8891results about "From chemically reactive gases" patented technology

A laminated structure comprises a first layer comprising a crystal with six-fold symmetry, and a second layer comprising a metal oxynitride crystal formed on the first layer, wherein the second layer comprises at least one element selected from the group consisting of In, Ga, Si, Ge and Al, N, O and Zn, as main elements, and wherein the second layer has in-plane orientation.

PCT No. PCT / JP98 / 01640 Sec. 371 Date Dec. 9, 1998 Sec. 102(e) Date Dec. 9, 1998 PCT Filed Apr. 9, 1998 PCT Pub. No. WO98 / 47170 PCT Pub. Date Oct. 22, 1998A method of growing a nitride semiconductor crystal which has very few crystal defects and can be used as a substrate is disclosed. This invention includes the step of forming a first selective growth mask on a support member including a dissimilar substrate having a major surface and made of a material different from a nitride semiconductor, the first selective growth mask having a plurality of first windows for selectively exposing the upper surface of the support member, and the step of growing nitride semiconductor portions from the upper surface, of the support member, which is exposed from the windows, by using a gaseous Group 3 element source and a gaseous nitrogen source, until the nitride semiconductor portions grown in the adjacent windows combine with each other on the upper surface of the selective growth mask.

A bulk-doped semiconductor that is at least one of the following: a single crystal, an elongated and bulk-doped semiconductor that, at any point along its longitudinal axis, has a largest cross-sectional dimension less than 500 nanometers, and a free-standing and bulk-doped semiconductor with at least one portion having a smallest width of less than 500 nanometers. Such a semiconductor may comprise an interior core comprising a first semiconductor; and an exterior shell comprising a different material than the first semiconductor. Such a semiconductor may be elongated and my have, at any point along a longitudinal section of such a semiconductor, a ratio of the length of the section to a longest width is greater than 4:1, or greater than 10:1, or greater than 100:1, or even greater than 1000:1. At least one portion of such a semiconductor may a smallest width of less than 200 nanometers, or less than 150 nanometers, or less than 100 nanometers, or less than 80 nanometers, or less than 70 nanometers, or less than 60 nanometers, or less than 40 nanometers, or less than 20 nanometers, or less than 10 nanometers, or even less than 5 nanometers. Such a semiconductor may be a single crystal and may be free-standing. Such a semiconductor may be either lightly n-doped, heavily n-doped, lightly p-doped or heavily p-doped. Such a semiconductor may be doped during growth. Such a semiconductor may be part of a device, which may include any of a variety of devices and combinations thereof, and, and a variety of assembling techniques may be used to fabricate devices from such a semiconductor. Two or more of such a semiconductors, including an array of such semiconductors, may be combined to form devices, for example, to form a crossed p-n junction of a device. Such devices at certain sizes may exhibit quantum confinement and other quantum phenomena, and the wavelength of light emitted from one or more of such semiconductors may be controlled by selecting a width of such semiconductors. Such semiconductors and device made therefrom may be used for a variety of applications.

A process for depositing a silicon-based material on a substrate uses the technology of plasma-enhanced atomic layer deposition. The process is carried out over several cycles, wherein each cycle includes: exposing the substrate to a first precursor, which is an organometallic silicon precursor; and applying a plasma of at least a second precursor, different from the first precursor. Semiconductor products such as 3D capacitors, vertical transistor gate spacers, and conformal transistor stressors are made from the process.

Embodiments of the invention generally provide a method for depositing films or layers using a UV source during a photoexcitation process. The films are deposited on a substrate and usually contain a material, such as silicon (e.g., epitaxy, crystalline, microcrystalline, polysilicon, or amorphous), silicon oxide, silicon nitride, silicon oxynitride, or other silicon-containing materials. The photoexcitation process may expose the substrate and / or gases to an energy beam or flux prior to, during, or subsequent a deposition process. Therefore, the photoexcitation process may be used to pre-treat or post-treat the substrate or material, to deposit the silicon-containing material, and to enhance chamber cleaning processes. Attributes of the method that are enhanced by the UV photoexcitation process include removing native oxides prior to deposition, removing volatiles from deposited films, increasing surface energy of the deposited films, increasing the excitation energy of precursors, reducing deposition time, and reducing deposition temperature.

