Abstract: The current invention provides methods for performing a cleaning process that provides greater cleaning efficiency with less damage to device structures. After etching and photoresist stripping, a first plasma clean is performed. The first plasma clean may comprise one or more steps. Following the first plasma clean, a first HO based clean is performed. The first HO based clean may be a de-ionized water rinse, a water vapor clean, or a plasma clean, where the plasma includes hydrogen and oxygen. Following the first HO based clean, a second plasma clean is performed, which may comprise one or more steps. A second HO based clean follows the second plasma clean, and may be a de-ionized water rinse, a water vapor clean, or a plasma clean, where the plasma includes hydrogen and oxygen. For plasma processes, an RF, generated plasma, a microwave generated plasma, an inductively coupled plasma, or combination may be used.

Abstract: The current invention provides methods for performing a cleaning process that provides greater cleaning efficiency with less damage to device structures. After etching and photoresist stripping, a first plasma clean is performed. The first plasma clean may comprise one or more steps. Following the first plasma clean, a first HO based clean is performed. The first HO based clean may be a de-ionized water rinse, a water vapor clean, or a plasma clean, where the plasma includes hydrogen and oxygen. Following the first HO based clean, a second plasma clean is performed, which may comprise one or more steps. A second HO based clean follows the second plasma clean, and may be a de-ionized water rinse, a water vapor clean, or a plasma clean, where the plasma includes hydrogen and oxygen. For plasma processes, an RF generated plasma, a microwave generated plasma, an inductively coupled plasma, or combination may be used.

Abstract: The current invention provides methods for performing a cleaning process that provides greater cleaning efficiency with less damage to device structures. After etching and photoresist stripping, a first plasma clean is performed. The first plasma clean may comprise one or more steps. Following the first plasma clean, a first HO based clean is performed. The first HO based clean may be a de-ionized water rinse, a water vapor clean, or a plasma clean, where the plasma includes hydrogen and oxygen. Following the first HO based clean, a second plasma clean is performed, which may comprise one or more steps. A second HO based clean follows the second plasma clean, and may be a de-ionized water rinse, a water vapor clean, or a plasma clean, where the plasma includes hydrogen and oxygen. For plasma processes, an RF generated plasma, a microwave generated plasma, an inductively coupled plasma, or combination may be used.

Abstract: The method prevents oxidation or contamination phenomena of conductive interconnection structures in semiconductor devices and includes providing a layer of semiconductor or oxide base, a conductive layer or stack on the base layer, and an antireflection coating (ARC) layer on the conductive layer or stack. The method provides a thin dielectric covering layer on the antireflection coating layer to fill or cover the microfissures existing in the antireflection coating layer.

Abstract: A process for manufacturing an organic mask for the microelectronics industry, including forming an organic layer on a substrate; forming an inorganic mask on the organic layer; and etching selectively the organic layer through the inorganic mask. Furthermore, forming the inorganic mask includes forming at least a first auxiliary layer of a first inorganic material on the organic layer; forming a mask layer of a second inorganic material different from the first inorganic material on the first auxiliary layer; and shaping the mask layer using a dual-exposure lithographic process.

Abstract: A method for defining geometries in a semiconductor wafer supported on a plate electrode in a processing chamber includes forming a reusable refractory coated laminar mask. The reusable refractory coated laminar mask is formed by defining the geometries in a laminar mask substrate, forming apertures through the laminar mask substrate, and forming a layer of refractory material over at least one surface of the laminar mask substrate. The reusable refractory coated laminar mask is positioned over the semiconductor wafer. Treating of the semiconductor wafer is performed through the apertures of the reusable refractory coated laminar mask. The treating may be plasma etching or ion etching.

Abstract: The method prevents oxidation or contamination phenomena of conductive interconnection structures in semiconductor devices and includes providing a layer of semiconductor or oxide base, a conductive layer or stack on the base layer, and an antireflection coating (ARC) layer on the conductive layer or stack. The method provides a thin dielectric covering layer on the antireflection coating layer to fill or cover the microfissures existing in the antireflection coating layer.

Abstract: A process for the definition of integrated circuits on a wafer having at least one silicon semiconductor layer includes masking the wafer with a photoresist layer. The process includes a development step of the photoresist with definition of a lithographic pattern, a hardening step of the photoresist with a plasma of inert gas, and a dry etching step with a plasma of reactive gas for transferring the lithographic pattern on the wafer. The dry etching step includes at least an initial step, or breakthrough, with a plasma of a chlorinated gas and of an inert gas for removal of a silicon native oxide grown on the wafer.

Abstract: A method for manufacturing semiconductor-integrated electronic circuits includes: depositing an auxiliary layer on a substrate; depositing a layer of screening material on the auxiliary layer; selectively removing the layer of screening material to provide a first opening in the layer of screening material and expose an area of the auxiliary layer; and removing this area of the auxiliary layer to form a second opening in the auxiliary layer, whose cross-section narrows toward the substrate to expose an area of the substrate being smaller than the area exposed by the first opening.

Abstract: A method for manufacturing semiconductor-integrated electronic circuits includes: depositing an auxiliary layer on a substrate; depositing a layer of screening material on the auxiliary layer; selectively removing the layer of screening material to provide a first opening in the layer of screening material and expose an area of the auxiliary layer; and removing this area of the auxiliary layer to form a second opening in the auxiliary layer, whose cross-section narrows toward the substrate to expose an area of the substrate being smaller than the area exposed by the first opening.

