Abstract: The present invention discloses a method of forming a titanium nitride (TiN) thin film on a substrate disposed on a susceptor in a reaction chamber with low carbon content, low resistivity, and excellent step coverage. The method forming the TiN thin film includes feeding vapor of a Tetrakis Diethylamino Titanium (TDEAT) precursor and ammonia (NH3) gas into the reaction chamber, wherein a ratio of a vaporization rate of the TDEAT precursor to a flow rate of the ammonia gas is a value in the range of 1 mg/min:20 sccm to 1 mg/min:100 sccm; maintaining an atmosphere in the reaction chamber at a pressure in the range of 0.5 to 3.0 Torr; and heating the substrate to a temperature in the range of 300 to 400 degrees Celsius (° C.).

Abstract: A process for chemical vapor deposition includes depositing a film using a metal &bgr;-diketonate complex and an &agr;, &bgr;-unsaturated alcohol. The metal &bgr;-diketonate complex and the &agr;, &bgr;-unsaturated alcohol is contacted on the substrate at the same time, at different times or alternately.

Abstract: An improved gas precursor delivery system for a deposition chamber is disclosed. The system includes, in a preferred embodiment, a shower head containing holes through which the gas precursors will be delivered to the deposition chamber. Each hole within the shower head has associated with it a flow regulating micromachine, such as a microvalve or micropump, for independently regulating the flow of the precursor into the deposition chamber, and if necessary, for vaporizing the source chemical. Each micromachine is preferably associated with a single precursor source, and hence precursor lines are not shared and thus do not need to be purged with the introduction of each new precursor, saving manufacturing time and decreasing wasted precursor gas. Precise control of precursors into the chamber via the micromachines allows film stochiometry and thickness to be carefully controlled.

Abstract: A method is provided for making transparent articles utilizing protective layers for optical coatings. An optical coating on a transparent substrate is provided with a temporary layer of carbon as protection during manufacturing against scratches and corrosive environments. When the optical coating and/or substrate are tempered in an atmosphere reactive to carbon, such as air, the layer of carbon is removed as a carbon-containing gas. For an optical coating with a brittle, glassy, outermost layer furthest from the substrate, additional protection is provided by a scratch propagation blocker layer between the outermost layer and the carbon protective layer.

Abstract: This invention concerns a method for modifying a source material used in an ALD process, a method for depositing transition metal nitride thin films by an ALD process and apparatus for use in such process. According to the present invention transition metal source materials are reduced by vaporizing a metal source material, conducting the vaporized metal source material, into a reducing zone comprising a solid reducing agent maintained at an elevated temperature. Thereafter, the metal source material is contacted with the solid or liquid reducing agent in order to convert the source material into a reduced metal compound and reaction byproducts having a sufficiently high vapor pressure for transporting in gaseous form.

Abstract: A process for the deposition of thin layers by chemical vapor deposition includes adding an effective amount of nitroxyl radicals of the formula to a gas stream including the materials to be deposited. In this formula, R1 and R2 are identical or different alkyl, alkenyl, alkynyl, acyl, or aryl radicals, with or without heteroatoms. R1 and R2 can also together form a structure —CR3R4—CR5R6—CR7R8—CR9R10—CR11R12—, where R3, R4, R5, R6, R7, R8, R9, R10, R11, R12 are again identical or different alkyl, alkenyl, alkynyl, acyl, or aryl radicals, with or without heteroatoms.

Abstract: A method of forming a pyrolytic boron nitride (PBN) article and an article having layers of PBN separated by layers of PBN having a dopant of sufficient concentration to induce peeling, the steps of introducing vapors of ammonia and a gaseous boron halide in a suitable ratio into a heated furnace reactor to cause boron nitride to be deposited in layers on a substrate, with at least one gaseous dopant injected into furnace at controlled periodic interval(s) such that at least two selected layers of boron nitride are doped with said gaseous dopant(s) at a minimum average concentration of 0.1 atomic wt % at a depth ranging from 1000 to 2000 angstroms in each selected layer, and with the selected layers spaced apart about 0.1 micron to 100 microns.

