Abstract: A process for fabricating an optoelectronic device including an array of germanium-based photodiodes including the following steps: producing a stack of semiconductor layers, made from germanium; producing trenches; depositing a passivation intrinsic semiconductor layer, made from silicon; annealing, ensuring, for each photodiode, an interdiffusion of the silicon of the passivation semiconductor layer and of the germanium of a semiconductor portion, thus forming a peripheral zone of the semiconductor portion, made from silicon-germanium.

Abstract: The invention pertains to a process for producing a strained layer based on germanium-tin (GeSn). The process includes a step of producing a semiconductor stack containing a layer based on GeSn and having an initial strain value that is non-zero; a step of structuring the semiconductor stack so as to form a structured portion and a peripheral portion, the structured portion including a central section linked to the peripheral portion by at least two lateral sections having an average width greater than an average width of the central section; and a step of suspending the structured portion, the central section then having a final strain value higher than the initial value.

Abstract: First, second and third series of samples are successively made so as to determine the influence of the deposition parameters on the crystallographic quality of a layer of semiconductor material of III-V type. The parameters studied are successively the deposition pressure, the deposition temperature and the deposited thickness of a sub-layer of semiconductor material of III-V type so as to respectively determine a first deposition pressure, a first deposition temperature at the first deposition pressure, and a first deposited thickness at the first deposition temperature and at the first deposition pressure. The sub-layer of semiconductor material of III-V type is thickened by ways of a second layer of semiconductor material of III-V type deposited under different conditions.

Abstract: A method for producing a waveguide including a germanium-based core and a cladding is provided, the method including a step of “low temperature” depositing of a shell after forming the core by engraving, such that the deposition temperature is less than 780° C., followed by a step of “high temperature” depositing of a thick encapsulation layer. The shell and the encapsulation layer at least partially form the cladding of the waveguide. Optionally, a step of annealing under hydrogen at a “low temperature”, less than 750° C., precedes the deposition of the shell. These “low temperature” annealing and depositing steps advantageously make it possible to avoid a post-engraving alteration of the free surfaces of the core during the forming of the cladding which is less germanium-rich.

Abstract: A semiconductor device is disclosed that has a semiconductor substrate having a crystal structure with a <1,0,0> plane and a <1,1,0> plane and a surface that forms an angle of about 0.3 degrees to about 0.7 degrees with the <1,0,0> plane in the direction of the <1,1,0> plane; and a compound semiconductor layer formed on the semiconductor substrate. The compound semiconductor layer is free of antiphase boundaries, and has a thickness between about 200 nm and about 1,000 nm.

Abstract: A semiconductor device is disclosed that has a semiconductor substrate having a crystal structure with a <1,0,0> plane and a <1,1,0> plane and a surface that forms an angle of about 0.3 degrees to about 0.7 degrees with the <1,0,0> plane in the direction of the <1,1,0> plane; and a compound semiconductor layer formed on the semiconductor substrate. The compound semiconductor layer is free of antiphase boundaries, and has a thickness between about 200 nm and about 1,000 nm.

Abstract: The present disclosure concerns a method involving: forming a strained silicon germanium layer by epitaxial growth over a silicon layer disposed on a substrate; implanting atoms to amorphize the silicon layer and a lower portion of the silicon germanium layer, without amorphizing a surface portion of the silicon germanium layer; and annealing, to at least partially relax the silicon germanium layer and to re-crystallize the lower portion of the silicon germanium layer and the silicon layer, so that the silicon layer becomes a strained silicon layer.

Abstract: Method for fabricating a transistor comprising the steps consisting of: forming sacrificial zones in a semi-conductor layer, either side of a transistor channel zone, forming insulating spacers on said sacrificial zones against the sides of the gate of said transistor, removing said sacrificial zones so as to form cavities, with the cavities extending on either side of said channel zone and penetrating under said spacers, forming doped semi-conductor material in said cavities, with said semi-conductor material penetrating under said spacers.

Abstract: First, second and third series of samples are successively made so as to determine the influence of the deposition parameters on the crystallographic quality of a layer of semiconductor material of III-V type. The parameters studied are successively the deposition pressure, the deposition temperature and the deposited thickness of a sub-layer of semiconductor material of III-V type so as to respectively determine a first deposition pressure, a first deposition temperature at the first deposition pressure, and a first deposited thickness at the first deposition temperature and at the first deposition pressure. The sub-layer of semiconductor material of III-V type is thickened by ways of a second layer of semiconductor material of III-V type deposited under different conditions.

Abstract: Fabrication of a photodetector is performed on a substrate comprising a first portion successively provided with a first semiconductor film, an electrically insulating layer, a second semiconductor film, and a protection layer. The substrate also comprises a second portion not comprising the second semiconductor film. It further comprises a third portion not comprising the second semiconductor film and the protection layer. The second semiconductor film is etched in the first portion to form a cavity. A PIN/NIP diode is formed in the third portion at least by means of deposition of a third semiconductor material which also comes and fills the cavity. A conversion layer is deposited to absorb a light signal originating from the second semiconductor film and to convert the light signal into an electric signal, the conversion layer electrically connecting the PIN/NIP diode.

