Patent application number | Description | Published |
20080254623 | METHODS FOR GROWING LOW-RESISTIVITY TUNGSTEN FOR HIGH ASPECT RATIO AND SMALL FEATURES - The present invention addresses this need by providing methods for depositing low resistivity tungsten films in small features and features having high aspect ratios. The methods involve depositing very thin tungsten nucleation layers by pulsed nucleation layer (PNL) processes and then using chemical vapor deposition (CVD) to deposit a tungsten layer to fill the feature. Depositing the tungsten nucleation layer involves exposing the substrate to alternating pulses of a boron-containing reducing agent and a tungsten-containing precursor without using any hydrogen gas, e.g., as a carrier or background gas. Using this process, a conformal tungsten nucleation layer can be deposited to a thickness as small as about 10 Angstroms. The feature may then be wholly or partially filled with tungsten by a hydrogen reduction chemical vapor deposition process. Resistivities of about 14 μΩ-cm for a 500 Angstrom film may be obtained. | 10-16-2008 |
20100035427 | METHODS FOR GROWING LOW-RESISTIVITY TUNGSTEN FILM - Improved methods for depositing low resistivity tungsten films are provided. The methods involve depositing a tungsten nucleation layer on a substrate and then depositing a tungsten bulk layer over the tungsten nucleation layer to form the tungsten film. The methods provide precise control of the nucleation layer thickness and improved step coverage. According to various embodiments, the methods involve controlling thickness and/or improving step coverage by exposing the substrate to pulse nucleation layer (PNL) cycles at low temperature. Also in some embodiments, the methods may improve resistivity by using a high temperature PNL cycle of a boron-containing species and a tungsten-containing precursor to finish forming the tungsten nucleation layer. | 02-11-2010 |
20110223763 | METHODS FOR GROWING LOW-RESISTIVITY TUNGSTEN FOR HIGH ASPECT RATIO AND SMALL FEATURES - The present invention addresses this need by providing methods for depositing low resistivity tungsten films in small features and features having high aspect ratios. The methods involve depositing very thin tungsten nucleation layers by pulsed nucleation layer (PNL) processes and then using chemical vapor deposition (CVD) to deposit a tungsten layer to fill the feature. Depositing the tungsten nucleation layer involves exposing the substrate to alternating pulses of a boron-containing reducing agent and a tungsten-containing precursor without using any hydrogen gas, e.g., as a carrier or background gas. Using this process, a conformal tungsten nucleation layer can be deposited to a thickness as small as about 10 Angstroms. The feature may then be wholly or partially filled with tungsten by a hydrogen reduction chemical vapor deposition process. Resistivities of about 14 μΩ-cm for a 500 Angstrom film may be obtained. | 09-15-2011 |
20130109172 | HIGH TEMPERATURE TUNGSTEN METALLIZATION PROCESS | 05-02-2013 |
20130168864 | METHOD FOR PRODUCING ULTRA-THIN TUNGSTEN LAYERS WITH IMPROVED STEP COVERAGE - A tungsten nucleation film is formed on a surface of a semiconductor substrate by alternatively providing to that surface, reducing gases and tungsten-containing gases. Each cycle of the method provides for one or more monolayers of the tungsten film. The film is conformal and has improved step coverage, even for a high aspect ratio contact hole. | 07-04-2013 |
20140094036 | DIRECTIONAL SIO2 ETCH USING LOW-TEMPERATURE ETCHANT DEPOSITION AND PLASMA POST-TREATMENT - Methods for processing a substrate are described herein. Methods can include positioning a substrate comprising silicon in a processing chamber, delivering a plasma to the surface of the substrate while biasing the substrate, exposing the surface of the substrate to ammonium fluoride (NH | 04-03-2014 |
20140106083 | TUNGSTEN GROWTH MODULATION BY CONTROLLING SURFACE COMPOSITION - A method for selectively controlling deposition rate of a catalytic material during a catalytic bulk CVD deposition is disclosed herein. The method can include positioning a substrate in a processing chamber including both surface regions and gap regions, depositing a first nucleation layer comprising tungsten conformally over an exposed surface of the substrate, treating at least a portion of the first nucleation layer with activated nitrogen, wherein the activated nitrogen is deposited preferentially on the surface regions, reacting a first deposition gas comprising tungsten halide and hydrogen-containing gas to deposit a tungsten fill layer preferentially in gap regions of the substrate, reacting a nucleation gas comprising a tungsten halide to form a second nucleation layer, and reacting a second deposition gas comprising tungsten halide and a hydrogen-containing gas to deposit a tungsten field layer. | 04-17-2014 |
