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WO1993009262A1 - Thick, low-stress films, and coated substrates formed therefrom, and methods for making same - Google Patents

Thick, low-stress films, and coated substrates formed therefrom, and methods for making same Download PDF

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Publication number
WO1993009262A1
WO1993009262A1 PCT/US1991/008265 US9108265W WO9309262A1 WO 1993009262 A1 WO1993009262 A1 WO 1993009262A1 US 9108265 W US9108265 W US 9108265W WO 9309262 A1 WO9309262 A1 WO 9309262A1
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WO
WIPO (PCT)
Prior art keywords
film
substrate
stress
microns
high level
Prior art date
Application number
PCT/US1991/008265
Other languages
French (fr)
Inventor
Charles H. Henager, Jr.
Robert W. Knoll
Original Assignee
Battelle Memorial Institute
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from US07/445,794 external-priority patent/US5156909A/en
Priority claimed from US07/443,454 external-priority patent/US5061574A/en
Application filed by Battelle Memorial Institute filed Critical Battelle Memorial Institute
Publication of WO1993009262A1 publication Critical patent/WO1993009262A1/en

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Classifications

    • CCHEMISTRY; METALLURGY
    • C04CEMENTS; CONCRETE; ARTIFICIAL STONE; CERAMICS; REFRACTORIES
    • C04BLIME, MAGNESIA; SLAG; CEMENTS; COMPOSITIONS THEREOF, e.g. MORTARS, CONCRETE OR LIKE BUILDING MATERIALS; ARTIFICIAL STONE; CERAMICS; REFRACTORIES; TREATMENT OF NATURAL STONE
    • C04B41/00After-treatment of mortars, concrete, artificial stone or ceramics; Treatment of natural stone
    • C04B41/45Coating or impregnating, e.g. injection in masonry, partial coating of green or fired ceramics, organic coating compositions for adhering together two concrete elements
    • C04B41/50Coating or impregnating, e.g. injection in masonry, partial coating of green or fired ceramics, organic coating compositions for adhering together two concrete elements with inorganic materials
    • C04B41/5053Coating or impregnating, e.g. injection in masonry, partial coating of green or fired ceramics, organic coating compositions for adhering together two concrete elements with inorganic materials non-oxide ceramics
    • C04B41/5062Borides, Nitrides or Silicides
    • C04B41/5067Silicon oxynitrides, e.g. SIALON
    • CCHEMISTRY; METALLURGY
    • C23COATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; CHEMICAL SURFACE TREATMENT; DIFFUSION TREATMENT OF METALLIC MATERIAL; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL; INHIBITING CORROSION OF METALLIC MATERIAL OR INCRUSTATION IN GENERAL
    • C23CCOATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; SURFACE TREATMENT OF METALLIC MATERIAL BY DIFFUSION INTO THE SURFACE, BY CHEMICAL CONVERSION OR SUBSTITUTION; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL
    • C23C14/00Coating by vacuum evaporation, by sputtering or by ion implantation of the coating forming material
    • C23C14/06Coating by vacuum evaporation, by sputtering or by ion implantation of the coating forming material characterised by the coating material
    • C23C14/0641Nitrides
    • CCHEMISTRY; METALLURGY
    • C23COATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; CHEMICAL SURFACE TREATMENT; DIFFUSION TREATMENT OF METALLIC MATERIAL; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL; INHIBITING CORROSION OF METALLIC MATERIAL OR INCRUSTATION IN GENERAL
    • C23CCOATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; SURFACE TREATMENT OF METALLIC MATERIAL BY DIFFUSION INTO THE SURFACE, BY CHEMICAL CONVERSION OR SUBSTITUTION; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL
    • C23C14/00Coating by vacuum evaporation, by sputtering or by ion implantation of the coating forming material
    • C23C14/06Coating by vacuum evaporation, by sputtering or by ion implantation of the coating forming material characterised by the coating material
    • C23C14/0676Oxynitrides

Definitions

  • This invention relates to the production of relatively thick, low-stress films, particularly optical films, and to coated substrates produced.
  • transparent electrically conductive metallic film is deposited onto the surface of a non-conductive material at a non-elevated temperature of 300 to 400°C by cathode sputtering or thermal evaporation, respectively.
  • Thick films i.e. >5 micron thickness, are not contemplated using non-elevated temperature deposition techniques.
  • U.S. 3,320,484 In another method at a non-elevated temperature (at 20 to 100°C), U.S. 3,320,484, a semiconductor integrated circuit is produced by depositing onto a support, a
  • substantially planar thin layer (0.05 to 0.15 micron thickness) of aluminum vapor is deposited onto a high resistivity semiconductor wafer substrate, the thin
  • dielectric layer including silicon nitride.
  • U.S. 3,463,715 relates to an elevated temperature (about 1000 °C) method of sputter deposition of a
  • semiconductor material such as silicon onto a substrate to produce a silicon layer having high conductivity.
  • the deposition technique employed is cathode sputtering
  • the sputtering deposition of the film onto a molybdenum substrate is carried out at a temperature of 500 to 900°C, depending on the film thickness.
  • the film thickness is in a range of 50 angstroms to 20 microns. As the thickness of the film increases, the operating
  • the deposition technique described therein utilizes RF energy across a substrate and source to generate a plasma-containing source material at temperatures of 300°C, or more. Again, the greater the film thickness, the higher the deposition temperature. At a film thickness of 0.5 microns, an operating temperature of 1250°C is indicated.
  • U.S. 3,629,088 covers a sputtering method for the deposition of silicon oxynitride.
  • the low temperature deposition of silicon oxynitride onto an integrated circuit device is accomplished by the reactive sputtering of a thin layer (0.15 microns) of high-purity silicon source material in the presence of nitrous oxide and nitrogen.
  • a film of a transition metal suicide or an aluminum silicon alloy is deposited on a semiconductor substrate at a temperature of 500 to 1200°C by vacuum evaporation, and then used as an electrode or wiring of a semiconductor device.
  • the thin film (0.3 microns in Examples) is
  • U.S. 4,656,101 describes an electronic device having a structure in which at least one electronic element
  • the insulating or protecting film can consist principally of aluminum nitride and a film consisting principally of silicon oxide or silicon nitride.