In one implementation, a substrate susceptor for receiving a semiconductor substrate for selective epitaxial silicon-comprising depositing thereon, where the depositing comprises measuring emissivity of the susceptor from at least one susceptor location in a non-contacting manner, includes a body having a front substrate receiving side, a back side, and a peripheral edge. At least one susceptor location from which emissivity is to be measured is received on at least one of the front substrate receiving side, the back side, and the edge. Such at least one susceptor location comprises an outermost surface comprising a material upon which selective epitaxial silicon will not deposit upon during selective epitaxial silicon depositing on a semiconductor substrate received by the susceptor for at least an initial thickness of epitaxial silicon depositing on said substrate. Other aspects and implementations are contemplated.

One or more highly-oriented, multi-walled carbon nanotubes are grown on an outer surface of a substrate initially disposed with a catalyst film or catalyst nano-dot by plasma enhanced hot filament chemical vapor deposition of a carbon source gas and a catalyst gas at temperatures between 300° C. and 3000° C. The carbon nanotubes range from 4 to 500 nm in diameter and 0.1 to 50 μm in length depending on growth conditions. Carbon nanotube density can exceed 104 nanotubes / mm2. Acetylene is used as the carbon source gas, and ammonia is used as the catalyst gas. Plasma intensity, carbon source gas to catalyst gas ratio and their flow rates, catalyst film thickness, and temperature of chemical vapor deposition affect the lengths, diameters, density, and uniformity of the carbon nanotubes. The carbon nanotubes of the present invention are useful in electrochemical applications as well as in electron emission, structural composite, material storage, and microelectrode applications.

A method of and apparatus for providing tunable gas injection in a plasma processing system (10, 10′). The apparatus includes a gas injection manifold (50) having a pressurizable plenum (150) and an array of adjustable nozzle units (250), or an array of non-adjustable nozzles (502, 602), through which gas from the plenum can flow into the interior region (40) of a plasma reactor chamber (14) capable of containing a plasma (41). The adjustable nozzle units include a nozzle plug (160) arranged within a nozzle bore (166). A variety of different nozzle units are disclosed. The nozzle plugs are axially translatable to adjust the flow of gas therethrough. In one embodiment, the nozzle plugs are attached to a plug plate (154), which is displacable relative to an injection plate (124) via displacement actuators (170) connecting the two plates. The displacement actuators are controlled by a displacement actuator control unit (180), which is in electronic communication with a plasma processing system control unit (80). The gas flow into the chamber interior region is preferably controlled by monitoring the pressure in the plenum and in the chamber and adjusting the nozzle units accordingly. Where the nozzle units are not adjustable, a portion of the nozzles are sized to a first flow condition, and another portion of the nozzles are sized to a second flow condition.

Thin films are formed by formed by atomic layer deposition, whereby the composition of the film can be varied from monolayer to monolayer during cycles including alternating pulses of self-limiting chemistries. In the illustrated embodiments, varying amounts of impurity sources are introduced during the cyclical process. A graded gate dielectric is thereby provided, even for extremely thin layers. The gate dielectric as thin as 2 nm can be varied from pure silicon oxide to oxynitride to silicon nitride. Similarly, the gate dielectric can be varied from aluminum oxide to mixtures of aluminum oxide and a higher dielectric material (e.g., ZrO2) to pure high k material and back to aluminum oxide. In another embodiment, metal nitride (e.g., WN) is first formed as a barrier for lining dual damascene trenches and vias. During the alternating deposition process, copper can be introduced, e.g., in separate pulses, and the copper source pulses can gradually increase in frequency, forming a transition region, until pure copper is formed at the upper surface. Advantageously, graded compositions in these and a variety of other contexts help to avoid such problems as etch rate control, electromigration and non-ohmic electrical contact that can occur at sharp material interfaces. In some embodiments additional seed layers or additional transition layers are provided.

An atomic deposition (ALD) thin film deposition apparatus includes a deposition chamber configured to deposit a thin film on a wafer mounted within a space defined therein. The deposition chamber comprises a gas inlet that is in communication with the space. A gas system is configured to deliver gas to the gas inlet of the deposition chamber. At least a portion of the gas system is positioned above the deposition chamber. The gas system includes a mixer configured to mix a plurality of gas streams. A transfer member is in fluid communication with the mixer and the gas inlet. The transfer member comprising a pair of horizontally divergent walls configured to spread the gas in a horizontal direction before entering the gas inlet.

