Abstract: A nanotube-based flexible field effect transistor and its method of manufacture is provided. The field effect transistor according to the invention comprises at least two contact electrodes, respectively drain and source electrodes, an electrical conduction zone connected to the contact electrodes, said zone comprising a plurality of single-wall carbon nanotubes that are substantially aligned, a gate electrode for controlling the electric current circulating in said zone and a flexible substrate on which the contact and gate electrodes are deposited. The nanotube density in the conduction zone is strictly greater than 10 nanotubes per micrometer.

Abstract: A process for mask-free localized grafting of organic molecules capable of being electrically activated, onto a composite surface comprising conductive and/or semiconductive portions, by placing said organic molecules in contact with said composite surface, in which said grafting is performed electrochemically in a single step on chosen, defined areas of said conductive and/or semiconductive portions, said areas being brought to a potential higher than or equal to a threshold electrical potential determined relative to a reference electrode, said threshold electrical potential being the potential above which grafting of said organic molecules takes place.

Abstract: The invention relates to an integrated device (PM) for characterising electric or electronic components (DUT), in particular nanometric ones, comprising a substantially insulating substrate (S) on which are provided four conducting pads (P1, P2, P3, P4), at least three resistive pads (R1, R3, R4) connecting said pads together, and a transmission line (CPW) including a signal conductor (Cc) and at least one ground conductor (CL1, CL2), wherein: said resistive pads are arranged so as to connect a first conducting pad to a second and a fourth conducting pad, and to connect said fourth conducting pad to a third conducting pad; the signal conductor of the transmission line is connected to the first conducting pad; and the ground conductor of the transmission line is connected to the third pad.

Abstract: The invention concerns a device for detecting and storing electromagnetic beams, an imager incorporating same, a method for making said device and use thereof. The inventive device comprises a field-effect phototransistor including: two source and drain contact electrodes, an electrical conduction unit which is connected to the two contact electrodes and which is coated with a photosensitive polymeric coating capable of absorbing the beams, of detecting, of generating in response the loads detected by said unit and of storing said loads, and a gate electrode which is capable of controlling the electric current in the unit as well as spatially distributing the loads in said coating and which is separated from said unit by a gate dielectric.

Abstract: The invention concerns a device for detecting and storing electromagnetic beams, an imager incorporating same, a method for making said device and use thereof. The inventive device comprises a field-effect phototransistor including: two source and drain contact electrodes, an electrical conduction unit which is connected to the two contact electrodes and which is coated with a photosensitive polymeric coating capable of absorbing the beams, of detecting, of generating in response the loads detected by said unit and of storing said loads, and a gate electrode which is capable of controlling the electric current in the unit as well as spatially distributing the loads in said coating and which is separated from said unit by a gate dielectric.

Abstract: A nanotube-based flexible field effect transistor and its method of manufacture is provided. The field effect transistor according to the invention comprises at least two contact electrodes, respectively drain and source electrodes, an electrical conduction zone connected to the contact electrodes, said zone comprising a plurality of single-wall carbon nanotubes that are substantially aligned, a gate electrode for controlling the electric current circulating in said zone and a flexible substrate on which the contact and gate electrodes are deposited. The nanotube density in the conduction zone is strictly greater than 10 nanotubes per micrometer.

Abstract: The present invention concerns a method for modyfing at least an electronic property of a carbon nanotube or nanowire comprising exposing said nanotube or nanowire to an acid having the formula (I) wherein R1, R2 and R3 are chosen in the group comprising (H, F, Cl, Br, I) with at least one of R1, R2 and R3 being different from H. At least part of the nanotube or nanowire may be a channel region of a field effect transistor.

Abstract: The invention relates to a semiconductor device comprising at least two electrodes and at least one nanotube or nanowire, in particular a carbon nanotube or nanowire, the device including at least one semiconductive nanotube or nanowire having at least one region that is covered at least in part by at least one layer of molecules or nanocrystals of at least one photosensitive material, an electrical connection between said two electrodes being made by at least one nanotube, namely said semiconductive nanotube or nanowire and optionally by at least one other nanotube or nanowire.

Abstract: The invention relates to a semiconductor device comprising at least two electrodes and at least one nanotube or nanowire, in particular a carbon nanotube or nanowire, the device including at least one semiconductive nanotube or nanowire having at least one region that is covered at least in part by at least one layer of molecules or nanocrystals of at least one photosensitive material, an electrical connection between said two electrodes being made by at least one nanotube, namely said semiconductive nanotube or nanowire and optionally by at least one other nanotube or nanowire.

Abstract: The present invention concerns a method for modyfing at least an electronic property of a carbon nanotube or nanowire comprising exposing said nanotube or nanowire to an acid having the formula (I) wherein R1, R2 and R3 are chosen in the group comprising (H, F, Cl, Br, I) with at least one of R1, R2 and R3 being different from H. At least part of the nanotube or nanowire may be a channel region of a field effect transistor.

Abstract: The invention concerns a mask-free localised grafting of organic molecules capable of being electrically activated, on a composite surface comprising conductive and/or semiconductive portions, by contacting said organic molecules with said composite surface, whereby the grafting is carried out electrochemically in one single step on specific selected zones of said conductive and/or semiconductive portions, said zones being brought to a potential not less than an electric potential threshold determined relative to a reference electrode, said electric potential threshold being the potential beyond which the grafting of said organic molecules occurs.

Abstract: A process for mask-free localized grafting of organic molecules capable of being electrically activated, onto a composite surface comprising conductive and/or semiconductive portions, by placing said organic molecules in contact with said composite surface, in which said grafting is performed electrochemically in a single step on chosen, defined areas of said conductive and/or semiconductive portions, said areas being brought to a potential higher than or equal to a threshold electrical potential determined relative to a reference electrode, said threshold electrical potential being the potential above which grafting of said organic molecules takes place.

Abstract: A method of forming a network of islands (124) of semiconductor material on an electrically insulating material (112), comprising: p1 a) the deposition of nucleation kernels (122) on the surface of the electrically insulating material, b) the formation of islands of semiconductor material (124) respectively on the nucleation kernels. In accordance with the invention, the deposition of the nucleation kernels is effected using at least one so-called distribution layer (116) made of a material having a substantially regular molecular structure, formed on the surface of the electrically insulating material (112), in order to distribute the nucleation kernels in a substantially regular fashion on the surface of the electrically insulating material.