Abstract: Fabrication of a photodetector is performed on a substrate comprising a first portion successively provided with a first semiconductor film, an electrically insulating layer, a second semiconductor film, and a protection layer. The substrate also comprises a second portion not comprising the second semiconductor film. It further comprises a third portion not comprising the second semiconductor film and the protection layer. The second semiconductor film is etched in the first portion to form a cavity. A PIN/NIP diode is formed in the third portion at least by means of deposition of a third semiconductor material which also comes and fills the cavity. A conversion layer is deposited to absorb a light signal originating from the second semiconductor film and to convert the light signal into an electric signal, the conversion layer electrically connecting the PIN/NIP diode.

Abstract: Method for fabricating a transistor comprising the steps consisting of: forming sacrificial zones in a semi-conductor layer, either side of a transistor channel zone, forming insulating spacers on said sacrificial zones against the sides of the gate of said transistor, removing said sacrificial zones so as to form cavities, with the cavities extending on either side of said channel zone and penetrating under said spacers, forming doped semi-conductor material in said cavities, with said semi-conductor material penetrating under said spacers.

Abstract: The present disclosure concerns a method involving: forming a strained silicon germanium layer by epitaxial growth over a silicon layer disposed on a substrate; implanting atoms to amorphize the silicon layer and a lower portion of the silicon germanium layer, without amorphizing a surface portion of the silicon germanium layer; and annealing, to at least partially relax the silicon germanium layer and to re-crystallize the lower portion of the silicon germanium layer and the silicon layer, so that the silicon layer becomes a strained silicon layer.

Abstract: A layer of second semiconductor material is deposited on the layer of first semiconductor material of a substrate. Two active areas are then defined by means of selective elimination of the first and second semiconductor materials. One of the two active areas is then covered by a protective material. The layer of second semiconductor material is then eliminated by means of selective elimination of material. A first active area comprising a main surface made from a first semiconductor material, and a second active area comprising a main surface made from second semiconductor material are thus obtained.

Abstract: A layer of second semiconductor material is deposited on the layer of first semiconductor material of a substrate. Two active areas are then defined by means of selective elimination of the first and second semiconductor materials. One of the two active areas is then covered by a protective material. The layer of second semiconductor material is then eliminated by means of selective elimination of material. A first active area comprising a main surface made from a first semiconductor material, and a second active area comprising a main surface made from second semiconductor material are thus obtained.

Abstract: A method for producing stacked and self-aligned components on a substrate, including: providing a substrate made of monocrystalline silicon having one face enabling production of components, forming a stack of layers on the face of the substrate, selective etching by a gaseous mixture comprising gaseous HCl conveyed by a carrier gas and at a temperature between 450° C. and 900° C., depositing resin, implementing lithography of the resin, replacing resin eliminated during the lithography with a material for confining remaining resin, and forming elements of the components.

Abstract: The invention relates to a method for producing stacked and self-aligned components on a substrate, comprising the following steps: forming a stack of layers on one face of the substrate, the stack comprising a first sacrificial layer, a second sacrificial layer and a superficial layer, selective etching of a zone of the first sacrificial layer, the second sacrificial layer and the superficial layer forming a bridge above the etched zone of the first sacrificial layer, depositing resin in the etched zone of the first sacrificial layer and on the superficial layer, lithography of the resin to leave remaining at least one zone of resin in the etched zone of the first sacrificial layer, in alignment with at least one resin zone on the superficial layer, replacing the eliminated resin in the etched zone of the first sacrificial layer and on the superficial layer with a material for confining the remaining resin, eliminating the remaining resin zones in the etched zone of the first sacrificial layer and on the

Abstract: The invention relates to a process for fabricating a semiconductor structure, which comprises: a step a) of providing an Si substrate having a front face and a rear face; and a step b) that includes the epitaxial deposition, on the front face of the Si substrate, of a thick Ge layer, of an SiGe virtual substrate or of a multilayer comprising at least one thick Ge layer or at least one SiGe virtual substrate, and which is characterized in that it further includes the deposition, on the rear face of the Si substrate, of a layer or a plurality of layers generating, on this rear face, flexural stresses that compensate for the flexural stresses that are exerted on the front face of said substrate after step b). The invention also relates to a process for fabricating semiconductor-on-insulator substrates implementing the above process. Applications in microelectronics and optoelectronics.

Abstract: The invention concerns a method for forming nanostructures of semi-conductor material on a substrate of dielectric material by chemical vapour deposition (CVD). Said method comprises the following steps: a step of forming on the substrate (12) stable nuclei (14) of a first semi-conductor material in the form of islands, by CVD from a precursor (11) of the first semi-conductor material chosen so that the dielectric material (12) accepts the formation of said nuclei (14), a step of forming nanostructures (16A, 16B) of a second semi-conductor material from the stable nuclei (14) of the first semi-conductor material, by CVD from a precursor (21) chosen to generate a selective deposition of the second semi-conductor material only on said nuclei (14). The invention further concerns nanostructures formed according to one of said methods as well as devices comprising said nanostructures.

Abstract: The invention concerns a method for forming nanostructures of semi-conductor material on a substrate of dielectric material by chemical vapour deposition (CVD).