Abstract: Integrated circuits are generally built layer by layer on a substrate. One technique for forming layers is chemical vapor deposition (CVD.) This technique injects gases through a gas-dispersion fixture, such as a showerhead, into a chamber. The gases react and blanket a substrate in the chamber with a layer of material. One method of promoting uniform layer thickness is to coat the gas-dispersion fixture with a uniform layer of the material before using the fixture for deposition on the substrate. However, conventional fixture-coating techniques yield uneven or poorly adherent coatings. Accordingly, the inventor devised new methods for coating these fixtures. One exemplary method heats a fixture to a temperature greater than its temperature during normal deposition and then passes one or more gases through the fixture to form a coating on it. The greater conditioning temperature improves evenness and adhesion of the fixture coating, which, in turn, produces higher quality layers in integrated circuits.

Abstract: A method of forming a silicon nitride film is described. According to the present invention, a silicon nitride film is deposited by thermally decomposing a silicon/nitrogen containing source gas or a silicon containing source gas and a nitrogen containing source gas at low deposition temperatures (e.g., less than 550° C.) to form a silicon nitride film. The thermally deposited silicon nitride film is then treated with hydrogen radicals to form a treated silicon nitride film.

Abstract: A plasma 10 is generated within a film formation chamber 2, and mainly a nitrogen gas 11 is excited within the film formation chamber 2. Then, the excited nitrogen gas 11 is mixed with a diborane gas 13 diluted with a hydrogen gas to react them, thereby forming a boron nitride film 15 on a substrate 4. At the initial stage of film formation, the nitrogen gas 11 is supplied in excess to suppress the occurrence of an amorphous phase on the interface. As a result, the boron nitride film 15 improved in moisture absorption resistance on the interface with the substrate and maintaining low dielectric constant properties is formed.

Abstract: The invention relates to a method for manufacture of a semiconductor component by the formation of a hydrogenous layer containing silicon on a substrate comprising or containing silicon such as a wafer or film. In order to achieve a good surface and volume passivation, it is proposed that during formation of the siliceous layer in the form of SiNxOy with 0<x≦1.5 and 0≦y≦2 one or more catalytically acting dopants are selectively added into the layer which release hydrogen from the SiNxOy layer. The concentration C of the dopants is 1×1014 cm3≦C≦1021 cm3.

Abstract: The present invention provides a method and precursor for forming a metal and/or metal nitride layer on the substrate by chemical vapor deposition. The organometallic precursor has the formula of (Cp(R)n)xMHy−x, where Cp is a cyclopentadienyl functional group, R is a substituent on the cyclopentadienyl functional group comprising an organic group having at least one carbon-silicon bond, n is an integer from 0 to 5, x is an integer from 1 to 4, M is a metal, and y is the valence of the metal M. A metal, metal nitride, metal carbon nitride, or metal silicon nitride film is deposited on a heated substrate by thermal or plasma enhanced decomposition of the organometallic precursor in the presence of a processing gas, such as hydrogen, nitrogen, ammonia, silane, and combinations thereof, at a pressure of less than about 20 Torr. By controlling the reactive gas composition either metal or metal nitride films may be deposited.

Abstract: A coating for a handpiece (1) for dental-medical or surgical purposes consists of a hard material layer (11) having a predetermined roughness and of a plastics layer (12), having a reduced wettability, arranged on the hard material layer (11). Through this there is obtained a dirt repellent surface. At the same time handling is improved, since a slipping of the handpiece is avoided.

Abstract: Method for producing cutting tools provides a first hard material coating on a first region of a tool base body containing at least one cutting edge, using a plasma vacuum coating process. A second hard material coating is provided on a second region which is adjacent the first, also via plasma vacuum coating process. Hard material for the coatings is a carbide, oxide, oxicarbide, nitride, nitrocarbide, oxinitride or nitrooxicarbide of at least two of Ti, Zr, Hf, V, Nb, Ta, Cr, Mo, W, Al. The first coating has a content of at least two of the metal elements which is at most 2 at % different from the content of the two metal elements in the second coating if the tool is for higher adhesive strength than hardness. The first coating has a content of the two metal elements that is different from the content of the two metal elements of the second coating by more than 2 at % if the tool is for higher hardness than high adhesive strength.

