Abstract: A spot lamp, including a lamp body, a light source, a surface ring and a rotation connector, which is characterized in that the spot lamp includes a main body portion and an adjusting installation portion, which are separable from each other, the main body portion includes the lamp body, the light source and a first magnetic connection portion, and the adjusting installation portion includes the surface ring, the rotation connector and a second magnetic connection portion, the main body portion and the adjusting installation portion are connected by mutual attraction of the first magnetic connection portion and the second magnetic connection portion.

Abstract: A semiconductor processing chamber may include a remote plasma region, and a processing region fluidly coupled with the remote plasma region. The processing region may be configured to house a substrate on a support pedestal. The support pedestal may include a first material at an interior region of the pedestal. The support pedestal may also include an annular member coupled with a distal portion of the pedestal or at an exterior region of the pedestal. The annular member may include a second material different from the first material.

Abstract: A spot lamp, including a lamp body, a light source, a surface ring and a rotation connector, which is characterized in that the spot lamp includes a main body portion and an adjusting installation portion, which are separable from each other, the main body portion includes the lamp body, the light source and a first magnetic connection portion, and the adjusting installation portion includes the surface ring, the rotation connector and a second magnetic connection portion, the main body portion and the adjusting installation portion are connected by mutual attraction of the first magnetic connection portion and the second magnetic connection portion.

Abstract: A semiconductor processing chamber may include a remote plasma region, and a processing region fluidly coupled with the remote plasma region. The processing region may be configured to house a substrate on a support pedestal. The support pedestal may include a first material at an interior region of the pedestal. The support pedestal may also include an annular member coupled with a distal portion of the pedestal or at an exterior region of the pedestal. The annular member may include a second material different from the first material.

Abstract: Exemplary etching methods may include flowing a hydrogen-containing precursor into a semiconductor processing chamber. The methods may include flowing a fluorine-containing precursor into a remote plasma region of the semiconductor processing chamber. The methods may include forming a plasma of the fluorine-containing precursor in the remote plasma region. The methods may include etching a pre-determined amount of a silicon-containing material from a substrate in a processing region of the semiconductor processing chamber. The methods may include measuring a radical density within the remote plasma region during the etching. The methods may also include halting the flow of the hydrogen-containing precursor into the semiconductor processing chamber when the radical density measured over time correlates to a produced amount of etchant to remove the pre-determined amount of the silicon-containing material.

Abstract: Exemplary etching methods may include flowing a hydrogen-containing precursor into a semiconductor processing chamber. The methods may include flowing a fluorine-containing precursor into a remote plasma region of the semiconductor processing chamber. The methods may include forming a plasma of the fluorine-containing precursor in the remote plasma region. The methods may include etching a pre-determined amount of a silicon-containing material from a substrate in a processing region of the semiconductor processing chamber. The methods may include measuring a radical density within the remote plasma region during the etching. The methods may also include halting the flow of the hydrogen-containing precursor into the semiconductor processing chamber when the radical density measured over time correlates to a produced amount of etchant to remove the pre-determined amount of the silicon-containing material.

Abstract: Systems and methods may be used to produce coated components. Exemplary chamber components may include an aluminum, stainless steel, or nickel plate defining a plurality of apertures. The plate may include a hybrid coating, and the hybrid coating may include a first layer comprising a corrosion resistant coating. The first layer may extend conformally through each aperture of the plurality of apertures. The hybrid coating may also include a second layer comprising an erosion resistant coating extending across a plasma-facing surface of the semiconductor chamber component.

Abstract: A method of selectively etching a metal-containing film from a substrate comprising a metal-containing layer and a silicon oxide layer includes flowing a fluorine-containing gas into a plasma generation region of a substrate processing chamber, and applying energy to the fluorine-containing gas to generate a plasma in the plasma generation region. The plasma comprises fluorine radicals and fluorine ions. The method also includes filtering the plasma to provide a reactive gas having a higher concentration of fluorine radicals than fluorine ions, and flowing the reactive gas into a gas reaction region of the substrate processing chamber. The method also includes exposing the substrate to the reactive gas in the gas reaction region of the substrate processing chamber. The reactive gas etches the metal-containing layer at a higher etch rate than the reactive gas etches the silicon oxide layer.

Abstract: The present disclosure provides methods for cleaning chamber components post substrate etching. In one example, a method for cleaning includes activating an etching gas mixture using a plasma to create an activated etching gas mixture, the etching gas mixture comprising hydrogen-containing precursor and a fluorine-containing precursor and delivering the activated etching gas mixture to a processing region of a process chamber, the process chamber having an edge ring positioned therein, the edge ring comprising a catalyst and anticatalytic material, wherein the activated gas removes the anticatalytic material from the edge ring.

Abstract: A method of etching exposed silicon oxide on patterned heterogeneous structures is described and includes a gas phase etch created from a remote plasma etch. The remote plasma excites a fluorine-containing precursor. Plasma effluents from the remote plasma are flowed into a substrate processing region where the plasma effluents combine with water vapor. Reactants thereby produced etch the patterned heterogeneous structures to remove two separate regions of differing silicon oxide at different etch rates. The methods may be used to remove low density silicon oxide while removing less high density silicon oxide.

Abstract: A method of etching exposed silicon on patterned heterogeneous structures is described and includes a gas phase etch using plasma effluents formed in a remote plasma. The remote plasma excites a fluorine-containing precursor. Plasma effluents within the remote plasma are flowed into a substrate processing region where the plasma effluents combine with a hydrogen-containing precursor. The combination react with the patterned heterogeneous structures to remove an exposed silicon portion faster than a second exposed portion. The silicon selectivity results from the presence of an ion suppressor positioned between the remote plasma and the substrate processing region. The methods may be used to selectively remove silicon faster than silicon oxide, silicon nitride and a variety of metal-containing materials. The methods may be used to remove small etch amounts in a controlled manner and may result in an extremely smooth silicon surface.

