensions of 1-dimensional and 0-dimensional nanostructures on semiconductor substrates in real-time during epitaxial growth. The method includes either assigning a pre-calculated 3D-model from a data base to the sample or calculating a 3D-model of the sample using the measured optical reflectances of the plurality of different measuring positions of the sample, where calculation or pre-calculation of the 3D-model includes calculation of the interference effects of light reflected from the front and back interfaces of the nano-structure and calculation of the interference effects due to superposition of neighbouring wave-fronts reflected from the nano-structure area and wave-fronts reflected from the substrate area between the nano-structures.

Abstract: The invention relates to a nanowire device for manipulation of charged molecules, comprising a tubular nanowire with a through-going channel; a plurality of individually addressable wrap gate electrodes arranged around said tubular nanowire with a spacing between each two adjacent wrap gate electrodes and means for connecting the wrap gate electrodes to a voltage source. The invention further relates to a nanowire system comprising at least one nanowire device, and to a method for manipulating of charged molecules within a through-going channel of a tubular nanowire.