Abstract: A method for manufacturing a semiconductor structure comprises the steps of: providing a substrate including a first semiconductor material; forming a dielectric layer on a surface of the substrate; forming an opening in the dielectric layer having a bottom reaching the substrate; providing a second semiconductor material in the opening and on the substrate, the second semiconductor material being en-capsulated by a further dielectric material thereby forming a filled cavity; melting the second semiconductor material in the cavity; recrystallizing the second semi-conductor material in the cavity; laterally removing the second semiconductor material at least partially for forming a lateral surface at the second semiconductor material; and forming a third semiconductor material on the lateral surface of the second semiconductor material, wherein the third semiconductor material is different from the second semiconductor material.

Abstract: A volume and speech frequency level adjustment method, system, and computer program product include learning a characteristic of at least one of audio volume and speech frequency from a conversation, detecting a contextual characteristic of an ongoing conversation and an interaction of a user with a device, determining a cognitive state of the user in relation to the ongoing conversation as a function of at least one of the contextual characteristic of the volume or the speech frequency, and a user interaction pattern with a conversation device, and dynamically adjusting audio levels of the ongoing conversation for the user based on the function.

Abstract: Methods are provided for fabricating semiconductor nanowires on a substrate. A nanowire template is formed on the substrate. The nanowire template defines an elongate tunnel which extends, laterally over the substrate, between an opening in the template and a seed surface. The seed surface is exposed to the tunnel and of an area up to about 2×104 nm2. The semiconductor nanowire is selectively grown, via said opening, in the template from the seed surface. The area of the seed surface is preferably such that growth of the nanowire proceeds from a single nucleation point on the seed surface. There is also provided a method for fabricating a plurality of semiconductor nanowires on a substrate and a semiconductor nanowire and substrate structure.

Abstract: A volume and speech frequency level adjustment method, system, and computer program product include learning a preferred level and a characteristic of at least one of volume and speech frequency from a historical conference conversation, detecting a context characteristic of an ongoing conversation and an interaction of a user with a device, determining a cognitive state and a contextual situation of the user in relation to the ongoing conversation as a function of at least one of the context characteristic, a preferred level and a characteristic of the volume or the speech frequency, and the interaction, determining at least one factor to trigger an audio level modulation based on the function, and dynamically adjusting audio levels of the ongoing conversation for the user based on the at least one factor.

Abstract: A device comprising a control unit and a plurality of resistive cells. The plurality of resistive cells each comprises a first terminal, a second terminal and a polymorphic layer comprising a polymorphic material. The polymorphic layer is configured to form a tunnel barrier. The polymorphic layer is arranged between the first terminal and the second terminal. The first terminal, the second terminal and the polymorphic layer form a tunnel junction.

Abstract: A device comprising a control unit and a plurality of resistive cells. The plurality of resistive cells each comprises a first terminal, a second terminal and a polymorphic layer comprising a polymorphic material. The polymorphic layer is configured to form a tunnel barrier. The polymorphic layer is arranged between the first terminal and the second terminal. The first terminal, the second terminal and the polymorphic layer form a tunnel junction.

Abstract: A method of fabrication of an array of optoelectronic structures includes first providing a crystalline substrate having cells corresponding to individual optoelectronic structures to be obtained. Each of the cells includes an opening to the substrate. Then, several first layer portions of a first compound semiconductor material are grown in each the opening to at least partly fill a respective one of the cells and form an essentially planar film portion therein. Next, several second layer portions of a second compound semiconductor material are grown over the first layer portions that coalesce to form a coalescent film extending over the first layer portions. Finally, excess portions of materials are removed, to obtain the array of optoelectronic structures. Each optoelectronic structure comprises a stack protruding from the substrate of: a residual portion of one of the second layer portions; and a residual portion of one of the first layer portions.