Abstract: A method of selectively etching silicon nitride from a substrate comprising a silicon nitride layer and a silicon oxide layer includes flowing a fluorine-containing gas into a plasma generation region of a substrate processing chamber and applying energy to the fluorine-containing gas to generate a plasma in the plasma generation region. The plasma comprises fluorine radicals and fluorine ions. The method also includes filtering the plasma to provide a reactive gas having a higher concentration of fluorine radicals than fluorine ions and flowing the reactive gas into a gas reaction region of the substrate processing chamber. The method also includes exposing the substrate to the reactive gas in the gas reaction region of the substrate processing chamber. The reactive gas etches the silicon nitride layer at a higher etch rate than the reactive gas etches the silicon oxide layer.

Abstract: A method of etching patterned heterogeneous silicon-containing structures is described and includes a remote plasma etch with inverted selectivity compared to existing remote plasma etches. The methods may be used to conformally trim polysilicon while removing little or no silicon oxide. More generally, silicon-containing films containing less oxygen are removed more rapidly than silicon-containing films which contain more oxygen. Other exemplary applications include trimming silicon carbon nitride films while essentially retaining silicon oxycarbide. Applications such as these are enabled by the methods presented herein and enable new process flows. These process flows are expected to become desirable for a variety of finer linewidth structures. Methods contained herein may also be used to etch silicon-containing films faster than nitrogen-and-silicon containing films having a greater concentration of nitrogen.

Abstract: A semiconductor processing chamber may include a remote plasma region, and a processing region fluidly coupled with the remote plasma region. The processing region may be configured to house a substrate on a support pedestal. The support pedestal may include a first material at an interior region of the pedestal. The support pedestal may also include an annular member coupled with a distal portion of the pedestal or at an exterior region of the pedestal. The annular member may include a second material different from the first material.

Abstract: The present disclosure provides methods for cleaning chamber components post substrate etching. In one example, a method for cleaning includes activating an etching gas mixture using a plasma to create an activated etching gas mixture, the etching gas mixture comprising hydrogen-containing precursor and a fluorine-containing precursor and delivering the activated etching gas mixture to a processing region of a process chamber, the process chamber having an edge ring positioned therein, the edge ring comprising a catalyst and anticatalytic material, wherein the activated gas removes the anticatalytic material from the edge ring.

Abstract: Methods of selectively etching silicon relative to silicon germanium are described. The methods include a remote plasma etch using plasma effluents formed from a fluorine-containing precursor and a hydrogen-containing precursor. Plasma effluents from the remote plasma are flowed into a substrate processing region where the plasma effluents react with the silicon. The plasmas effluents react with exposed surfaces and selectively remove silicon while very slowly removing other exposed materials. The methods are useful for removing Si(1-X)GeX faster than Si(1-Y)GeY, for X<Y. In some embodiments, the silicon germanium etch selectivity results partly from the presence of an ion suppression element positioned between the remote plasma and the substrate processing region.

Abstract: A method of etching exposed silicon on patterned heterogeneous structures is described and includes a gas phase etch using plasma effluents formed in a remote plasma. The remote plasma excites a fluorine-containing precursor. Plasma effluents within the remote plasma are flowed into a substrate processing region where the plasma effluents combine with a hydrogen-containing precursor. The combination reacts with the patterned heterogeneous structures to remove an exposed silicon portion faster than a second exposed portion. The silicon selectivity results from the presence of an ion suppressor positioned between the remote plasma and the substrate processing region. The methods may be used to selectively remove silicon faster than silicon oxide, silicon nitride and a variety of metal-containing materials. The methods may be used to remove small etch amounts in a controlled manner and may result in an extremely smooth silicon surface.

Abstract: Methods of conditioning interior processing chamber walls of an etch chamber are described. A fluorine-containing precursor may be remotely or locally excited in a plasma to treat the interior chamber walls periodically on a preventative maintenance schedule. The treated walls promote an even etch rate when used to perform gas-phase etching of silicon regions following conditioning. Alternatively, a hydrogen-containing precursor may be remotely or locally excited in a plasma to treat the interior chamber walls in embodiments. Regions of exposed silicon may then be etched with more reproducible etch rates from wafer-to-wafer. The silicon etch may be performed using plasma effluents formed from a remotely excited fluorine-containing precursor.

Abstract: Methods of etching exposed titanium nitride with respect to other materials on patterned heterogeneous structures are described, and may include a remote plasma etch formed from a fluorine-containing precursor. Precursor combinations including plasma effluents from the remote plasma are flowed into a substrate processing region to etch the patterned structures with high titanium nitride selectivity under a variety of operating conditions. The methods may be used to remove titanium nitride at faster rates than a variety of metal, nitride, and oxide compounds.

Abstract: A method of etching exposed silicon on patterned heterogeneous structures is described and includes a gas phase etch using plasma effluents formed in a remote plasma. The remote plasma excites a fluorine-containing precursor. Plasma effluents within the remote plasma are flowed into a substrate processing region where the plasma effluents combine with a hydrogen-containing precursor. The combination react with the patterned heterogeneous structures to remove an exposed silicon portion faster than a second exposed portion. The silicon selectivity results from the presence of an ion suppressor positioned between the remote plasma and the substrate processing region. The methods may be used to selectively remove silicon faster than silicon oxide, silicon nitride and a variety of metal-containing materials. The methods may be used to remove small etch amounts in a controlled manner and may result in an extremely smooth silicon surface.