  • U.S. 4,711,821 relates to an optomagnetic recording medium which utilizes at least one thin film layer (0.01 to 0.02 microns) of silicon nitride.
  • the underlying substrate can be a plastic material such as acrylic resin or
  • U.S. 4,804,640 relates to a method of forming a three-region dielectric film, having an overall thickness of 0.01 microns, on silicon, and a semiconductor device employing such a film.
  • the formation method includes the step of reactive sputtering of aluminum in an oxygen plasma atmosphere.
  • U.S. 4,846,948 shows a method of producing an iron-silicon-aluminum alloy magnetic film of 1 to 20 microns thickness in which argon is entrapped by using a DC
  • magnetron sputtering apparatus to apply RF bias to a substrate using an RF diode sputtering technique.
  • Heat treatment of the alloy takes place at 450 to 800°C.
  • a laminated composite and a method for forming same by chemical vapor deposition is the subject of U.S. 4,336,304.
  • the composite includes a layer of opaque silicon aluminum oxynitride of a thickness between 12 and 50 microns, and an average of 25 microns, and a underlying substrate material to which the layer is bonded.
  • the method includes the steps of exposing a surface of the material to an ammonia-containing atmosphere, heating the surface to at least 1200°C, and impinging a gas containing in a flowing
  • a low-stress film material for coating underlying substrates, particularly silicon, silicon nitride, and the like, by methods which are conducted at a non-elevated temperature (500°C or less), but which produce the above-described films at a relatively high thickness levels.
  • These films should be transparent, hard, dense, and mechanically stable even at thicknesses of 50 microns or greater.
  • the above described needs have been met by the Si-Al-N and Si-Al-O-N film materials of the present invention for coating underlying substrates, such as silicon, silicon nitride, and the like.
  • the subject film material exhibits a substantial reduction of total stress, without degrading the optical properties, electrical properties, or
  • a film material can be produced for use in various applications such as optical devices, and in protective and insulating coatings for microelectronic devices.
  • the subject films have excellent adherence to the underlying substrate, a high degree of hardness and durability, and are excellent insulators.
  • Prior art elevated temperature deposition processes cannot meet the microelectronic packaging temperature formation
  • the process of the present invention is conducted under non-elevated temperature conditions, typically 500°C or less.
  • FIG. 1 is a schematic of the probe tip region of the thermal conductivity apparatus.
  • the method of the present invention relates to
  • producing a low stress, film-coated substrate comprises depositing a film material onto a surface of an underlying substrate.
  • Typical substrates useful in the practice of this invention, particularly in the microelectronics industry, are silicon, silicon dioxide, germanium, gallium arsenide, molybdenum, and the like. The preferred
  • underlying substrates are silicon and silicon dioxide.
  • the above-described method is conducted at a non- elevated operating temperature of not more than 500°C.
  • a non-elevated operating temperature of not more than about 300°C, and more
  • the subject non-elevated temperature method of coating a substrate can be conducted employing several deposition techniques.
  • the preferred forms of deposition are sputtering methods such as RF-Diode Sputtering, Magnetron Sputtering, and the like.
  • the hereinafter described film materials are produced using Reactive RF-Diode .Sputtering from a target made by hot pressing mixed powders.
  • the film material comprises a Si-Al-N-containing material.
  • the structural formula of the Si-Al-N-containing material comprises Si 1-x Al x N, wherein x is from about 0.1 up to about 0.6. In the preferred structural formula, x is from about 0.2 up to about 0.4.
  • the film coating material of this invention has a thickness of at least about 5 microns.
  • a low stress layer of the film material of extremely high thickness can be produced at non-elevated temperature conditions using the method of the present invention; the upper practical limit of thickness is up to about 150 microns.
  • the thickness range is preferably from about 10 microns, and more
  • the Si-Al-N-containing material of this invention preferably from about 25 microns, up to preferably about 100 microns, and more preferably up to about 75 microns.
  • An important property of the Si-Al-N-containing material of this invention is that it exhibits a high level of optical transparency, particularly in both the visible and infrared ranges.
  • An important measure of optical transparency is optical transmissivity, which is defined as the ratio, expressed as a percent, of the light intensity transmitted through the film, at a specified wavelength, to the light intensity transmitted in a vacuum.
  • the optical transmissivity of the film material is typically at least about 90%, at a 800 nm wavelength, for films of at least a 50 micron thickness.
  • optical transmissivity values have been determined using, for instance, the test procedures described in Example 1 with a Beckman
  • Another way of describing the optical transparency of the film materials of this invention is by determining the optical absorption coefficient of these materials at a wavelength of 750 nm In this case, when a high level of optical transparency is present in the subject materials, it will be indicated by their extremely low optical
  • coefficients are typically not more than about 30/cm, preferably not more than about 20/cm, and more preferably not more than about 10/cm.
  • optical absorption coefficient values have been
  • Film stress is defined as force per unit area acting in the plane of the film which acts to supply a bending moment to an underlying substrate. More
  • the film materials produced by the process of this invention have a relatively low film stress and a high level of adherence to the underlying substrate, thereby avoiding substantial cracking and debonding of the film and any resultant damage to the underlying substrate.
  • Total film stress is defined as the sum of the intrinsic, or
  • the total stress of the material is generally not more than 100 MPa, preferably not more than 75 MPa, and most preferably less than about.50 MPa.
  • the total stress values have been determined using the following test procedures in Example 1 below, using a high resolution Tropel Model 9000i Laser Interferometer with CRT display, camera data storage, and vacuum chuck accessory for handling thin substrates.
  • Intrinsic elastic stiffness is defined as the ratio of the film's Young's Modulus (E f ) to [1 minus Poissons ratio of the film], (l-v f ), which represents the resistance of the film to the elastic deflection.
  • the intrinsic elastic stiffness should be less than about 300 GP a , preferably less than about 200 GP a , and more preferably less than about 150 GP a .
  • the intrinsic elastic stiffness values have been determined using the test procedures described in Example 1 below and the Tropel Interferometer described above, with calculations being done according to the Retajczyk and Sinha method.
  • CTE coefficient of thermal expansion
  • the CTE of the film material is not more than about 3.8 ⁇ 10 -6 , preferably not more than about 3.3 ⁇ 10 -6 , and more preferably less than about 2.8 ⁇ 10 -6 .