Abstract: A method comprises providing a cavity structure on the substrate comprising a first growth channel extending in a first direction, a second growth channel extending in a second direction, wherein the second direction is different from the first direction and the second channel is connected to the first channel at a channel junction, a first seed surface in the first channel, at least one opening for supplying precursor materials to the cavity structure, selectively growing from the first seed surface a first semiconductor structure substantially only in the first direction and in the first channel, thereby forming a second seed surface for a second semiconductor structure at the channel junction, growing in the second channel the second semiconductor structure in the second direction from the second seed surface, thereby forming the semiconductor junction comprising the first and the second semiconductor structure.

Abstract: Methods are provided for fabricating semiconductor nanowires on a substrate. A nanowire template is formed on the substrate. The nanowire template defines an elongate tunnel which extends, laterally over the substrate, between an opening in the template and a seed surface. The seed surface is exposed to the tunnel and of an area up to about 2×104 nm2. The semiconductor nanowire is selectively grown, via said opening, in the template from the seed surface. The area of the seed surface is preferably such that growth of the nanowire proceeds from a single nucleation point on the seed surface. There is also provided a method for fabricating a plurality of semiconductor nanowires on a substrate and a semiconductor nanowire and substrate structure.

Abstract: A method for producing a mono-crystalline sheet includes providing at least two aperture elements forming a gap in between; providing a molten alloy including silicon in the gap; providing a gaseous precursor medium comprising silicon in the vicinity of the molten alloy; providing a silicon nucleation crystal in the vicinity of the molten alloy; and bringing in contact said silicon nucleation crystal and the molten alloy. A device for producing a mono-crystalline sheet includes at least two aperture elements at a predetermined distance from each other, thereby forming a gap, and being adapted to be heated for holding a molten alloy including silicon by surface tension in the gap between the aperture elements; a precursor gas supply supplies a gaseous precursor medium comprising silicon in the vicinity of the molten alloy; and a positioning device for holding and moving a nucleation crystal in the vicinity of the molten alloy.

Abstract: A method of fabrication of an array of optoelectronic structures includes first providing a crystalline substrate having cells corresponding to individual optoelectronic structures to be obtained. Each of the cells includes an opening to the substrate. Then, several first layer portions of a first compound semiconductor material are grown in each the opening to at least partly fill a respective one of the cells and form an essentially planar film portion therein. Next, several second layer portions of a second compound semiconductor material are grown over the first layer portions that coalesce to form a coalescent film extending over the first layer portions. Finally, excess portions of materials are removed, to obtain the array of optoelectronic structures. Each optoelectronic structure comprises a stack protruding from the substrate of: a residual portion of one of the second layer portions; and a residual portion of one of the first layer portions.

Abstract: A thermoelectric device for transferring heat from a heat source to a heat sink includes at least one thermoelectric leg pair having a first leg including an n-type semiconductor material and a second leg including a p-type semiconductor material. The first leg and the second leg are electrically coupled in series. A resistive element electrically couples the first leg and the second leg between the heat source and the heat sink.

Abstract: A method of fabrication of an array of optoelectronic structures. The method first provides a crystalline substrate having cells corresponding to individual optoelectronic structures to be obtained. Each of the cells comprises an opening to the substrate. Then, several first layer portions of a first compound semiconductor material are grown in each the opening to at least partly fill a respective one of the cells and form an essentially planar film portion therein. Next, several second layer portions of a second compound semiconductor material are grown over the first layer portionsthat coalesce to form a coalescent film extending over the first layer portions. Finally, excess portions of materials are removed, to obtain the array of optoelectronic structures. Each optoelectronic structure comprises a stack protruding from the substrate of: a residual portion of one of the second layer portions; and a residual portion of one of the first layer portions.