Abstract: A coated cemented carbide excellent in peel strength includes a cemented carbide substrate comprising a hard phase containing tungsten carbide and a binder phase, and a hard film being provided on a surface of the substrate with a single layer or two or more laminated layers, wherein (1) at least part of the surface of the substrate is subjected to machining, and (2)(i) substantially no crack is present in particles of the hard phase existing at an interface of the surface of the substrate subjected to machining and the hard film and/or (2)(ii) peak intensities of crystal surfaces satisfy hs(001)wc/hs(101)wc≧1.1×hi(001)wc/hi(101)wc wherein hs(001)wc and hs(101)wc each represent a peak intensity of (001) crystal face and that of (101) crystal face at the surface of the substrate subjected to machining processing, respectively, and hi(001)wc and hi(101)wc each represent a peak intensity of (001) crystal face and that of (101) crystal face in the substrate, respectively.

Abstract: Embodiments of the invention relate to an apparatus and method of depositing a titanium silicon nitride layer by cyclical deposition. In one aspect, a titanium silicon nitride layer having a variable content or a controlled composition of titanium, silicon, and nitrogen through the depth of the layer may be formed. One embodiment of this variable content titanium silicon nitride layer or tuned titanium silicon nitride layer includes a bottom sub-layer of TiSiX1NY1, a middle sub-layer of TiSiX2NY2, and a top sub-layer of TiSiX3NY3 in which X1 is less than X2 and X3 is less than X2. Another embodiment of a variable content titanium silicon nitride layer includes a bottom sub-layer of TiSiX1NY1 and a top sub-layer of TiSiX2NY2 in which X2 is greater than X1. Still another embodiment of a variable content titanium silicon nitride layer includes a bottom sub-layer of TiSiX1NY1, a middle sub-layer of TiSiX2NY2, and a top sub-layer of TiSiX3NY3 in which X1 is greater than X2 and X3 is greater than X2.

Abstract: A conventional cutting tool is provided and a cutting edge of that tool is formed and/or sharpened. A relatively hard layer is applied over at least a portion of the cutting tool that includes the cutting edge and then a friction-reducing layer is applied over the hard layer. The entire coated cutting tool, or at least a portion of the coated cutting tool that includes the cutting edge, is cryogenically treated. The coated and cryogenically treated cutting tool is mounted in a conventional manner to a conventional cutting machine, and then used cut articles containing at least a substantial amount of wood.

Abstract: An oxide and an oxynitride films and their methods of fabrication are described. The oxide or the oxynitride film is grown on a substrate that is placed in a deposition chamber. A silicon source gas (or a silicon source gas with a nitridation source gas) and an oxidation source gas are decomposed in the deposition chamber using a thermal energy source. A silicon oxide (or an oxynitride) film is formed above the substrate wherein total pressure for the deposition chamber is maintained in the range of 50 Torr to 350 Torr and wherein a flow ratio for the silicon source gas (or the silicon source gas with the nitridiation source gas) and the oxidation source gas is in the range of 1:50 to 1:10000 during a deposition process.

Abstract: A substrate is set on a susceptor installed in a reactor and arranged horizontally. A cooling jacket is provided at a portion of the inner wall of the reactor that is opposite to the substrate. By flowing a given cooling medium through the cooling jacket with a pump connected to the jacket, at least the opposite portion of the inner wall is cooled down, which inhibits the reaction between raw material gases introduced into the reactor. As a result, in fabricating a III-V nitride film, the film growth rate is developed and the crystal quality is developed.

Abstract: Methods for producing metal nitride thin layers having low resistivity by means of atomic layer deposition processes comprising alternate surface reactions of metal and nitrogen source materials include using nitrogen source materials that have better reducing properties than ammonia and 1,1-dimethyl hydrazine. Suitable compounds for that purpose include those in which a hydrocarbon group bound to nitrogen, when dissociating in a homolytic manner, generates a radical that serves as a reducing agent and reacts further to generate atomic hydrogen. The nitride thin layers produced are especially suitable for use as diffusion barrier layers in integrated circuits.