  • the CTE values have also been determined using the test procedures and test equipment used in computing the above-described elastic stiffness value. Furthermore, it is important to the adherence and stress properties of the film-coated
  • the CTE ratio (expressed as a percentage) for a given film material has been determined by dividing the CTE of that film material by the CTE of the underlying
  • the CTE ratio for the film materials produced by the method of this invention will not be more than about 50%, and preferably not more than about 40%, and most preferably not more than 30%.
  • the index of refraction of the film material should have a similar value to the index of refraction of the underlying substrate.
  • the index of refraction of the film material should be from about 1.9 up to about 2.1, respectively.
  • the index of refraction values have been determined using the test procedure set forth in Example 1 using the method of
  • the actual density of the film material is at least about 95% of the theoretical density of the material, and preferably about 97%.
  • the densities have been determined by measuring the weight gain of the substrate after coating operations have been completed, calculating the film volume from the measured film thickness, and then determining the mass per unit volume.
  • the film materials of the present invention typically have a high thermal conductivity, preferably at least about 1.0 ⁇ 10 -3 W/cm/K, more preferably at least about 5.0 ⁇ 10 -3 W/cm/K, and most preferably at least about 7.0 ⁇ 10 -3 W/cm/K.
  • Fig. 1 is a schematic figure which identifies the various components that make up the thin film thermal conductivity measurement. At each interface, heat flow is assumed to be proportional to the temperature difference and inversely proportional to the thermal resistance. Defining
  • YT ij is the temperature difference between adjacent regions (numbered 1 to 5 in Fig. Al)
  • R i is the thermal resistance of the ith interface
  • Q is the steady state heat flow across the interfaces, which is the same value at each interface at steady state.
  • R 1 is the thermal resistance to heat flow from the reservoir (10) into the probe (12).
  • the thermal resistance terms are conventionally written as a product of the thermal conductivity and geometrical factors as follows: Probe Resistance (Region 1.
  • the resistances are considered to be in series such that
  • a plot of the temperature ratio as a function of coating thickness is fit with a line using a least squares
  • a 3 is the contact area between the probe tip and the coating
  • K 1 is the probe tip radius
  • K 1 is the thermal conductivity of the probe material.
  • the contact area was determined by measuring the impression of the probe left on the coating surface using a white thermal grease. The probe tip radius and probe thermal conductivity are known and, thus, the coating conductivity can be calculated.
  • probe contact resistance only appears in the intercept term and does not affect the measured value of the film thermal conductivity.
  • the film material of this invention also comprises a Si-Al-O-N-containing material.
  • the structural formula of the Si-Al-O-N-containing material comprises Si l- ⁇ Al ⁇ O y N y-l , wherein x is from about 0.1 up to about 0.6, and y is from about 0 up to about 1.
  • x is from about 0.2 up to about 0.4, and y is from about 0.2 up to about 0.6.
  • the optical transmissivity of the film material is typically at least about 95%, at a 800 nm wavelength, for films of at least a 50 micron thickness.
  • the optical absorption coefficients of Si-Al-O-N at a 750 nm wavelength are typically not more than about 20/cm, preferably not more than about 10/cm, and more preferably not more than about 5/cm.
  • Si-Al-O-N film material which verify this film low stress include, for example, a determination of the total film stress of the material.
  • Total film stress is defined as the sum of the intrinsic, or deposition stress, and the thermal stress, which is due to the difference between thermal expansion coefficients of the respective film and substrate.
  • the total stress of the material is generally not more than 200 MPa, preferably not more than 150 MPa, and most preferably less than about 100 MPa.
  • the intrinsic elastic stiffness of the material should be less than about 200 GP a , preferably less than about 100 GP a , and more preferably less than about 50 GP a .
  • the CTE of the film material is not more than about 6.0 ⁇ 10 -6 , preferably not more than about 4.0 ⁇ 10 -6 , and more
  • the CTE ratio for the Si-Al-O-N film materials produced by the method of this invention will not be more than about 50%, and
  • the index of refraction of the Si-Al-O-N film material can be changed so that it can have a similar value to the index of refraction of the underlying substrate.
  • the index of refraction of the film material is from about 1.5 up to about 2.1, respectively.
  • the actual density of the Si-Al-O-N film material is at least about 95% of the theoretical density of the material, and preferably about 97%. This is similar to the density of the Si-Al-N film material.
  • the Si-Al-O-N film materials of the present invention typically have a high thermal conductivity, preferably at least about
  • the system was equipped with feedback control of gas pressure, gas flow, and RF power. Films were deposited on flat, polished SiO 2 and Si substrates (25.4 mm dia. by 0.25 to 0.38 mm thick),
  • the film materials were deposited from Si, or hot-pressed Si 70 Al 30 or Si 60 Al 40 powder targets, at a 600 W target power and a "210°C substrate temperature.
  • Ar/N 2 gas mixtures at a total pressure of 2.7 Pa (20 mTorr) were used for the sputtering deposition.
  • N 2 partial pressures were 0.4-0.7 Pa for the nitride depositions.
  • Deposition rates were 1.7 lm/hr for pure nitrides.
  • the Si:Al ratio in the films was set by the target.
  • E f /(l-n f ) (where E f is the elastic modulus and n f is Poisson's Ratio of the film), were calculated using the method of Retajczyk and Sinha, see G. Lucovsky, et al., J. Vac. Sci. Techol. A4 (3), 681 (1986). For this
  • the stress-induced bending of the SiO 2 and Si substrates was measured over the temperature range 20 to 200°C by equipping the interferometer with a heated
  • a thermal comparator apparatus was assembled to measure thermal conductivity of thin films.
  • a heated probe was brought into contact with a specimen, which consists of a film on a standard 38.5 mm (1.5 inch) Si mirror substrate held at constant temperature.
  • a temperature difference is developed in a few seconds between the probe reference and the probe tip. This temperature difference is used to determine the thermal conductivity of the film.
  • Table I A summary of measured film properties is given in Table I for the three different compositions evaluated, namely, Si:N, Si 60 Al 40 and Si 70 Al 30 , respectively.