Abstract: A method of fabrication of an array of optoelectronic structures. The method first provides a crystalline substrate having cells corresponding to individual optoelectronic structures to be obtained. Each of the cells comprises an opening to the substrate. Then, several first layer portions of a first compound semiconductor material are grown in each the opening to at least partly fill a respective one of the cells and form an essentially planar film portion therein. Next, several second layer portions of a second compound semiconductor material are grown over the first layer portions that coalesce to form a coalescent film extending over the first layer portions. Finally, excess portions of materials are removed, to obtain the array of optoelectronic structures. Each optoelectronic structure comprises a stack protruding from the substrate of: a residual portion of one of the second layer portions; and a residual portion of one of the first layer portions.

Abstract: A method for manufacturing a semiconductor structure comprises the steps of: providing a substrate including a first semiconductor material; forming a dielectric layer on a surface of the substrate; forming an opening in the dielectric layer having a bottom reaching the substrate; providing a second semiconductor material in the opening and on the substrate, the second semiconductor material being en-capsulated by a further dielectric material thereby forming a filled cavity; melting the second semiconductor material in the cavity; recrystallizing the second semi-conductor material in the cavity; laterally removing the second semiconductor material at least partially for forming a lateral surface at the second semiconductor material; and forming a third semiconductor material on the lateral surface of the second semiconductor material, wherein the third semiconductor material is different from the second semiconductor material.

Abstract: A semiconductor device for use in an optical application and a method for fabricating the device. The device includes: an optically passive aspect that is operable in a substantially optically passive mode; and an optically active material having a material that is operable in a substantially optically active mode, wherein the optically passive aspect is patterned to include a photonic structure with a predefined structure, and the optically active material is formed in the predefined structure so as to be substantially self-aligned in a lateral plane with the optically passive aspect.

Abstract: A method for manufacturing a semiconductor structure comprises the steps of: providing a substrate including a first semiconductor material; forming a dielectric layer on a surface of the substrate; forming an opening in the dielectric layer having a bottom reaching the substrate; providing a second semiconductor material in the opening and on the substrate, the second semiconductor material being en-capsulated by a further dielectric material thereby forming a filled cavity; melting the second semiconductor material in the cavity; recrystallizing the second semi-conductor material in the cavity; laterally removing the second semiconductor material at least partially for forming a lateral surface at the second semiconductor material; and forming a third semiconductor material on the lateral surface of the second semiconductor material, wherein the third semiconductor material is different from the second semiconductor material.

Abstract: An optical spectrometer contains a photodiode and a straining mechanism for imposing adjustable strain on the photodiode. The spectrometer includes a measurement apparatus for measuring variation of photocurrent with strain at different values of the adjustable strain imposed by the straining mechanism. Adjusting the strain allows adjustment of the band gap Eg of the photosensitive region of the photodiode, and this determines the cut-off energy for absorption of photons. Measuring variation of photocurrent with strain at different values of the adjustable strain imposed by the straining mechanism allows study of photons within a desired energy range of the band gap energy corresponding to each strain value.

Abstract: A method comprises providing a cavity structure on the substrate comprising a first growth channel extending in a first direction, a second growth channel extending in a second direction, wherein the second direction is different from the first direction and the second channel is connected to the first channel at a channel junction, a first seed surface in the first channel, at least one opening for supplying precursor materials to the cavity structure, selectively growing from the first seed surface a first semiconductor structure substantially only in the first direction and in the first channel, thereby forming a second seed surface for a second semiconductor structure at the channel junction, growing in the second channel the second semiconductor structure in the second direction from the second seed surface, thereby forming the semiconductor junction comprising the first and the second semiconductor structure.

Abstract: A device for storing electrical energy comprises a photo electrode, having a semiconductor layer with a photo dye thereon, a counter electrode, a reservoir comprising a solvent, a first redox mediator for enabling a redox reaction at the photo electrode, a second redox mediator for enabling a redox reaction at the counter electrode, wherein the photo electrode and the counter electrode are at least partly in the solvent, the first redox mediator is adapted to form an entity that is soluble in the solvent when the first redox mediator is in its reduced state, and an entity that is insoluble in the solvent when the first redox mediator is in its oxidized state.