Abstract: A surface treatment method in which a surface of a part (7) is contacted with at least one activated species. The activated species is obtained by activating a gaseous medium containing at least two of the following elements: carbon, nitrogen, boron and oxygen. Preferably, the activated species is a neutral excited CN species. The activated species brings at least one interstitial element to the metal part (7) surface which is borne and maintained at a temperature enabling the interstitial element to be diffused into a surface layer of the metal part (7).

Abstract: Metal silicates or phosphates are deposited on a heated substrate by the reaction of vapors of alkoxysilanols or alkylphosphates along with reactive metal amides, alkyls or alkoxides. For example, vapors of tris-(ter-butoxy)silanol react with vapors of tetrakis(ethylmethylamido)hafnium to deposit hafnium silicate on surfaces heated to 300 ° C. The product film has a very uniform stoichiometry throughout the reactor. Similarly, vapors of diisopropylphosphate react with vapors of lithium bis(ethyldimethylsilyl)amide to deposit lithium phosphate films on substrates heated to 250 ° C. supplying the vapors in alternating pulse produces these same compositions with a very uniform distribution of thickness and excellent step coverage.

Abstract: A method of forming (and apparatus for forming) tantalum suicide layers (including tantalum silicon nitride layers), which are typically useful as diffusion barrier layers, on a substrate by using a vapor deposition process with a tantalum halide precursor compound, a silicon precursor compound, and an optional nitrogen precursor compound.

Abstract: The construction of a film on a wafer, which is placed in a processing chamber, may be carried out through the following steps. A layer of material is deposited on the wafer. Next, the layer of material is annealed. Once the annealing is completed, the material may be oxidized. Alternatively, the material may be exposed to a silicon gas once the annealing is completed. The deposition, annealing, and either oxidation or silicon gas exposure may all be carried out in the same chamber, without need for removing the wafer from the chamber until all three steps are completed. A semiconductor wafer processing chamber for carrying out such an in-situ construction may include a processing chamber, a showerhead, a wafer support and a rf signal means. The showerhead supplies gases into the processing chamber, while the wafer support supports a wafer in the processing chamber.

Abstract: A method for depositing a film on a substrate is provided. In one aspect, the method includes providing a metal-containing precursor to an activation zone, and activating the metal-containing precursor to form an activated precursor. The activated precursor gas is transported to a reaction chamber, and a film is deposited on the substrate using a cyclical deposition process, wherein the activated precursor gas and a reducing gas are alternately adsorbed on the substrate. Also provided is a method of depositing a film on a substrate using an activated reducing gas.

Abstract: Methods of depositing titanium nitride (TiN) films on a substrate are disclosed. The titanium nitride (TiN) films may be formed using a cyclical deposition process by alternately adsorbing a titanium-containing precursor and a NH3 gas on the substrate. The titanium-containing precursor and the NH3 gas react to form the titanium nitride (TiN) layer on the substrate. The titanium nitride (TiN) films are compatible with integrated circuit fabrication processes. In one integrated circuit fabrication process, an interconnect structure is fabricated. The titanium nitride films may also be used as an electrode of a three-dimensional capacitor structure such as for example, trench capacitors and crown capacitors.

Abstract: A method for forming thin films of a semiconductor device is provided. The thin film formation method presented here is based upon a time-divisional process gas supply in a chemical vapor deposition (CVD) method, where the process gases are supplied and purged sequentially, and additionally plasma is generated in synchronization with the cycle of pulsing reactant gases. A method of forming thin films that possess a property of gradient composition profile is also presented.

Abstract: Method and apparatus are provided for forming metal nitrides (MN) wherein M is contacted with iodine vapor or hydrogen iodide (HI) vapor to form metal iodide (MI) and contacting MI with ammonia to form the MN in a process of reduced or no toxicity. MN is then deposited on a substrate, on one or more seeds or it can self nucleate on the walls of a growth chamber, to form high purity metal nitride material. The inventive MN material finds use in semiconductor materials and in making nitride electronic devices as well as other uses.

