Abstract:
Multinary alloys, in particular for use as coatings, if appropriate in combination with other types of layers, for components which are exposed to high temperatures and corrosive gases. The alloys are of the general form: Al—Ni—Ru-M, where at least one B2 phase is present, the aluminum content being in the range from 26–60 atomic percent and where M may be one or more metals and/or semimetals selected from the group consisting of: precious metal, transition metal, rare earths, semimetal. Multinary alloys of this type are very stable with respect to oxidation, have a low thermal conductivity and in particular have similar coefficients of thermal expansion to superalloys, which are usually used as substrates for protective coatings of this type in gas turbine components.

Description:
This application claims priority under 35 U.S.C. § 119 to German application number 103 32 420.8, filed 16 Jul. 2003, the entirety of which is incorporated by reference herein. 
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to alloys, in particular for use as heat- and corrosion-resistant coatings, if appropriate in combination with other types of layers, for components which are exposed to high temperatures and corrosive gases. The present invention also relates to processes for producing coatings from alloys of this type in particular on substrates formed from superalloys, and to the use of coatings of this type in particular for coating components of gas turbines or jet engines. 
     2. Brief Description of the Related Art 
     Numerous works have dealt with analysis of the thermodynamic stability, mechanical properties and corrosion resistance of the Al—Ru and Al—Ni—Ru B2 alloys. The B2 phase is an ordered cubic phase AB in which the A atoms are arranged at the corners of the unit cell and the B atoms are arranged in the center of the unit cell (cP2- CsCl structure type). B2 Al—Ru is a thermodynamically stable phase which melts congruently at the very high temperature of 2050° C. (cf. in this respect Massalski T. B. (Editor), Binary alloy phase diagrams, 2nd edition OH: ASM International, (1990), 1, 203) and contains a significant amount of aluminum, which is required in order to form the layer of aluminum deposits which provides protection against oxidation. Surprisingly good mechanical properties, including satisfactory mechanical formability at room temperature, are other attractive properties of the Al—Ru B2 phases (cf. in this respect U.S. Pat. No. 5,152,853; Fleischer R. L., (1991), Metall. Trans. A, 22A, 403; U.S. Pat. No. 5,011,554; Wolff I. M., Sauthoff G., (1996), Metall. And Mater. Trans. A, 27A, 2642). Moreover, it has been reported that the oxidation resistance of B2 ruthenium aluminide can be significantly improved by an alloy with a small proportion of yttrium (up to 1 atomic %) and chromium (up to 5 atomic %) (cf. in this respect McKee D. W., Fleischer R. L., (1991), Mat. Res. Soc. Symp. Proc., 213, 969; and Wolff I. M., Sauthoff G., Cornish L. A., Steyn H. DeV., Coetzee R., (1997), Structural Intermetallics, ed. Nathal D. B. et al, 815). 
     Currently the only intermetallic B2 compounds whose thermal conductivity has been investigated are the following: AlNi, AlFe and AlCo (cf. in this respect Terada Y., Ohkubo K., Nakagawa K., Mohri T., Suzuki T., (1995), Intermetallics, 3, 347; and Reddy B. V., Deevi S. C., (2000), Intermetallics, 8, 1369). 
     The Al—Ni—Ru phase diagram has been investigated at different temperatures (cf. in this respect Tsurikov V. F., Sokolovskaya E. M., Kazakova E. F., (1980), Vestnik Moskovskogo Univ. Khim., 35(5), 113; Petrovoj L. A., (1985), Diagrammy Sostoyaniya Metallicheskikh System, ed. N. V. Ageeva, VINITI, Moskau, 30, 323; Chartavorty S., West D. R. F., (1985), Scripta Metall., 19, 1355; Chartavorty S., West D. R. F., (1986), J. Mater. Sci., 21, 2721; Homer I. J., Hall N., Cornish L. A., Witcomb M. J., Cortie M. B., Boniface T. D., (1998), J. Alloys and Compds, 264, 173; Homer I. J., Cornish L. A., Witcomb M. J., (1997), J. Alloys and Compds, 256, 221; Hahls J., Cornish L. A., Ellis P., Witcomb M. J., (2000), J. Alloys and Compds, 308, 205). The information available in connection with these studies varies noticeably. Tsurikov et al. report two B2 phases, which are based on AlNi and AlRu, in a ternary system at 550° C. (cf. in this respect Tsurikov V. F., Sokolovskaya E. M., Kazakova E. F., (1980), Vestnik Moskovskogo Univ. Khim., 35(5), 113), asserting that AlRu (β1) is able to dissolve up to 8 atomic % of nickel, and AlNi (β2) is supposed to be able to dissolve up to 5 atomic % of ruthenium. By contrast, Petrovoj found an unlimited solubility between the two B2 phases at 800° C. within the ternary system (cf. in this respect Petrovoj L. A., (1985), Diagrammy Sostoyaniya Metallicheskikh System, ed. N. V. Ageeva, VINITI, Moskau, 30, 323). Chakrovorty et al. have indicated a miscibility gap between AlRu and AlNi up to high temperatures and have recorded the existence of a ternary equilibrium state β1–β2-γ′ (cf. in this respect Chartavorty S., West D. R. F., (1985), Scripta Metall., 19, 1355; Chartavorty S., West D. R. F., (1986), J. Mater. Sci., 21, 2721). 
