Abstract: The disclosure concerns an electronic component manufacturing method including a first step of etching at least one first layer followed, with no exposure to oxygen, by a second step of passivating the first layer.

Abstract: The disclosure concerns an electronic component manufacturing method including a first step of etching at least one first layer followed, with no exposure to oxygen, by a second step of passivating the first layer.

Abstract: A method for etching a layer of assembled block copolymer including first and second polymer phases, the etching method including a first step of etching by a first plasma formed from carbon monoxide or a first gas mixture including a fluorocarbon gas and a depolymerising gas, the first etching step being carried out so as to partially etch the first polymer phase and to deposit a carbon layer on the second polymer phase, and a second step of etching by a second plasma formed from a second gas mixture including a depolymerising gas and a gas selected among the carbon oxides and the fluorocarbon gases, the second etching step being carried out so as to etch the first polymer phase and the carbon layer on the second polymer phase.

Abstract: The disclosure concerns an electronic component manufacturing method including a first step of etching at least one first layer followed, with no exposure to oxygen, by a second step of passivating the first layer.

Abstract: A method for etching a dielectric layer covering at least one top and at least one flank of a semi-conductive material-based structure is provided, including a plurality of sequences, each including successive steps of: a first etching of the layer by plasma using a chemistry including at least a first fluorine-based compound and a second compound chosen from SiwCl(2w+2) and SiwF(2w+2), w, x, y, and z being whole numbers, and oxygen, the first etching: interrupting before complete consumption of the dielectric layer thickness on the flank and after complete consumption of the thickness on the top, and forming a first protective layer on the top and a second protective layer on the flank; and a second etching fully removing the second layer while conserving a portion of the first layer thickness, each sequence being repeated until complete removal of the dielectric layer on the flank.

Abstract: A method for etching a dielectric layer covering at least one top and at least one flank of a semi-conductive material-based structure is provided, including a plurality of sequences, each including successive steps of: a first etching of the layer by plasma using a chemistry including at least a first fluorine-based compound and a second compound chosen from SiwCl(2w+2) and SiwF(2w+2), w, x, y, and z being whole numbers, and oxygen, the first etching: interrupting before complete consumption of the dielectric layer thickness on the flank and after complete consumption of the thickness on the top, and forming a first protective layer on the top and a second protective layer on the flank; and a second etching fully removing the second layer while conserving a portion of the first layer thickness, each sequence being repeated until complete removal of the dielectric layer on the flank.

Abstract: There is provided a method for producing on a same substrate at least one first transistor and at least one second transistor that have different characteristics, the method including producing at least one first gate pattern and at least one second gate pattern on the substrate; depositing, on the first and the second gate patterns, at least: a first protective layer, and a second protective layer overlying the first protective layer and made of a material different from that of the first protective layer; masking of the second gate pattern by a masking layer; isotropic etching of the second protective layer; removing the masking layer; and anisotropic etching of the second protective layer selectively relative to the first protective layer.

Abstract: A method for etching a layer of assembled block copolymer including first and second polymer phases, the etching method including a first step of etching by a first plasma formed from carbon monoxide or a first gas mixture including a fluorocarbon gas and a depolymerising gas, the first etching step being carried out so as to partially etch the first polymer phase and to deposit a carbon layer on the second polymer phase, and a second step of etching by a second plasma formed from a second gas mixture including a depolymerising gas and a gas selected among the carbon oxides and the fluorocarbon gases, the second etching step being carried out so as to etch the first polymer phase and the carbon layer on the second polymer phase.

Abstract: The invention relates to a method of etching a layer of porous dielectric material, characterized in that the etching is performed in a plasma formed from at least one silicon-based gas mixed with oxygen (O2) and/or nitrogen (N2) so as to grow a passivation layer all along said etching, at least on flanks of the layer of porous dielectric material and wherein the silicon-based gas is taken from all the compounds of the type SixHy for which the ratio x/y is equal or greater than 0.3 or is taken from all the compounds of the following types: SixFy and SixCly, where x is the proportion of silicon (Si) in the gas and y is the proportion of fluorine (F) or chlorine (Cl) or hydrogen (H) in the gas.

Abstract: A method for forming reliefs on the surface of a substrate, including a first implantation of ions in the substrate according to a first direction; a second implantation of ions in the substrate according to a second direction that is different from the first direction; at least one of the first and second implantations is carried out through at least one mask having at least one pattern; an etching of areas of the substrate having received by implantation a dose greater than or equal to a threshold, selectively to the areas of the substrate that have not received via implantation a dose greater than said threshold; the parameters of the first and second implantations being adjusted in such a way that only areas of the substrate that have been implanted both during the first implantation and during the second implantation receive a dose greater than or equal to said threshold.