Abstract: A method of forming a film by a plasma CVD process in which a high density plasma is generated in the presence of a magnetic field wherein the electric power for generating the plasma has a pulsed waveform. The electric power typically is supplied by microwave, and the pulsed wave may be a complex wave having a two-step peak, or may be a complex wave obtained by complexing a pulsed wave with a stationary continuous wave.

Abstract: A method of forming a coated body having a nanocrystalline CVD coating of Ti(C,N,O) is disclosed. The coating is formed using the MTCVD process and including, as part of the gaseous mixture, CO, CO2 or mixtures therof. The use of this dopant during the coating results in a much smaller, equiaxed grain size.

Abstract: The present invention provides for sequential chemical vapor deposition by employing a reactor operated at low pressure, a pump to remove excess reactants, and a line to introduce gas into the reactor through a valve. A first reactant forms a monolayer on the part to be coated, while the second reactant passes through a radical generator which partially decomposes or activates the second reactant into a gaseous radical before it impinges on the monolayer. This second reactant does not necessarily form a monolayer but is available to react with the monolayer. A pump removes the excess second reactant and reaction products completing the process cycle. The process cycle can be repeated to grow the desired thickness of film.

Abstract: Embodiments of the present invention relate to methods and apparatus for depositing a silicon nitride film. More particularly, embodiments of the present invention relate to methods and apparatus for depositing a silicon nitride film by cyclical layer deposition. One method for depositing a silicon nitride film generally comprises separately introducing one or more pulses of a nitrogen precursor and one or more pulses of a silicon precursor to a region adjacent to the substrate surface. A portion of the pulses of the nitrogen precursor and a portion of the pulses of the silicon precursor are present together at the region adjacent the substrate surface. Another embodiment for depositing a silicon nitride film comprises dosing a continuous flow of a purge gas with at least one pulse of a silicon precursor and at least one pulse of a nitrogen precursor. Each pulse of the silicon precursor and the nitrogen precursor is provided for a time period between about 0.01 seconds and about 2.0 seconds.

Abstract: A showerhead adapted for distributing gases into a process chamber and a method for forming dielectric layers on a substrate are generally provided. In one embodiment, a showerhead for distributing gases in a processing chamber includes an annular body coupled between a disk and a mounting flange. The disk has a plurality of holes formed therethrough. A lip extends from a side of the disk opposite the annular body and away from the mounting flange. The showerhead may be used for the deposition of dielectric materials on a substrate. In one embodiment, silicon nitride and silicon oxide layers are formed on the substrate without removing the substrate from a processing chamber utilizing the showerhead of the present invention.

Abstract: Processes for producing tungsten nitride and tungsten nitride films are provided in which a tungsten carbonyl compound and a nitrogen-containing reactant gas are reacted at a temperature below about 600° C. Tungsten nitride precursors are also included which comprise a tungsten carbonyl compound capable of forming a tungsten nitride film in the presence of a nitrogen-containing reactant gas at a temperature of less than about 600° C.

Abstract: The present invention is to provide a silicon nitride film forming apparatus and a forming method which makes possible the high reproducibility of film quality or film thickness. The silicon nitride film forming apparatus and forming method in which a heating element and a substrate are arranged in a vacuum vessel connected to a gas exhaust system and a gas supply system to deposit a silicon nitride film on the substrate surface by maintaining the heating element at a predetermined temperature and by decomposing and/or activating a raw material gas supplied from the gas supply system, comprises: an inner wall which is arranged in the vacuum vessel surrounding the heating element and the substrate so as to form a film formation space, a gas introduction means to introduce the raw material gas to the film forming space, and at least one of a heating means and a cooling means of the inner wall arranged to control the inner wall to a predetermined temperature.

Abstract: The present invention provides a method for making a superabrasive composite material having the general formula SixCyNz, and tools containing such a material. In one aspect, vapor forms of Si, C, and N elements are deposited onto a molten metal catalyst and solid SixCyNz is precipitated therefrom.

Abstract: A method of making a cutting tool, the cutting tool having a WC—Co based cemented carbide body and a multi-layer coating, the method including: applying a first innermost bonding layer TiN to the body; applying a second layer in the form of a multilayered structure having sublayers of (TixAl1-x)N where x varies according to 0.45<x<0.55 and 0.70<x<0.80; applying a third layer of (TixAl1-x)N where x is 0.45<x<0.55; and applying a forth outermost layer on TiN.