  • the qualities listed in Table I are mean values for the film thickness range of 2 to 10 microns; therefore, the listed standard deviations include contributions from measurement errors and from the thickness dependence. Table I is intended mainly to illustrate property differences
  • the refractive indices of the pure nitride films corresponded closely to the indices of bulk Si 3 N 4 and
  • Example l The experimental method of Example l was repeated for the deposition of the following film materials:

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Abstract

Stress-induced deformation, and the damage resulting therefrom, increases with film thickness. The overcoming of excessive stress by the use of the Si-Al-N film material of the present invention, permits the formation of thick films that are necessary for certain of the above described applications. The most likely use for the subject film materials, other than their specialized views as an optical film, is for microelectronic packaging of components on silicon substrates. In general, the subject films have excellent adherence to the underlying substrate, a high degree of hardness and durability, and are excellent insulators. Prior art elevated temperature deposition processes cannot meet the microelectronic packaging temperature formation constraints. The process of the present invention is conducted under non-elevated temperature conditions, typically 500 °C or less.

Description

THICK, LOW-STRESS FILMS, AND COATED SUBSTRATED FORMED THEREFROM, AND METHODS FOR MAKING SAME
BACKGROUND OF THE INVENTION
This invention relates to the production of relatively thick, low-stress films, particularly optical films, and to coated substrates produced.
Deposition of thin (<5 microns) electrically
conductive films onto the support surface of an electrical non-conductor at non-elevated temperature conditions (not more tihan about 500°C) is known in the prior art. For example, in U.S. 2,769,778, a thin (0.05 micron),
transparent electrically conductive metallic film is deposited onto the surface of a non-conductive material at a non-elevated temperature of 300 to 400°C by cathode sputtering or thermal evaporation, respectively. Thick films, i.e. >5 micron thickness, are not contemplated using non-elevated temperature deposition techniques.
In another method at a non-elevated temperature (at 20 to 100°C), U.S. 3,320,484, a semiconductor integrated circuit is produced by depositing onto a support, a
substantially planar thin layer (0.05 to 0.15 micron thickness) of aluminum vapor is deposited onto a high resistivity semiconductor wafer substrate, the thin
dielectric layer including silicon nitride.
U.S. 3,463,715 relates to an elevated temperature (about 1000 °C) method of sputter deposition of a
semiconductor material such as silicon onto a substrate to produce a silicon layer having high conductivity. The deposition technique employed is cathode sputtering
deposition.
Another elevated temperature method is provided in U.S. 3,560,364 for producing an extremely thin, freestanding or unsupported transparent film of silicon nitride having a low density, a low coefficient of thermal
expansion, high flexibility, and good dielectric properties. The sputtering deposition of the film onto a molybdenum substrate is carried out at a temperature of 500 to 900°C, depending on the film thickness. The film thickness is in a range of 50 angstroms to 20 microns. As the thickness of the film increases, the operating
temperature for producing that film moves upward toward 900°C, the upper end of the temperature range. The above technique described is known as RF sputtering.
A method of deposition is described in U.S. 3,600,218 in which insulating films of silicon nitride and aluminum nitride are deposited onto a substrate. Nitrogen is employed in the deposition reaction to form a thin,
insulating film of silicon nitride or aluminum nitride, respectively, onto the substrate surface. The deposition technique described therein utilizes RF energy across a substrate and source to generate a plasma-containing source material at temperatures of 300°C, or more. Again, the greater the film thickness, the higher the deposition temperature. At a film thickness of 0.5 microns, an operating temperature of 1250°C is indicated.
U.S. 3,629,088 covers a sputtering method for the deposition of silicon oxynitride. The low temperature deposition of silicon oxynitride onto an integrated circuit device is accomplished by the reactive sputtering of a thin layer (0.15 microns) of high-purity silicon source material in the presence of nitrous oxide and nitrogen.
A film of a transition metal suicide or an aluminum silicon alloy is deposited on a semiconductor substrate at a temperature of 500 to 1200°C by vacuum evaporation, and then used as an electrode or wiring of a semiconductor device. The thin film (0.3 microns in Examples) is
produced by a sputtering method wherein the silicon
component of the film was not supplied from the target, but from a gaseous silicon compound contained in the sputtering atmosphere. (See U.S. 4,218,291). U.S. 4,656,101 describes an electronic device having a structure in which at least one electronic element,
including an insulating film or covered with a protecting film, is formed on a substrate, at a temperature from ambient to 900°C, where the insulating or protecting film can consist principally of aluminum nitride and a film consisting principally of silicon oxide or silicon nitride.
U.S. 4,711,821 relates to an optomagnetic recording medium which utilizes at least one thin film layer (0.01 to 0.02 microns) of silicon nitride. The underlying substrate can be a plastic material such as acrylic resin or
polycarbonate.
U.S. 4,804,640 relates to a method of forming a three-region dielectric film, having an overall thickness of 0.01 microns, on silicon, and a semiconductor device employing such a film. The formation method includes the step of reactive sputtering of aluminum in an oxygen plasma atmosphere.
U.S. 4,846,948 shows a method of producing an iron-silicon-aluminum alloy magnetic film of 1 to 20 microns thickness in which argon is entrapped by using a DC
magnetron sputtering apparatus to apply RF bias to a substrate using an RF diode sputtering technique. Heat treatment of the alloy takes place at 450 to 800°C.
A laminated composite and a method for forming same by chemical vapor deposition is the subject of U.S. 4,336,304. The composite includes a layer of opaque silicon aluminum oxynitride of a thickness between 12 and 50 microns, and an average of 25 microns, and a underlying substrate material to which the layer is bonded. The method includes the steps of exposing a surface of the material to an ammonia-containing atmosphere, heating the surface to at least 1200°C, and impinging a gas containing in a flowing
atmosphere of air, nitrogen, silicon tetrachloride, and aluminum trichloride on the surface. This is an example of a high temperature deposition technique, typically at temperatures between 1000 and 1400°C, and at a pressure on the order of 240 megapascals (MPa).
Finally, in an article by Shiban K. Tiku and Gregory C. Smith in the IEEE Transactions on Electronic Devices. Volume Ed-31, No. 1, January 1984 , entitled, "Choice of Dielectrics for TFEL Displays", an attempt was made to deposit silicon aluminum nitroxide and Si3N4 for use in AC thin-film electroluminescence displays. Films of 0.2 to 0.3 microns thickness were fabricated. The authors stated that thinner films of the dielectric material were found to be a problem because of pinholes, while thicker films caused high optical absorption and film stress. Since a high degree of optical transparency is required in many applications, such as in the electronics industry, the use of thick films is prohibited. Furthermore, high film stress results in a substantial amount and cracking and debonding of the film with respect to the underlying substrate, and in many cases resultant damage thereto.
