Abstract: A semiconductor device and a method of manufacturing the device is disclosed. In one aspect, a method includes providing a substrate, providing a first epitaxial semiconducting layer on top of the substrate, and forming a one- or two-dimensional repetitive pattern, each part of the pattern having an aspect ratio in the range of about 0.1 to 50.

Abstract: Disclosed are methods for forming hybrid metal-oxide-semiconductor field effect transistors (MOSFETs) and the hybrid MOSFETS thus obtained. In one embodiment, a method is disclosed that includes providing a first substrate comprising a first region and a second region, providing a second substrate comprising a second semiconductor layer and an insulating layer overlaying the second semiconductor layer, and direct substrate bonding the second substrate to the first substrate, thereby contacting the first region and the second region with the insulating layer. The method further includes selectively removing the second semiconductor layer and the insulating layer in the first region, thereby exposing the first semiconductor layer in the first region, forming a first gate stack of a first MOSFET on the exposed first semiconductor layer in the first region, and forming a second gate stack of a second MOSFET on the second semiconductor layer in the second region.

Abstract: Manufacturing an III-V engineered substrate involves providing a base substrate comprising an upper layer made of a first III-V compound with a <110> or a <111> crystal orientation, forming an intermediate layer comprising at least a buffer layer of a second III-V compound, wherein the intermediate layer is overlying and in contact with the upper layer of the base substrate. Then a pseudomorphic passivation layer made of a group IV semiconductor material is grown so as to be overlying and in contact with the intermediate layer. This can enable an unpinned interface. The substrate surface can be smoother, implying fewer problems from surface stress. It can be used in electronic devices such as metal-oxide-semiconductor field effect transistors (MOSFETs), high electron mobility transistors (HEMTs), tunneling field effect transistors (TFETs), and optoelectronic devices.

Abstract: A method for selective deposition of semiconductor materials in semiconductor processing is disclosed. In some embodiments, the method includes providing a patterned substrate comprising a first region and a second region, where the first region comprises an exposed first semiconductor material and the second region comprise an exposed insulator material. The method further includes selectively providing a film of the second semiconductor material on the first semiconductor material of the first region by providing a precursor of a second semiconductor material, a carrier gas that is not reactive with chlorine compounds, and tin-tetrachloride (SnCl4). The tin-tetrachloride inhibits the deposition of the second semiconductor material on the insulator material of the second region.

Abstract: The present disclosure is related to a method for the deposition of a continuous layer of germanium on a substrate by chemical vapor deposition. According to the disclosure, a mixture of a non-reactive carrier gas and a higher order germanium precursor gas, i.e. of higher order than germane (GeH4), is applied. In an example embodiment, the deposition is done under application of a deposition temperature between 275° C. and 500° C., with the partial pressure of the precursor gas within the mixture being at least 20 mTorr for temperatures between 275° C. and 285° C., and at least 10 mTorr for temperatures between 285° and 500° C.

Abstract: Disclosed are methods for manufacturing floating gate memory devices and the floating gate memory devices thus manufactured. In one embodiment, the method comprises providing a monocrystalline semiconductor substrate, forming a tunnel oxide layer on the substrate, and depositing a protective layer on the tunnel oxide layer to form a stack of the tunnel oxide layer and the protective layer. The method further includes forming at least one opening in the stack, thereby exposing at least one portion of the substrate, and cleaning the at least one exposed portion with a cleaning liquid. The method still further includes loading the substrate comprising the stack into a reactor and, thereafter, performing an in-situ etch to remove the protective layer, using the at least one exposed portion as a source to epitaxially grow a layer comprising the monocrystalline semiconductor material, and forming the layer into at least one columnar floating gate structure.

Abstract: The present invention relates to a semiconductor device comprising a homojunction or a heterojunction with a controlled dopant (concentration) profile and a method of making the same. Accordingly, one aspect of the invention is a method for manufacturing a junction comprising forming a first semiconductor material comprising a first dopant having a first concentration and thereupon; forming a second semiconductor material comprising a second dopant, having a second concentration thereby forming a junction, and depositing by Atomic Layer Epitaxy or Vapor Phase Doping at least a fraction of a monolayer of a precursor suitable to form the second dopant on the first semiconductor material, prior to forming the second semiconductor material, thereby increasing the second concentration of the second dopant at the junction.

Abstract: Methods of manufacturing a III-V compound semiconductor material, and the semiconductor material thus manufactured, are disclosed. In one embodiment, the method comprises providing a substrate comprising a first semiconductor material having a {001} orientation and an insulating layer overlaying the first semiconductor material. The insulating layer comprises a recessed region exposing an exposed region of the first semiconductor material. The method further comprises forming a buffer layer overlaying the exposed region that comprises a group IV semiconductor material. The method further comprises thermally annealing the substrate and the buffer layer, thereby roughening the buffer layer to create a rounded, double-stepped surface having a step density and a step height. A product of the step density and the step height is greater than or equal to 0.05 on the surface.

Abstract: One inventive aspect is related to an atomic layer deposition (ALD) method comprising: a) providing a semiconductor substrate in a reactor, b) providing a pulse of a first precursor gas into the reactor at a first temperature, c) providing a first pulse of a second precursor gas into the reactor at a second temperature, and d) providing a second pulse of the second precursor gas at a third temperature lower than the second temperature. Another inventive aspect relates to a reactor suitable to apply the method.