Abstract: The present invention provides a method of depositing an amorphous fluorocarbon film using a high bias power applied to the substrate on which the material is deposited. The invention contemplates flowing a carbon precursor at rate and at a power level so that equal same molar ratios of a carbon source is available to bind the fragmented fluorine in the film thereby improving film quality while also enabling improved gap fill performance. The invention further provides for improved adhesion of the amorphous fluorocarbon film to metal surfaces by first depositing a metal or TiN adhesion layer on the metal surfaces and then stuffing the surface of the deposited adhesion layer with nitrogen. Adhesion is further improved by coating the chamber walls with silicon nitride or silicon oxynitride.

Abstract: A method for producing a material selected from the group consisting of metal oxide, metal oxynitride and mixtures thereof on a substrate, comprising; reacting a first reactant selected from the group consisting of (R1R2N)xM(═NR3)y, (R4R5N)xM[&eegr;2—R6N═C (R7)(R8)]y and mixtures thereof with an oxidant and up to 95 volume percent of a source of nitrogen selected from the group consisting of ammonia, N2O, NO, NO2, alkyl amines, N2H2, alkyl hydrazine, N2 and mixtures thereof, to produce said material on said substrate, where R1, R2, R3, R4, R5, R6, R7 and R8 are individually C1-6 alkyl, aryl or hydrogen, M═Ta, Nb, W or Mo or mixtures thereof, and when M═Ta or Nb, x=3 and y=1 and when M═W or Mo, y=x=2.

Abstract: A method for depositing a tungsten nitride layer is provided. The method includes a cyclical process of alternately adsorbing a tungsten-containing compound and a nitrogen-containing compound on a substrate. The barrier layer has a reduced resistivity, lower concentration of fluorine, and can be deposited at any desired thickness, such as less than 100 angstroms, to minimize the amount of barrier layer material.

Abstract: The present invention relates to a mass spectrometer that includes an ionization source having a chamber for ionizing a fluid sample. The ionization chamber has surfaces to reduce the overall interaction with reactive samples. The inner surface walls of the ionization chamber may be formed from an inorganic conductive nitride or disulfide material or may be applied to a substrate as a coating. The invention also includes a method for reducing the interaction of a reactive analyte with the inner wall of the chamber by application or coating the inner wall of the chamber with an inert conductive material.

Abstract: The present invention is a process for enhancing the chemical vapor deposition of titanium nitride from a titanium containing precursor selected from the group consisting of tetrakis(dimethylamino)titanium, tetrakis(diethylamino)titanium and mixtures thereof, reacted with ammonia to produce the titanium nitride on a semiconductor substrate by the addition of organic amines, such as dipropylamine, in a range of approximately 10 parts per million by weight to 10% by weight, preferably 50 parts per million by weight to 1.0 percent by weight, most preferably 100 parts per million by weight to 5000 parts per million by weight to the titanium containing precursor wherein prior to the reaction, said titanium containing precursor is subjected to a purification process to remove hydrocarbon impurities from the titanium containing precursor.

Abstract: An oxide and an oxynitride films and their methods of fabrication are described. The oxide or the oxynitride film is grown on a substrate that is placed in a deposition chamber. A silicon source gas (or a silicon source gas with a nitridation source gas) and an oxidation source gas are decomposed in the deposition chamber using a thermal energy source. A silicon oxide (or an oxynitride) film is formed above the substrate wherein total pressure for the deposition chamber is maintained in the range of 50 Torr to 350 Torr and wherein a flow ratio for the silicon source gas (or the silicon source gas with the nitridiation source gas) and the oxidation source gas is in the range of 1:50 to 1:10000 during a deposition process.

Abstract: Single imido tungsten imido precursors are described for the deposition of tungsten nitride on a substrate by processes such as metal organic chemical vapor deposition. The precursors may be employed to form diffusion barrier layers on microelectronic devices. A method for forming tungsten nitride layers includes the steps of providing a tungsten imido species having the formula LyW(NR)Xn, where R is a carbon containing group, y is an integer between 0 and 5, n is an integer between 0 and 4 and Ly and Xn are selected from the group of non-imido ligands. The single imido tungsten imido species is flowed to a surface of a substrate where the single imido tungsten imido species decomposes to form a tungsten nitride layer.