Accordingly, there exists a need for a low-stress film material for coating underlying substrates, particularly silicon, silicon nitride, and the like, by methods which are conducted at a non-elevated temperature (500°C or less), but which produce the above-described films at a relatively high thickness levels. These films should be transparent, hard, dense, and mechanically stable even at thicknesses of 50 microns or greater.
SUMMARY OF THE INVENTION
The above described needs have been met by the Si-Al-N and Si-Al-O-N film materials of the present invention for coating underlying substrates, such as silicon, silicon nitride, and the like. The subject film material exhibits a substantial reduction of total stress, without degrading the optical properties, electrical properties, or
protective properties of the material. Since excessive film stress has been eliminated, a film material can be produced for use in various applications such as optical devices, and in protective and insulating coatings for microelectronic devices.
Stress-induced deformation, and the damage resulting therefrom, increases with film thickness. The overcoming of excessive stress by the use of the Si-Al-N and Si-Al-O-N film materials of the present invention, permits the formation of thick films that are necessary for certain of the above described applications. The most likely use for the subject film materials, other than their specialized views as an optical film, is for microelectronic packaging of components on silicon substrates.
In general, the subject films have excellent adherence to the underlying substrate, a high degree of hardness and durability, and are excellent insulators. Prior art elevated temperature deposition processes cannot meet the microelectronic packaging temperature formation
constraints. The process of the present invention is conducted under non-elevated temperature conditions, typically 500°C or less.
The foregoing and other objects, features, and
advantages of the invention will become more readily apparent from the following detailed description of a preferred embodiment which proceeds with reference to the drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a schematic of the probe tip region of the thermal conductivity apparatus.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
The method of the present invention relates to
producing a low stress, film-coated substrate comprises depositing a film material onto a surface of an underlying substrate. Typical substrates useful in the practice of this invention, particularly in the microelectronics industry, are silicon, silicon dioxide, germanium, gallium arsenide, molybdenum, and the like. The preferred
underlying substrates are silicon and silicon dioxide.
The above-described method is conducted at a non- elevated operating temperature of not more than 500°C. In this way, underlying substrates, which cannot withstand the effects of coating operations at elevated temperatures, can be conducted at the non-elevated temperature levels of the present invention. Preferably, a non-elevated operating temperature of not more than about 300°C, and more
preferably not more than about 200°C, is employed in producing the requisite film materials.
The subject non-elevated temperature method of coating a substrate can be conducted employing several deposition techniques. However, the preferred forms of deposition are sputtering methods such as RF-Diode Sputtering, Magnetron Sputtering, and the like. In the most preferred form of the present invention, the hereinafter described film materials are produced using Reactive RF-Diode .Sputtering from a target made by hot pressing mixed powders.
The film material comprises a Si-Al-N-containing material. In the preferred case, the structural formula of the Si-Al-N-containing material comprises Si1-xAlxN, wherein x is from about 0.1 up to about 0.6. In the preferred structural formula, x is from about 0.2 up to about 0.4.
The film coating material of this invention has a thickness of at least about 5 microns. A low stress layer of the film material of extremely high thickness can be produced at non-elevated temperature conditions using the method of the present invention; the upper practical limit of thickness is up to about 150 microns. The thickness range is preferably from about 10 microns, and more
preferably from about 25 microns, up to preferably about 100 microns, and more preferably up to about 75 microns. An important property of the Si-Al-N-containing material of this invention is that it exhibits a high level of optical transparency, particularly in both the visible and infrared ranges. An important measure of optical transparency is optical transmissivity, which is defined as the ratio, expressed as a percent, of the light intensity transmitted through the film, at a specified wavelength, to the light intensity transmitted in a vacuum. Thus, the optical transmissivity of the film material is typically at least about 90%, at a 800 nm wavelength, for films of at least a 50 micron thickness. Preferably, an optical transmissivity of at least about 60%, more preferably at least about 70%, and most preferably at least about 80%, at respective corre-sponding wavelengths of 450, 500, and 600 nm For purposes of this invention, optical transmissivity values have been determined using, for instance, the test procedures described in Example 1 with a Beckman
Instruments Model 5270 double-monochromator spectrometer.
Another way of describing the optical transparency of the film materials of this invention is by determining the optical absorption coefficient of these materials at a wavelength of 750 nm In this case, when a high level of optical transparency is present in the subject materials, it will be indicated by their extremely low optical
absorption coefficients. These optical absorption
coefficients are typically not more than about 30/cm, preferably not more than about 20/cm, and more preferably not more than about 10/cm. For purposes of this invention, the optical absorption coefficient values have been
determined, using the Beckman spectrometer described above, directly from the spectral transmission curve by measuring the decrease in optical transmission (as function of thickness) compared to an uncoated SiO2 substrate.
A novel and extremely important feature of the film materials of the present invention relates to their low stress values. Film stress is defined as force per unit area acting in the plane of the film which acts to supply a bending moment to an underlying substrate. More
specifically, the film materials produced by the process of this invention have a relatively low film stress and a high level of adherence to the underlying substrate, thereby avoiding substantial cracking and debonding of the film and any resultant damage to the underlying substrate.
Various properties of the film material which verify this film low stress include, for example, a determination of the total film stress of the material. Total film stress is defined as the sum of the intrinsic, or
deposition, stress, and the thermal stress, which is due to the difference between thermal expansion coefficients of the respective film and substrate. Based on a film
material produced by the method of this invention and having a thickness of about 50 microns on an underlying silicon substrate, the total stress of the material is generally not more than 100 MPa, preferably not more than 75 MPa, and most preferably less than about.50 MPa. For purposes of this invention, the total stress values have been determined using the following test procedures in Example 1 below, using a high resolution Tropel Model 9000i Laser Interferometer with CRT display, camera data storage, and vacuum chuck accessory for handling thin substrates.