Abstract: The invention relates in particular to a method for producing subsequent patterns in an underlying layer (120), the method comprising at least one step of producing prior patterns in a carbon imprintable layer (110) on top of the underlying layer (120), the production of the prior patterns involving nanoimprinting of the imprintable layer (110) and leave in place a continuous layer formed by the imprintable layer (110) and covering the underlying layer (120), characterized in that it comprises the following step: at least one step of modifying the underlying layer (120) via ion implantation (421) in the underlying layer (120), the implantation (421) being carried out through the imprintable layer (110) comprising the subsequent patterns, the parameters of the implantation (421) being chosen in such a way as to form, in the underlying layer (120), implanted zones (122) and non-implanted zones, the non-Implanted zones defining the subsequent patterns and having a geometry that is dependent on the prior pattern

Abstract: The invention relates in particular to a method for producing subsequent patterns in an underlying layer (120), the method comprising at least one step of producing prior patterns in a carbon imprintable layer (110) on top of the underlying layer (120), the production of the prior patterns involving nanoimprinting of the imprintable layer (110) and leave in place a continuous layer formed by the imprintable layer (110) and covering the underlying layer (120), characterized in that it comprises the following step: at least one step of modifying the underlying layer (120) via ion implantation (421) in the underlying layer (120), the implantation (421) being carried out through the imprintable layer (110) comprising the subsequent patterns, the parameters of the implantation (421) being chosen in such a way as to form, in the underlying layer (120), implanted zones (122) and non-implanted zones, the non-Implanted zones defining the subsequent patterns and having a geometry that is dependent on the prior pattern

Abstract: There is provided a method for producing on a same substrate at least one first transistor and at least one second transistor that have different characteristics, the method including producing at least one first gate pattern and at least one second gate pattern on the substrate; depositing, on the first and the second gate patterns, at least: a first protective layer, and a second protective layer overlying the first protective layer and made of a material different from that of the first protective layer; masking of the second gate pattern by a masking layer; isotropic etching of the second protective layer; removing the masking layer; and anisotropic etching of the second protective layer selectively relative to the first protective layer.

Abstract: A method for forming reliefs on the surface of a substrate, including a first implantation of ions in the substrate according to a first direction; a second implantation of ions in the substrate according to a second direction that is different from the first direction; at least one of the first and second implantations is carried out through at least one mask having at least one pattern; an etching of areas of the substrate having received by implantation a dose greater than or equal to a threshold, selectively to the areas of the substrate that have not received via implantation a dose greater than said threshold; the parameters of the first and second implantations being adjusted in such a way that only areas of the substrate that have been implanted both during the first implantation and during the second implantation receive a dose greater than or equal to said threshold.

Abstract: A method for etching a dielectric layer located on the surface of a three-dimensional structure formed on a face of a substrate oriented along a plane of a substrate, which includes a step of implanting ions so as to directionally create a top layer in the dielectric layer. Such top layer is thus not formed everywhere. Then, the layer in question is removed, except on the predefined zones, such as flanks of a transistor gate. A selective etching of the dielectric layer is executed relative to the material of the residual part of the top layer and relative to the material of the face of the substrate.

Abstract: A substrate is successively provided with a support (7), an electrically insulating layer (8), and a semi-conductor material layer (2). A first protective mask (1) completely covers a second area (B) of the semi-conductor material layer and leaves a first area (A) of the semi-conductor material layer uncovered. A second etching mask (3) partially covers the first area (A) and at least partially covers the second area (B), so as to define and separate a first area and a second area. Lateral spacers are formed on the lateral surfaces of the second etching mask (3) so as to form a third etching mask. The semi-conductor material layer (2) is etched by means of the third etching mask so as to form a pattern made from semi-conductor material in the first area (A), the first etching mask (3) protecting the second area (B).

Abstract: The production of spacers at flanks of a transistor gate, including a step of forming a dielectric layer covering the gate and a peripheral region of a layer of semiconductor material surrounding the gate, including forming a superficial layer covering the gate and the peripheral region; partially removing the superficial layer configured so as to completely remove the superficial layer at the peripheral region while preserving a residual part of the superficial layer at the flanks; and selective etching of the dielectric layer vis-à-vis the material of the residual part of the superficial layer and vis-à-vis the semiconductor material.

Abstract: A method includes making a gate stack on the surface of an active zone, including depositing a first dielectric layer; depositing a gate conductive layer; depositing a first metal layer; depositing a second metal layer; depositing a second dielectric layer; partially etching the gate stack for the formation of a gate zone on the active zone; making insulating spacers on either side of the gate zone on the active zone; making source and drain electrodes zones; making silicidation zones on the surface of the source and drain zones; etching, in the gate zone on the active zone, the second dielectric layer and the second metal layer with stopping on the first metal layer, so as to form a cavity between the insulating spacers; making a protective plug at the surface of the first metal layer of the gate zone on the active zone, where the protective plug fills the cavity.

Abstract: A method for etching a dielectric layer located on the surface of a three-dimensional structure formed on a face of a substrate oriented along a plane of a substrate, which includes a step of implanting ions so as to directionally create a top layer in the dielectric layer. Such top layer is thus not formed everywhere. Then, the layer in question is removed, except on the predefined zones, such as flanks of a transistor gate. A selective etching of the dielectric layer is executed relative to the material of the residual part of the top layer and relative to the material of the face of the substrate.

Abstract: The production of spacers at flanks of a transistor gate, including a step of forming a dielectric layer covering the gate and a peripheral region of a layer of semiconductor material surrounding the gate, including forming a superficial layer covering the gate and the peripheral region; partially removing the superficial layer configured so as to completely remove the superficial layer at the peripheral region while preserving a residual part of the superficial layer at the flanks; and selective etching of the dielectric layer vis-à-vis the material of the residual part of the superficial layer and vis-à-vis the semiconductor material.