20140120700 | PLASMA TREATMENT OF FILM FOR IMPURITY REMOVAL - Methods for plasma treatment of films to remove impurities are disclosed herein. Methods for removing impurities can include positioning a substrate with a barrier layer in a processing chamber, the barrier layer comprising a barrier metal and one or more impurities, maintaining the substrate at a bias, creating a plasma comprising a treatment gas, the treatment gas comprising an inert gas, delivering the treatment gas to the substrate to reduce the ratio of one or more impurities in the barrier layer, and reacting a deposition gas comprising a metal halide and hydrogen-containing gas to deposit a bulk metal layer on the barrier layer. The methods can further include the use of diborane to create selective nucleation in features over surface regions of the substrate. | 05-01-2014 |
20140187038 | HIGH TEMPERATURE TUNGSTEN METALLIZATION PROCESS - Embodiments of the invention provide an improved process for depositing tungsten-containing materials. In one embodiment, the method for forming a tungsten-containing material on a substrate includes forming an adhesion layer containing titanium nitride on a dielectric layer disposed on a substrate, forming a tungsten nitride intermediate layer on the adhesion layer, wherein the tungsten nitride intermediate layer contains tungsten nitride and carbon. The method further includes forming a tungsten barrier layer (e.g., tungsten or tungsten-carbon material) from the tungsten nitride intermediate layer by thermal decomposition during a thermal annealing process (e.g., temperature from about 700° C. to less than 1,000° C.). Subsequently, the method includes optionally forming a nucleation layer on the tungsten barrier layer, optionally exposing the tungsten barrier layer and/or the nucleation layer to a reducing agent during soak processes, and forming a tungsten bulk layer on or over the tungsten barrier layer and/or the nucleation layer. | 07-03-2014 |
20140193979 | DIRECTIONAL SIO2 ETCH USING PLASMA PRE-TREATMENT AND HIGH-TEMPERATURE ETCHANT DEPOSITION - Methods for processing a substrate are described herein. Methods can include positioning a substrate with an exposed surface comprising a silicon oxide layer in a processing chamber, biasing the substrate, treating the substrate to roughen a portion of the silicon oxide layer, heating the substrate to a first temperature, exposing the exposed surface of the substrate to a plasma comprising ammonium fluoride to form one or more volatile products while maintaining the first temperature, and heating the substrate to a second temperature, which is higher than the first temperature, to sublimate the volatile products. | 07-10-2014 |
20140273451 | TUNGSTEN DEPOSITION SEQUENCE - Methods of filling gaps with tungsten are described. The methods include a tungsten dep-etch-dep sequence to enhance gapfilling yet avoid difficulty in restarting deposition after the intervening etch. The first tungsten deposition may have a nucleation layer or seeding layer to assist growth of the first tungsten deposition. Restarting deposition with a less-than-conductive nucleation layer would impact function of an integrated circuit, and therefore avoiding tungsten “poisoning” during the etch is desirable. The etching step may be performed using a plasma to excite a halogen-containing precursor while the substrate at relatively low temperature (near room temperature or less). The plasma may be local or remote. Another method may be used in combination or separately and involves the introduction of a source of oxygen into the plasma in combination with the halogen-containing precursor. | 09-18-2014 |
20140363979 | DIRECTIONAL SIO2 ETCH USING LOW-TEMPERATURE ETCHANT DEPOSITION AND PLASMA POST-TREATMENT - Methods for processing a substrate are described herein. Methods can include positioning a substrate comprising silicon in a processing chamber, delivering a plasma to the surface of the substrate while biasing the substrate, exposing the surface of the substrate to ammonium fluoride (NH | 12-11-2014 |
20150072508 | DIRECTIONAL SIO2 ETCH USING PLASMA PRE-TREATMENT AND HIGH-TEMPERATURE ETCHANT DEPOSITION - Methods for processing a substrate are described herein. Methods can include positioning a substrate with an exposed surface comprising a silicon oxide layer in a processing chamber, biasing the substrate, treating the substrate to roughen a portion of the silicon oxide layer, heating the substrate to a first temperature, exposing the exposed surface of the substrate to ammonium fluoride to form one or more volatile products while maintaining the first temperature, and heating the substrate to a second temperature, which is higher than the first temperature, to sublimate the volatile products. | 03-12-2015 |
20150076110 | BORON IONIZATION FOR ALUMINUM OXIDE ETCH ENHANCEMENT - Embodiments described herein generally provide a method for performing a semiconductor precleaning process. More specifically, embodiments provided herein relate to boron ionization for aluminum oxide etch enhancement. A process for removing native oxide from aluminum may utilize ionized boron alone or in combination with a halogen plasma. The ionized boron may provide improved aluminum oxide etching properties while being highly selective for native oxides more generally. | 03-19-2015 |