Another indication of the low stress of the film material of the present invention is provided by measuring the intrinsic elastic stiffness of the material. Intrinsic elastic stiffness is defined as the ratio of the film's Young's Modulus (Ef) to [1 minus Poissons ratio of the film], (l-vf), which represents the resistance of the film to the elastic deflection. With respect to the film
material produced by the method of the subject invention, the intrinsic elastic stiffness should be less than about 300 GPa, preferably less than about 200 GPa, and more preferably less than about 150 GPa. For purposes of this invention, the intrinsic elastic stiffness values have been determined using the test procedures described in Example 1 below and the Tropel Interferometer described above, with calculations being done according to the Retajczyk and Sinha method.
Another important property which can be measured with respect to the film materials of this invention is the coefficient of thermal expansion (CTE) . The CTE is defined as the fractional change in length per degree of
temperature change. Thus, the CTE of the film material is not more than about 3.8 × 10-6, preferably not more than about 3.3 × 10-6, and more preferably less than about 2.8 × 10-6. For purposes of this invention, the CTE values have also been determined using the test procedures and test equipment used in computing the above-described elastic stiffness value. Furthermore, it is important to the adherence and stress properties of the film-coated
substrate that the CTE of the film material be of similar magnitude to the CTE of the underlying substrate. For this purpose, the CTE ratio (expressed as a percentage) for a given film material has been determined by dividing the CTE of that film material by the CTE of the underlying
substrate, and multiplying the resultant quotient by 100. Thus, the CTE ratio for the film materials produced by the method of this invention will not be more than about 50%, and preferably not more than about 40%, and most preferably not more than 30%.
In many applications it is important that the film material coated onto the substrate have similar refractive properties of as the underlying substrate itself so that the end user won't notice the optical differences between same. Thus, the index of refraction of the film material should have a similar value to the index of refraction of the underlying substrate. For use in conjunction with silicon based materials, the index of refraction of the film material should be from about 1.9 up to about 2.1, respectively. For purposes of this invention, the index of refraction values have been determined using the test procedure set forth in Example 1 using the method of
Manificier, and the above described Beckman spectrometer.
Another way of determining the optical properties of the coating material is by measuring the actual density of the film material and comparing it with the theoretical density of the film material. This will indicate the amount of free space or voids present in the film material. The closer the actual density to the theoretical density of the film material, the freer of voids will be the film material. In that regard, a film material free of voids exhibits good optical properties since light will pass through same without being diverted by a preponderance of void areas. Preferably, the actual density of the film material is at least about 95% of the theoretical density of the material, and preferably about 97%. For purposes of this invention, the densities have been determined by measuring the weight gain of the substrate after coating operations have been completed, calculating the film volume from the measured film thickness, and then determining the mass per unit volume.
For many industries, such as the semiconductor
industry, it is important that the film material have as high a thermal conductivity as possible in order for it to dissipate the maximum amount of heat within its interstices without destroying the structural integrity of the film coating. The film materials of the present invention typically have a high thermal conductivity, preferably at least about 1.0 × 10-3 W/cm/K, more preferably at least about 5.0 × 10-3 W/cm/K, and most preferably at least about 7.0 × 10-3 W/cm/K.
The following analysis was developed to extract thin film thermal conductivities from the thermal conductivity apparatus of Fig. 1. Fig. 1 is a schematic figure which identifies the various components that make up the thin film thermal conductivity measurement. At each interface, heat flow is assumed to be proportional to the temperature difference and inversely proportional to the thermal resistance. Defining
Ti - Tj = YTij = RiQ
where YTij is the temperature difference between adjacent regions (numbered 1 to 5 in Fig. Al), Ri is the thermal resistance of the ith interface, and Q is the steady state heat flow across the interfaces, which is the same value at each interface at steady state. As an example
T1 - T2 = YT12 = R1Q
and R1 is the thermal resistance to heat flow from the reservoir (10) into the probe (12). The thermal resistance terms are conventionally written as a product of the thermal conductivity and geometrical factors as follows: Probe Resistance (Region 1.
1/R1 = 4K1rl K1 = probe thermal conductivity r1 = probe tip radius
(This solution is for heat flow from a circular region into a semi-infinite cylinder and is from Carslow, H.S., and J.C. Jaeger, Conduction of Heat in Solids, Oxford, N.Y., 1947, pp. 214-216.)
Probe Tip/Coatinα Resistance (Contact Resistance) (Region 21
1/R2 = K2A2/t2 K2 = contact conductivity
A2 = contact area
t2 = contact layer thickness
Coating Resistance (Region 3.
1/R3 = K3A3/t3 K3 = coating conductivity
A3 = contact area
t3 = coating thickness
(Here we assume there is no lateral heat flow in the coating, which is a valid assumption if the coating thermal conductivity is low and the coating thickness is small compared to its radius.) Substrate Resistance (Region 4)
1/R4 = 4K4r4 K4 = substrate conductivity
r4 = substrate radius
(Here we assume that heat flow from coating into the substrate also obeys the semi-infinite solution discussed above.)
Heat Sink Resistance (Region 5)
R5 ≈ 0 since T4 ≈ T5 Assume R5 ≪ R1, R2, R3, R4
The resistances are considered to be in series such that
Figure imgf000014_0001
which can be solved for Q to give
Figure imgf000014_0003
Thus, we can write
Figure imgf000014_0002
which can be used to give
Figure imgf000014_0004
Using the definitions for the Ri and neglecting R5 give
Figure imgf000014_0005
Therefore, this gives
Figure imgf000015_0001
which is of the form for a line y = mx + b
where
Figure imgf000015_0002
x = t3 = coating thickness
Figure imgf000015_0003
Figure imgf000015_0004
A plot of the temperature ratio as a function of coating thickness is fit with a line using a least squares
procedures. The resulting slope is used to solve for the coating thermal conductivity, K3, as
Figure imgf000015_0005
where A3 is the contact area between the probe tip and the coating, K1 is the probe tip radius, and K1 is the thermal conductivity of the probe material. The contact area was determined by measuring the impression of the probe left on the coating surface using a white thermal grease. The probe tip radius and probe thermal conductivity are known and, thus, the coating conductivity can be calculated.
Note that the probe contact resistance only appears in the intercept term and does not affect the measured value of the film thermal conductivity.
The film material of this invention also comprises a Si-Al-O-N-containing material. In the preferred case, the structural formula of the Si-Al-O-N-containing material comprises Sil-χAlχOyNy-l, wherein x is from about 0.1 up to about 0.6, and y is from about 0 up to about 1. In the preferred structural formula, x is from about 0.2 up to about 0.4, and y is from about 0.2 up to about 0.6.