Abstract: A method for introducing species into a strained semiconductor layer comprising: providing a substrate comprising a first region comprising an exposed strained semiconductor layer, loading the substrate in a reaction chamber, then forming a conformal first species containing-layer by vapor phase deposition (VPD) at least on the exposed strained semiconductor layer, and thereafter performing a thermal treatment, thereby diffusing at least part of the first species from the first species-containing layer into the strained semiconductor layer and activating at least part of the diffused first species in the strained semiconductor layer.

Abstract: Manufacturing an III-V engineered substrate involves providing a base substrate comprising an upper layer made of a first III-V compound with a <110> or a <111> crystal orientation, forming an intermediate layer comprising at least a buffer layer of a second III-V compound, wherein the intermediate layer is overlying and in contact with the upper layer of the base substrate. Then a pseudomorphic passivation layer made of a group IV semiconductor material is grown so as to be overlying and in contact with the intermediate layer. This can enable an unpinned interface. The substrate surface can be smoother, implying fewer problems from surface stress. It can be used in electronic devices such as metal-oxide-semiconductor field effect transistors (MOSFETs), high electron mobility transistors (HEMTs), tunneling field effect transistors (TFETs), and optoelectronic devices.

Abstract: The present invention relates to a semiconductor device comprising a homojunction or a heterojunction with a controlled dopant (concentration) profile and a method of making the same. Accordingly, one aspect of the invention is a method for manufacturing a junction comprising forming a first semiconductor material comprising a first dopant having a first concentration and thereupon; forming a second semiconductor material comprising a second dopant, having a second concentration thereby forming a junction, and depositing by Atomic Layer Epitaxy or Vapor Phase Doping at least a fraction of a monolayer of a precursor suitable to form the second dopant on the first semiconductor material, prior to forming the second semiconductor material, thereby increasing the second concentration of the second dopant at the junction.

Abstract: The invention is related to an ALD method for depositing a layer including the steps of a) providing a semiconductor substrate in a reactor; b) providing a pulse of a first precursor gas into the reactor; c) providing a pulse of a second precursor gas into the reactor; d) providing an inert atmosphere in the reactor; and e) repeating step b) through step d), wherein at least once during step d) the semiconductor substrate is exposed to UV irradiation.

Abstract: A method of producing a semiconductor device using a selective epitaxial growth (SEG) process is disclosed. In one aspect, the method comprises providing a semiconductor substrate, forming a pattern of an insulation material on the semiconductor substrate, thereby defining a covered and non covered surface, performing a cleaning processing of the covered and non covered surface of the substrate having the insulating pattern defined, loading the substrate with the insulating pattern into a reaction chamber of an epitaxial reactor, and starting a selective epitaxial growth comprising an injection of at least one semiconductor source gas possibly with at least one first carrier gas in the reaction chamber of the epitaxial reactor. The method further comprises, prior to the selective epitaxial growth, the surface of the substrate is subjected in the reaction chamber to an in situ pre-treatment with the injection of a halogen containing etching gas possibly with a second carrier gas.

Abstract: Electronic devices are disclosed that may be used for infrared radiation detection. An example electronic device includes a substrate, a transistor included in the substrate and a silicon-germanium (Si—Ge) structural layer coupled with the transistor. The structural layer has a stress in a predetermined range, where the predetermined range for the stress is selected prior to deposition of the structural layer. Also, the structural layer is deposited on the substrate subsequent to formation of the transistor such that deposition of the structural layer does not substantially adversely affect the operation of the transistor.

Abstract: The invention is related to an ALD method for depositing a layer comprising the steps of a) providing a semiconductor substrate in a reactor; b) providing a pulse of a first precursor gas into the reactor; c) providing a pulse of a second precursor gas into the reactor; d) providing an inert atmosphere in the reactor; and e) repeating step b) through step d), wherein at least once during step d) the semiconductor substrate is exposed to UV irradiation.

Abstract: Method and apparatus to obtain as-deposited polycrystalline and low-stress SiGe layers. These layers may be used in Micro Electro-Mechanical Systems (MEMS) devices or micromachined structures. Different parameters are analysed which effect the stress in a polycrystalline layer. The parameters include, without limitation: deposition temperature; concentration of semiconductors (e.g., the concentration of Silicon and Germanium in a SixGe1?x layer, with x being the concentration parameter); concentration of dopants (e.g., the concentration of Boron or Phosphorous); amount of pressure; and use of plasma. Depending on the particular environment in which the polycrystalline SiGe is grown, different values of parameters may be used.

Abstract: Electronic devices are disclosed that may be used for infrared radiation detection. An example electronic device includes a substrate, a transistor included in the substrate and a silicon-germanium (Si—Ge) structural layer coupled with the transistor. The structural layer has a stress in a predetermined range, where the predetermined range for the stress is selected prior to deposition of the structural layer. Also, the structural layer is deposited on the substrate subsequent to formation of the transistor such that deposition of the structural layer does not substantially adversely affect the operation of the transistor.

Abstract: One inventive aspect is related to an atomic layer deposition (ALD) method comprising: a) providing a semiconductor substrate in a reactor, b) providing a pulse of a first precursor gas into the reactor at a first temperature, c) providing a first pulse of a second precursor gas into the reactor at a second temperature, and d) providing a second pulse of the second precursor gas at a third temperature lower than the second temperature. Another inventive aspect relates to a reactor suitable to apply the method.

Abstract: A method of controlling an internal stress in a polycrystalline silicon-germanium layer deposited on a substrate. The method includes selecting a deposition pressure that is at or below atmospheric pressure and selecting a deposition temperature that is no greater than 700° C. The deposition pressure and the deposition temperature are selected so as to achieve an internal stress in the silicon-germanium layer that is within a predetermined range.