Metal organic chemical vapor deposition equipment is metal organic chemical vapor deposition equipment for forming a film on a substrate by using a reactant gas, and includes a susceptor heating the substrate and having a holding surface for holding the substrate, and a flow channel for introducing the reactant gas to the substrate. The susceptor is rotatable with the holding surface kept facing an inner portion of the flow channel, and a height of the flow channel along a flow direction of the reactant gas is kept constant from a position to a position, and is monotonically decreased from the position to the downstream side. It is thereby possible to improve film formation efficiency while allowing the formed film to have a uniform thickness.

The present invention generally provides apparatus and method for forming a clean and damage free surface on a semiconductor substrate. One embodiment of the present invention provides a system that contains a cleaning chamber that is adapted to expose a surface of substrate to a plasma cleaning process prior to forming an epitaxial layer thereon. In one embodiment, a method is employed to reduce the contamination of a substrate processed in the cleaning chamber by depositing a gettering material on the inner surfaces of the cleaning chamber prior to performing a cleaning process on a substrate. In one embodiment, oxidation and etching steps are repeatedly performed on a substrate in the cleaning chamber to expose or create a clean surface on a substrate that can then have an epitaxial placed thereon. In one embodiment, a low energy plasma is used during the cleaning step.

A solid organometallic compound novel filled container stably supplies an apparatus for vapor phase epitaxial growth such as an MOCVD apparatus with a solid organometallic compound over a long term. The solid organometallic compound-filled container has a carrier gas inlet and a carrier gas outlet. The interior of the filled container is separated into a plurality of vertical compartments. A carrier gas introduced via the carrier gas inlet flows through each of the vertical compartments and is then discharged via the carrier gas outlet.

A method of growing a thin film on a substrate by pulsing vapor-phase precursors material into a reaction chamber according to the ALD method. The method comprises vaporizing at least one precursor from a source material container maintained at a vaporising temperature, repeatedly feeding pulses of the vaporized precursor via a feed line into the reaction chamber at a first pressure, and subsequently purging the reaction chamber with pulses of inactive gas fed via the feed line at a second pressure. The second pressure is maintained at the same as or a higher level than the first pressure for separating successive pulses of said vaporized precursor from each other.

A susceptor at least a surface thereof being coated with SiC, includes a recess where an wafer is mounted, the recess having an round portion disposed on a lower portion of an outer circumferential portion of the recess, a ring-shaped SiC crystal growth surface portion provided within the round portion in a range of 0.05 mm or more and 0.3 mm or less defined from an outer circumference vertical portion of the recess and a contact portion, where the susceptor contacts with the wafer on the recess, having a surface roughness Ra in a range of 0.5 μm or more and 3 μm or less.

A novel filled container is provided, which can stably supply an apparatus for vapor phase epitaxial growth such as an MOCVD apparatus with a solid organometallic compound over a long term. The solid organometallic compound-filled container has a carrier gas inlet and a carrier gas outlet. The interior of the filled container is separated into a plurality of vertical compartments. A carrier gas introduced via the carrier gas inlet flows through each of the vertical compartments and is then discharged via the carrier gas outlet.

A semiconductor manufacturing apparatus A semiconductor manufacturing apparatus comprises a hot plate which heats a sapphire substrate; a support table having a support plate disposed with being spaced away from the hot plate by a predetermined interval, and support portions which respectively support the sapphire substrate with being spaced by a predetermined interval between the hot plate and the support plate and support the sapphire substrate in such a manner that back surfaces of the hot plate and the sapphire substrate are opposite to each other; an elevating device which moves the support table up and down; and a shielding cover which externally blocks off spacing defined between the hot plate and the sapphire substrate and spacing defined between the sapphire substrate and the support plate.

A process for depositing polycrystalline silicon on substrates, including foreign substrates, occurs in a chamber at about atmospheric pressure, wherein a temperature gradient is formed, and both the atmospheric pressure and the temperature gradient are maintained throughout the process. Formation of a vapor barrier within the chamber that precludes exit of the constituent chemicals, which include silicon, iodine, silicon diiodide, and silicon tetraiodide. The deposition occurs beneath the vapor barrier. One embodiment of the process also includes the use of a blanketing gas that precludes the entrance of oxygen or other impurities. The process is capable of repetition without the need to reset the deposition zone conditions.

An atomic layer deposition (ALD) apparatus capable of forming a conformal ultrathin-film layer with enhanced step coverage is disclosed. The apparatus includes an ALD reactor supporting therein a wafer, and a main pipe coupled thereto for constant supply of a carrier gas. This pipe has two parallel branch pipes. Raw material sources are connected by three-way valves to one branch pipe through separate pipes, respectively. Similarly, oxidant / reducer sources are coupled by three-way valves to the other branch pipe via independent pipes. ALD works by introducing one reactant gas at a time into the reactor while being combined with the carrier gas. The gas is “chemisorped” onto the wafer surface, creating a monolayer deposited. During the supply of a presently selected material gas from its source to a corresponding branch pipe, this gas passes through its own pipe independently of the others. An ALD method is also disclosed.