Abstract: The present invention generally relates to a method for depositing a metallic nitride series thin film, typically a TiN-series thin film. The TiN-series thin film according to the present invention is formed by a CVD, and contains Ti, O and N to have a higher barrier characteristic than those of conventional TiN thin films, so that TiN-series thin film can suitably used as a barrier layer. In addition, a TiN-series thin film according to the present invention is formed by a CVD, and contains Ti, N and P to have a lower resistance than those of conventional TiN films, so that TiN-series thin film can suitably used as a barrier layer or a capacitor top electrode. Moreover, if a TiN-series thin film containing Ti, O, N and P is formed by a CVD, the TiN-series thin film can have both of a high barrier characteristic and a low resistance characteristic.

Abstract: A method for near atmospheric pressure chemical vapor deposition of a silicon based film onto a substrate includes introducing into a deposition chamber at about atmospheric pressure: (i) a substrate; (ii) an iodosilane precursor in the vapor state having at least three iodine atoms bound to silicon; and (iii) at least one reactant gas; and maintaining a deposition temperature within the chamber from about 250° C. to about 650° C. for a period of time sufficient to deposit a silicon based film on the substrate. Silicon based films formed by near atmospheric pressure chemical vapor deposition using an iodosilane precursor in a vapor state and methods for forming silicon-based films using ultraviolet assisted chemical vapor deposition are also included.

Abstract: Embodiments of the invention relate to an apparatus and method of cyclical layer deposition utilizing three or more precursors. In one embodiment, the method includes providing at least one cycle of precursors to form a ternary material layer. Providing at least one cycle of precursors includes introducing a pulse of a first precursor, introducing a pulse of a second precursor, and introducing a pulse of a third precursor, wherein the pulses of two of the three precursors are introduced simultaneously or sequentially. In anoher embodiment, the method includes introducing a pulse of a first precursor, introducing a pulse of a second precursor, repeating the introduction of the first and the second precursors at least one time to form a binary material layer on the substrate surface, and introducing a pulse of a third precursor to form the ternary material layer.

Abstract: A barrier layer structure and a method of forming the structure. The barrier layer structure comprises a bilayer, with a first layer formed by chemical vapor deposition and a second layer formed by physical vapor deposition. The first barrier layer comprises a metal or a metal nitride and the second barrier layer comprises a metal or a metal nitride. The barrier bilayer is applicable to copper metallization.

Abstract: A process for coating the inside surfaces of silicon microflow devices, such as electrophoresis microchannels, with a low-stress, conformal (uniform) silicon nitride film which has the ability to uniformly coat deeply-recessed cavities with, for example, aspect ratios of up to 40:1 or higher. The silicon nitride coating allows extended exposure to caustic solutions. The coating enables a microflow device fabricated in silicon to be resistant to all classes of chemicals: acids, bases, and solvents. The process involves low-pressure (vacuum) chemical vapor deposition. The ultra-low-stress silicon nitride deposition process allows 1-2 &mgr;m thick films without cracks, and so enables extended chemical protection of a silicon microflow device against caustics for up to 1 year. Tests have demonstrated the resistance of the films to caustic solutions at both ambient and elevated temperatures to 65° C.

Abstract: A method for growing a group-III nitride compound (including BN, AlN, GaN and InN) semiconductor film, to which much attention is currently paid in the field of optical semiconductors. If the internal pressure of a reactor increases, vertical growth becomes faster, and internal crystal defects are reduced while many fine pits are generated in view of outer appearance. If the internal pressure of a reactor decreases, vertical growth becomes slower and lateral growth becomes relatively faster, producing fewer pits in view of outer appearance, while internal crystal defects increase. Based on such experimental results, nitride crystals having many fine pits and fewer internal defects are first grown by a high pressure growth method and the fine pits relatively increased in number are then filled by a low pressure growth method, thereby attaining a high quality group-III nitride film.