Patent application number | Description | Published |
20080286978 | ETCHING AND PASSIVATING FOR HIGH ASPECT RATIO FEATURES - An etch method includes etching a masked substrate to form a recess with a first sidewall in the substrate. A thin surface layer of the substrate on the first sidewall is then converted into a passivation layer. The masked substrate is etched again to deepen the recess in the substrate. A surface layer of the substrate on the second sidewall of the recess is then converted into a passivation layer. In one embodiment, upon removal of the passivation layers from both sidewalls, the first and second sidewalls of the high aspect ratio recess are aligned to within 10 Å of each other to provide a high aspect ratio recess having a vertical profile. | 11-20-2008 |
20090294101 | FAST SUBSTRATE SUPPORT TEMPERATURE CONTROL - Methods and apparatus for controlling the temperature of a substrate support are provided herein. In some embodiments, an apparatus for controlling the temperature of a substrate support may include a first heat transfer loop and a second heat transfer loop. The first heat transfer loop may have a first bath with a first heat transfer fluid at a first temperature. The second heat transfer loop may have a second bath with a second heat transfer fluid at a second temperature. The first and second temperatures may be the same or different. First and second flow controllers may be provided for respectively providing the first and second heat transfer fluids to a substrate support. One or more return lines may couple one or more outlets of the substrate support to the first and second baths for returning the first and second heat transfer fluids to the first and second baths. | 12-03-2009 |
20110045672 | MULTI-FILM STACK ETCHING WITH POLYMER PASSIVATION OF AN OVERLYING ETCHED LAYER - A method and apparatus for plasma etching a workpiece, such as a semiconductor wafer, including a thin film stack having a top film disposed over a bottom film with an intervening middle film there between. Etch selectivity between the top and bottom films may be as low as between 1:1 and 2:1 and a first carbon-lean gas chemistry is used to etch through the top film, a second carbon-lean gas chemistry is used to etch through the middle film, and the bottom film is etched through by alternating between depositing a polymer passivation on the top film using a carbon-rich gas chemistry and an etching of the bottom film with a third carbon-lean gas chemistry, which may be the same as the first carbon-lean gas chemistry. | 02-24-2011 |
20120088371 | METHODS FOR ETCHING SUBSTRATES USING PULSED DC VOLTAGE - Methods for etching substrates using a pulsed DC voltage are provided herein. In some embodiments, a method for method for etching a substrate disposed on a substrate support within a process chamber may include providing a process gas to the process chamber; forming a plasma from the process gas; applying a pulsed DC voltage to a first electrode disposed within the process chamber; and etching the substrate while applying the pulsed DC voltage. | 04-12-2012 |
20140212994 | SELF ALIGNED DUAL PATTERNING TECHNIQUE ENHANCEMENT WITH MAGNETIC SHIELDING - Embodiments of the present disclosure generally provide apparatus and method for improving processing uniformity by reducing external magnetic noises. One embodiment of the present disclosure provides an apparatus for processing semiconductor substrates. The apparatus includes a chamber body defining a vacuum volume for processing one or more substrate therein, and a shield assembly for shielding magnetic flux from the chamber body disposed outside the chamber body, wherein the shield assembly comprises a bottom plate disposed between the chamber body and the ground to shield magnetic flux from the earth. | 07-31-2014 |
20140377959 | METHODS FOR FORMING THREE DIMENSIONAL NAND STRUCTURES ATOP A SUBSTRATE - In some embodiments, methods for forming a three dimensional NAND structure include providing to a process chamber a substrate having alternating nitride layers and oxide layers or alternating polycrystalline silicon consisting layers and oxide layers formed atop the substrate and a photoresist layer formed atop the alternating layers; etching the photoresist layer to expose at least a portion of the alternating layers; providing a process gas comprising sulfur hexafluoride and oxygen to the process chamber; providing RF power of about 4 kW to about 6 kW to a first inductive RF coil and a second inductive RF coil disposed proximate the process chamber to ignite the process gas to form a plasma, wherein a current flowing through the first inductive RF coil is out of phase with RF current flowing through the second inductive RF coil; and etching through a desired number of the alternating layers to form a feature. | 12-25-2014 |
20150031187 | METHODS FOR FORMING A ROUND BOTTOM SILICON TRENCH RECESS FOR SEMICONDUCTOR APPLICATIONS - Embodiments of the present invention provide methods to etching a recess channel in a semiconductor substrate, for example, a silicon containing material. In one embodiment, a method of forming a recess structure in a semiconductor substrate includes transferring a silicon substrate into a processing chamber having a patterned photoresist layer disposed thereon exposing a portion of the substrate, providing an etching gas mixture including a halogen containing gas and a Cl | 01-29-2015 |
20150096959 | METHOD OF MATCHING TWO OR MORE PLASMA REACTORS - Etch rate distributions are captured at a succession of hardware tilt angles of the RF source power applicator relative to the workpiece and their non-uniformities computed, and the behavior is modeled as a non-uniformity function for each one of at least two plasma reactors. An offset Δα in tilt angle α between the non-uniformity functions of the two plasma reactors is detected. The two plasma reactors are then matched by performing a hardware tilt in one of them through a tilt angle equal to the offset Δα. | 04-09-2015 |
20150099314 | PREDICTIVE METHOD OF MATCHING TWO PLASMA REACTORS - Etch rate distribution non-uniformities are predicted for a succession of hardware tilt angles of the RF source applicator relative to the workpiece, and the behavior is modeled as a non-uniformity function for each one of at least two plasma reactors. An offset Δα in tilt angle α between the non-uniformity functions of the two plasma reactors is detected. The two reactors are then matched by performing a hardware tilt in one of them through a tilt angle equal to the offset Δα. | 04-09-2015 |