Disclosed are methods for growing Sn-containing semiconductor materials. In some embodiments, an example method includes providing a substrate in a chemical vapor deposition (CVD) reactor, and providing a semiconductor material precursor, a Sn precursor, and a carrier gas in the CVD reactor. The method further includes epitaxially growing a Sn-containing semiconductor material on the substrate, where the Sn precursor comprises tin tetrachloride (SnCl4). The semiconductor material precursor may be, for example, digermane, trigermane, higher-order germanium precursors, or a combination thereof. Alternatively, the semiconductor material precursor may be a silicon precursor.

An apparatus used for an epitaxial vapor growing arrangement and for detecting whether a wafer is properly seated within a susceptor contained therein. The apparatus includes a semiconductor laser element that generates a laser beam which irradiates the wafer's surface. The apparatus, further, includes a combination of a stop mechanism, a condenser lens and a photo diode, which detects the laser beam reflected from the wafer surface and an operation circuit, which determines the wafer's posture on the susceptor. During operation, the reflected laser beam focuses on a receiving surface of the photo diode through the condenser lens. The operation circuit then compares the output signal from the photo diode with a preset reference value for discriminating the slope of the wafer.

Embodiments of the invention generally provide a method for depositing films or layers using a UV source during a photoexcitation process. The films are deposited on a substrate and usually contain a material, such as silicon (e.g., epitaxy, crystalline, microcrystalline, polysilicon, or amorphous), silicon oxide, silicon nitride, silicon oxynitride, or other silicon-containing materials. The photoexcitation process may expose the substrate and / or gases to an energy beam or flux prior to, during, or subsequent a deposition process. Therefore, the photoexcitation process may be used to pre-treat or post-treat the substrate or material, to deposit the silicon-containing material, and to enhance chamber cleaning processes. Attributes of the method that are enhanced by the UV photoexcitation process include removing native oxides prior to deposition, removing volatiles from deposited films, increasing surface energy of the deposited films, increasing the excitation energy of precursors, reducing deposition time, and reducing deposition temperature.

A method and apparatus that may be utilized for chemical vapor deposition and / or hydride vapor phase epitaxial (HVPE) deposition are provided. In one embodiment, the apparatus is a processing chamber that includes a showerhead with separate inlets and channels for delivering separate processing gases into a processing volume of the chamber without mixing the gases prior to entering the processing volume. In one embodiment, the showerhead includes metrology ports with purge gas assemblies configured and positioned to deliver a purge gas to prevent deposition thereon. In one embodiment, the metrology port is configured to receive a temperature measurement device, and the purge gas assembly is a concentric tube configuration configured to prevent deposition on components of the temperature measurement device. In one embodiment, the metrology port has a sensor window and is configured to receive an optical measurement device, and the purge gas assembly and sensor window are configured to prevent deposition on the sensor window.

Improved apparatus and method for SMFD ALD include a method designed to enhance chemical utilization as well as an apparatus that implements lower conductance out of SMFD-ALD process chamber while maintaining full compatibility with standard wafer transport. Improved SMFD source apparatuses (700, 700′, 700″) and methods from volatile and non-volatile liquid and solid precursors are disclosed, e.g., a method for substantially controlling the vapor pressure of a chemical source (722) within a source space comprising: sensing the accumulation of the chemical on a sensing surface (711); and controlling the temperature of the chemical source depending on said sensed accumulation.

Embodiments of the invention generally relate to methods for forming silicon-germanium-tin alloy epitaxial layers, germanium-tin alloy epitaxial layers, and germanium epitaxial layers that may be doped with boron, phosphorus, arsenic, or other n-type or p-type dopants. The methods generally include positioning a substrate in a processing chamber. A germanium precursor gas is then introduced into the chamber concurrently with a stressor precursor gas, such as a tin precursor gas, to form an epitaxial layer. The flow of the germanium gas is then halted, and an etchant gas is introduced into the chamber. An etch back is then performed while in the presence of the stressor precursor gas used in the formation of the epitaxial film. The flow of the etchant gas is then stopped, and the cycle may then be repeated. In addition to or as an alternative to the etch back process, an annealing processing may be performed.