Abstract: A method for defining geometries in a semiconductor wafer supported on a plate electrode in a processing chamber includes forming a reusable refractory coated laminar mask. The reusable refractory coated laminar mask is formed by defining the geometries in a laminar mask substrate, forming apertures through the laminar mask substrate, and forming a layer of refractory material over at least one surface of the laminar mask substrate. The reusable refractory coated laminar mask is positioned over the semiconductor wafer. Treating of the semiconductor wafer is performed through the apertures of the reusable refractory coated laminar mask. The treating may be plasma etching or ion etching.

Abstract: The method prevents oxidation or contamination phenomena of conductive interconnection structures in semiconductor devices and includes providing a layer of semiconductor or oxide base, a conductive layer or stack on the base layer, and an antireflection coating (ARC) layer on the conductive layer or stack. The method provides a thin dielectric covering layer on the antireflection coating layer to fill or cover the microfissures existing in the antireflection coating layer.

Abstract: A method (300) and a corresponding apparatus for detecting a leak of external air into a plasma reactor are proposed. The method includes: establishing (340) a plasma inside the reactor, the plasma having a composition suitable to generate at least one predetermined compound when reacting with the air, detecting (345) a light emission of the plasma, and analyzing (350-375) the light emission to identify the presence of the at least one predetermined compound.

Abstract: A method for manufacturing semiconductor-integrated electronic circuits comprises: depositing an auxiliary layer on a substrate; depositing a layer of screening material on the auxiliary layer; selectively removing the layer of screening material to provide a first opening in the layer of screening material and expose an area of the auxiliary layer; and removing this area of the auxiliary layer to form a second opening in the auxiliary layer, whose cross-section narrows toward the substrate to expose an area of the substrate being smaller than the area exposed by the first opening.

Abstract: The process for the fabrication of an electronic device has the steps of forming a layer to be etched on top of a substrate in a wafer of semiconductor material; depositing a masking layer; and carrying out a plasma etch to define the geometry of the layer to be etched. The masking layer is made so as to be conductive, at least during one part of the etching step; in this way, the electrons implanted on the top part of the masking layer during plasma etching can recombine with the positive charges which have reached the layer to be etched. The recombination of the charges makes it possible to prevent damage from plasma resulting from the formation of parasitic electric currents which are detrimental to the electronic device itself.

Abstract: A method enhances selectivity between a film of a light-sensitive material and a layer to be subjected to etching in the course of fabrication processes of an electronic semiconductor device starting from a semiconductor material wafer. The method includes radiating the wafer with an ion beam subsequently to depositing the layer to be etched and defining a circuit pattern on the film of light-sensitive material. An alternative method exposes the wafer to a non-reactive gas medium under plasma rather than radiating the wafer with an ion beam.

Abstract: A method enhances selectivity between a film of a light-sensitive material and a layer to be subjected to etching in the course of fabrication processes of an electronic semiconductor device starting from a semiconductor material wafer. The method includes radiating the wafer with an ion beam subsequently to depositing the layer to be etched and defining a circuit pattern on the film of light-sensitive material. An alternative method exposes the wafer to a non-reactive gas medium under plasma rather than radiating the wafer with an ion beam.

Abstract: The method described comprises the following steps: measuring, with a spectroscopic ellipsometer, the values of two quantities which are dependent on the thickness of the altered silicon layer and of a thin layer of silicon dioxide grown thereon with variations in the wavelength of the light of the measurement beam of the ellipsometer, obtaining from these measured values respective experimental curves representing the two quantities as functions of the wavelength, calculating the theoretical curves of the two quantities as functions of the wavelength considering the refractive indices and absorption coefficients of silicon dioxide and of the altered silicon as known parameters and the thickness of the altered silicon layer and the thickness of the thin silicon dioxide layer as unknowns, comparing the theoretical curves with the respective experimental curves in order to determine for which values of the unknowns the curves under comparison approximate to one another best, and extracting from the values dete

Abstract: A method for assessing alterations in the dielectric properties of insulating layers on a wafer of semiconductor material induced by plasma treatments. The method includes forming cells of EEPROM type on a wafer with source, drain and control gate surface terminals (pads), subjecting the cells to UV radiation so as to erase them thereby fixing a reference threshold voltage, applying programming voltages of preset value to at least one of the cells and measuring the corresponding threshold voltages, and subjecting this cell to UV radiation so as to restore its threshold to the reference value. The wafer is then subjected to the plasma treatment to be assessed, and the threshold voltages of the cells are measured and compared with the reference threshold voltage so as to derive from the comparison information on the alterations induced on the dielectrics formed on the wafer and on the distribution of the plasma potential.

Abstract: The process described requires the formation of floating-gate non-volatile memory cells entirely similar in structure to those produced by known processes. The process comprises an annealing treatment at relatively low temperature (430.degree. C.) to repair damage due to plasma treatments. To obtain threshold voltage values for the cells close to the theoretical values, especially for cells with particularly extended interconnections, the cells are subjected to ultraviolet radiation before the annealing treatment, in order to neutralize any electrical charges present in the floating-gate electrodes of the cells.