The optical transmissivity of the film material is typically at least about 95%, at a 800 nm wavelength, for films of at least a 50 micron thickness. Preferably, an optical transmissivity of at least about 60%, more
preferably at least about 70%, and most preferably at least about 80%, at respective corresponding wavelengths of 450, 500, and 600 nm is provided. The optical absorption coefficients of Si-Al-O-N at a 750 nm wavelength, are typically not more than about 20/cm, preferably not more than about 10/cm, and more preferably not more than about 5/cm.
Various properties of the Si-Al-O-N film material which verify this film low stress include, for example, a determination of the total film stress of the material.
Total film stress is defined as the sum of the intrinsic, or deposition stress, and the thermal stress, which is due to the difference between thermal expansion coefficients of the respective film and substrate. Based on a film
material produced by the method of this invention, and having a thickness of about 50 microns on an underlying silicon substrate, the total stress of the material is generally not more than 200 MPa, preferably not more than 150 MPa, and most preferably less than about 100 MPa.
Another indication of the low stress of the Si-Al-O-N film material of the present invention is provided by measuring the intrinsic elastic stiffness of the material. With respect to the Si-Al-O-N film material produced by the method of the subject invention, the intrinsic elastic stiffness should be less than about 200 GPa, preferably less than about 100 GPa, and more preferably less than about 50 GPa.
Another important property which can be measured with respect to the Si-Al-O-N film materials of this invention is the coefficient of thermal expansion (CTE). The CTE of the film material is not more than about 6.0 × 10-6, preferably not more than about 4.0 × 10-6, and more
preferably not more than about 2.3 × 10-6. The CTE ratio for the Si-Al-O-N film materials produced by the method of this invention will not be more than about 50%, and
preferably not more than about 40%, and most preferably not more than 30%. The addition of oxygen to the film material formulation proportionally and controllably decreases the index of refraction. In this way, the index of refraction of the Si-Al-O-N film material can be changed so that it can have a similar value to the index of refraction of the underlying substrate. For use in conjunction with silicon based materials, the index of refraction of the film material is from about 1.5 up to about 2.1, respectively.
Preferably, the actual density of the Si-Al-O-N film material is at least about 95% of the theoretical density of the material, and preferably about 97%. This is similar to the density of the Si-Al-N film material. The Si-Al-O-N film materials of the present invention typically have a high thermal conductivity, preferably at least about
1.0 × 10-3 W/cm/K, more preferably at least about
3.0 × 10-3 W/cm/K, and most preferably at least about
7.0 × 10-3 W/cm/K. For purposes of this invention, the values of thermal conductivity have been determined using the following test procedures and test equipment previously described. Example 1
This is a description of a representative experimental method conducted under non-elevated temperature conditions to produce the novel Si-Al-N and Si-Al-O-N film materials and film-coated substrates of the present invention.
All the film materials were produced in an RF-Diode sputtering chamber, manufactured by MRC, which was equipped with 152 mm (6 inch) diameter targets and a liquid
nitrogen-trapped diffusion pump. The system was equipped with feedback control of gas pressure, gas flow, and RF power. Films were deposited on flat, polished SiO2 and Si substrates (25.4 mm dia. by 0.25 to 0.38 mm thick),
positioned 30 mm below the target. The film materials were deposited from Si, or hot-pressed Si70Al30 or Si60Al40 powder targets, at a 600 W target power and a "210°C substrate temperature. Ar/N2 gas mixtures at a total pressure of 2.7 Pa (20 mTorr) were used for the sputtering deposition. N2 partial pressures were 0.4-0.7 Pa for the nitride depositions. Deposition rates were 1.7 lm/hr for pure nitrides. Because of deleterious effects of residual H20 on film properties, care was taken to begin deposition only after a base pressure <~2 × 10-5 Pa (1.5 × 10-7 Torr) was reached, usually after overnight pumpout and bakeout of the chamber.
The following film materials were deposited and
studied: Si:N, Si70Al30:N, Si60Al40:N, respectively. The Si:Al ratio in the films was set by the target.
For each material, films of nominal thicknesses of 5, 10, and 50 microns were deposited on a pair of each
substrate type, SiO2 and Si. Thickness and refractive index of 5 to 10 micron films were measured from the
(visible) spectral transmission according to the method of J.C. Manifacier, et al.. Scientific Instruments, 9 1002 (1976). Briefly, the film/substrate system creates an interference pattern in the transmission spectrum that can be analyzed for the index of refraction and film thickness for the assumption that the film is much thinner than the substrate. A Beckman Instruments Model 5270 double-monochromator spectrometer was used for these measurements at wavelengths from 190 to 2800 nm. The optical absorption coefficient at 750 nm was measured directly from the spectral transmission plot by measuring the decrease in transmission as a function of film thickness compared to a bare silica substrate.
Mechanical stress in sputter deposited coatings
(intrinsic and/or thermal expansion mismatch components) is measured by optically detecting substrate distortion after coating deposition using a high resolution Tropel Model 9000i Laser Interferometer with CRT display, camera data storage, and vacuum chuck accessory for handling thin substrates. This technique utilizes grazing incidence interferometry to measure the curvature of a nominally flat substrate. Stress levels as low as 10 MPa can be measured by this technique. The total stress in the deposited film, sm, was calculated from the stress-induced bending of the substrate. The film CTE, Af, and elastic stiffness
parameter, Ef/(l-nf) (where Ef is the elastic modulus and nf is Poisson's Ratio of the film), were calculated using the method of Retajczyk and Sinha, see G. Lucovsky, et al., J. Vac. Sci. Techol. A4 (3), 681 (1986). For this
measurement, the stress-induced bending of the SiO2 and Si substrates was measured over the temperature range 20 to 200°C by equipping the interferometer with a heated
substrate holder. The total stress was then calculated over that temperature range for each substrate, and Af and Ef/ (l- nf ) were determined using the slopes of the sT vs. temperature data. With Af and Ef/(l-nf) known, the thermal component of the total stress was calculated. Finally, the intrinsic stress component was determined by the difference between the total stress and the thermal component of the total stress. To understand the film structure and to help the property data, some films were examined on the plane surface and in cross section by optical and by scanning electron microscopy (SEM). The thick films (50 microns) were examined by x-ray diffraction (XRD) to identify crystalline phases. Selected films were polished and were examined by laser profilometry to measure surface roughness before and after optical polishing. Film densities were determined from the weight and volume of the thickness films.
A thermal comparator apparatus was assembled to measure thermal conductivity of thin films. A heated probe was brought into contact with a specimen, which consists of a film on a standard 38.5 mm (1.5 inch) Si mirror substrate held at constant temperature. A temperature difference is developed in a few seconds between the probe reference and the probe tip. This temperature difference is used to determine the thermal conductivity of the film.
A summary of measured film properties is given in Table I for the three different compositions evaluated, namely, Si:N, Si60Al40 and Si70Al30, respectively. The qualities listed in Table I are mean values for the film thickness range of 2 to 10 microns; therefore, the listed standard deviations include contributions from measurement errors and from the thickness dependence. Table I is intended mainly to illustrate property differences
resulting from film composition differences.
The refractive indices of the pure nitride films corresponded closely to the indices of bulk Si3N4 and
AlN(~2.00).
Example 2
The experimental method of Example l was repeated for the deposition of the following film materials:
Si60Al40:N. Si60Al40:N:O and Si60Al40:O. The results of these experiments are shown in Table II. Having illustrated and described the principles of my invention in a preferred embodiment thereof, it should be readily apparent to those skilled in the art that the invention can be modified in arrangement and detail without departing from such principles. We claim all modifications coming within the spirit and scope of the accompanying claims.
Table I .
Optical Film
Absorption Thermal
Index Coefficient Expansion Thermal Elastic Total Intrinsic Thermal at at 750 nm Coefficient Conductivity Stiffness Stress Stress Stress Density
Material 750 nm) (cm-1) (10-6/K. (W/cm/K) (GPa) (MPa) (q/cm3)
Si:N 1.99 - - 2.7 - - 190 -390 -400 ~0 - -
Si70Al30:N 1.99 28 2.8 0.005 140 -60 -60 ~0 3.05
Si60Al40:N 1.99 21 3.3 0.007 190 -70 -80 ~0 3. 10
Table II.
Optical Film
Absorption Thermal
Index Coefficient Expansion Thermal Elastic Total Intrinsic Thermal at at 750 nm Coefficient Conductivity Stiffness Stress Stress Stress Density Material 750 nm) (cm-1) (10-6/K) (W/cm/K) (GPa) (MPa) (q/cm3)
Si:N 1.99 - - 2.7 - - 190 -390 -400 ~0 - -
Si70Al30:N 1.99 28 2.8 0.005 140 -60 -60 ~0 3.05
(2:1 N:0)
Si60Al40:N 1.99 21 3.3 0.007 190 -70 -80 ~0 3.10 (2:1 N:0)

Claims

We claim:
1. A method for producing a low stress film-coated substrate which comprises depositing a film onto a surface of an underlying substrate, at a non-elevated operating temperature of not more than about 500°C, said film comprising a Si-Al-N-containing material or a Si-Al-O-N- containing material, and having a thickness of at least 5 microns up to about 150 microns, a relatively low film stress and a high level of adherence to said substrate, thereby avoiding substantial cracking and debonding of said film and any substantial resultant damage to said
substrate, said film further having a high level of optical transparency in the visible and infrared ranges, the optical absorption of said film being not more than about 30/cm at a wavelength of 750 nm.
2. A low stress film-coated substrate, which
comprises a Si-Al-N-containing film material or a Si-Al-O-N containing film material, having a thickness of at least 5 microns up to about 150 microns, and formed by depositing said film material onto an underlying surface of said substrate at a non-elevated temperature of not more than about 500°C, said film exhibiting a relatively low total film stress and a high level of adherence to said substrate thereby avoiding substantial cracking and debonding of said film and any resultant damage to said substrate, said film further having a high level of optical transparency in the visible and infrared ranges, the optical absorption of said film being not more than about 30/cm at a wavelength of 750 nm. 3. A low stress film material for deposition onto an underlying substrate, which comprises a Si-Al-N-containing film material or a Si-Al-O-N-containing material, having a thickness of 50 microns up to at least about 150 microns, and formed at a non-elevated temperature of not more than about 500°C, said film exhibiting a relatively low total film stress and a high level of adherence when deposited on said substrate thereby avoiding substantial cracking and debonding of said film and any resultant damage to said substrate, said film further having a high level of optical transparency in the visible and infrared ranges, the optical absorption of said film being not more than about 30/cm at a wavelength of 750 nm.
AMENDED CLAIMS
[received by the International Bureau on 28 August 1992 (28.08.92); original claims 1-3 replaced by amended claims 1-3 (2 pages)]
1. A method for producing a low stress film-coated substrate which comprises depositing a film onto a surface of an underlying substrate, at a non-elevated operating temperature of not more than about 500°C, said film
comprising a Si-Al-N-containing material, and having a thickness of at least 5 microns up to about 150 microns, a relatively low film stress and a high level of adherence to said substrate, thereby avoiding substantial cracking and debonding of said film and any substantial resultant damage to said substrate, said film further having a high level of optical transparency in the visible and infrared ranges, the optical absorption of said film being not more than about 30/cm at a wavelength of 750 nm. 2. A low stress film-coated substrate, which
comprises a Si-Al-N-containing film material, having a thickness of at least 5 microns up to about 150 microns, and formed by depositing said film material onto an
underlying surface of said substrate at a non-elevated temperature of not more than about 500°C, said film
exhibiting a relatively low total film stress and a high level of adherence to said substrate thereby avoiding substantial cracking and debonding of said film and any resultant damage to said substrate, said film further having a high level of optical transparency in the visible and infrared ranges, the optical absorption of said film being not more than about 30/cm at a wavelength of 750 nm.
3. A low stress film material for deposition onto an underlying substrate, which comprises a Si-Al-N-containing film material, having a thickness of 50 microns up to at least about 150 microns, and formed at a non-elevated temperature of not more than about 500°C, said film
exhibiting a relatively low total film stress and a high level of adherence when deposited on said substrate, thereby avoiding substantial cracking and debonding of said film and any resultant damage to said substrate, said film further having a high level of optical transparency in the visible and infrared ranges, the optical absorption of said film being not more than about 30/cm at a wavelength of 750 nm.
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