     More recent works have described a continuous solid solution between AlRu and AlNi phases, although all specimens produced (using the casting process) had two phases, and annealing was in each case carried out for only a short time (less than 48 hours) (cf. in this respect Homer I. J., Hall N., Cornish L. A., Witcomb M. J., Cortie M. B., Boniface T. D., (1998), J. Alloys and Compds, 264, 173; Homer I. J., Cornish L. A., Witcomb M. J., (1997), J. Alloys and Compds, 256, 221; Hahls J., Cornish L. A., Ellis P., Witcomb M. J., (2000), J. Alloys and Compds, 308, 205). The authors have explained the two phases in the specimen on the basis of a so-called “coring effect”, which is supposed to occur on account of the different crystallization initiation for phases with very divergent solidus temperatures. This effect is supposed to be revealed by unclear boundaries between the grains and by the variation in the grain compositions. 
     Oxidation-resistant coatings based on nickel aluminides (nickel-aluminum alloys) which have been modified by precious metals, preferably by platinum, are already known (cf. in this respect Wolff I. M., (2002) in Intermetallic Compounds, ed. Westbrook J. H. and Fleischer R. L., 3, 53; Datta P. K., (2002) in Intermetallic Compounds, ed. Westbrook J. H. and Fleischer R. L., 3, 651; U.S. Pat. No. 4,447,538; U.S. Pat. No. 5,763,107; U.S. Pat. No. 5,645,893; U.S. Pat. No. 5,667,663; U.S. Pat. No. 5,981,091; U.S. Pat. No. 5,942,337; Lamesle P., Steinmetz P., Steinmetz J., Alperine S., (1995), J. Electrochem. Soc., 142(2), 497). The main advantage of coatings of this type compared to MCrAlY bond coatings (BC) is the improved bonding of the outer layer of a thermally insulating oxide (normally yttrium-stabilized zirconium, YSZ) to the metallic substrate. This bonding is effected by the formation of a pure, slow-growing α-Al 2 O 3  layer at the interface between YSZ/BC during operation. Unfortunately, the platinum group metals which can be used as materials for thermal barrier coatings (TBC) have some drawbacks. These include, for example, the very high price of the metals, the depletion of aluminum in those interlayers which are enriched with precious metal, the high vapor pressure of the metals and volatility of the oxides which primarily occur (platinum dioxide, rhodium dioxide, etc.). This leads to a significant loss of the valuable metals during exposure to the aggressive, oxidizing environment at high temperatures (cf. in this respect Datta P. K., (2002) in Intermetallic Compounds, ed. Westbrook J. H. and Fleischer R. L., 3, 651; Kofstad P., (1988), High temperature corrosion, Elsevier applied science publishers LTD; Jehn H., (1984), J. Less-Common Met., 100,321). 
     Oxidation-resistant alloys which contain ruthenium have also already been investigated, and corresponding coating methods have already been developed (cf. in this respect U.S. Pat. No. 4,980,244; U.S. Pat. No. 4,759,380). The alloys studied probably consisted of a mixture of B2-CrRuAl and CrRuFeAl phases and an Ru- or Cr-based solid solution. A separate α-Cr phase was assumed in some compositions. The authors investigated CrRuAl alloys within the composition range from 0 to 60 atomic % in chromium, where the Ru:Al ratio was kept at approximately 50:50 in CrRuFeAl alloys. The best oxidation properties were discovered for alloys with a chromium content of between 30 and 60 atomic %. The CrRuFeAl and CrRuAl alloys have already been proposed as high-temperature protective coatings for different materials: superalloys, refractory metals or alloys with a refractory metal base, titanium or niobium aluminides, etc. Another possible application for Ru-containing phases is as a diffusion barrier for TBCs in order to prevent interdiffusion between the substrate and the bond coat (BC) (cf. in this respect U.S. Pat. No. 6,306,524). CrRuFeAlY alloys containing structural high-temperature materials have likewise already been investigated (cf. in this respect U.S. Pat. No. 6,306,524). 
     SUMMARY OF THE INVENTION 
     Accordingly, the invention is based on the object of proposing a novel material from which coatings for surfaces exposed to high temperatures and a corrosive environment can particularly preferably be produced. 
     The solution to this object is achieved by the proposal of a multinary alloy, i.e. an alloy which contains more than three different components, of the general form Al x Ni y Ru z M u , which includes at least one B2 phase, where x, y, z and u are atomic percentages of the overall alloy, where the aluminum content is in the range from 20–60 atomic percent or preferably 26–60 atomic percent, i.e. where x=26–60; y&gt;0; z&gt;0; u&gt;0, and where M may be one or more metals and/or semimetals selected from the group consisting of: Ir, Pt, Rh, Pd, Cr, Fe, Co, Re, Ta, Ti, Zr, Hf, Y, Sc, Si, and B. A B2 phase is an ordered cubic phase AB in which the A atoms are arranged at the corners and the B atoms are arranged in the center of the unit cell (cP2-CsCl type structure). 
     The core of the invention therefore consists in the unexpected fact that the addition of the component M to an alloy of type Al—Ni—Ru makes it possible to produce properties which are highly advantageous for coatings, in particular on substrates made from superalloys. The Al—Ni—Ru-M alloys contain at least one B2 structure-based phase. If phases of this type are used as coatings, they allow both a substantial gain in performance and service life and a reduction in the maintenance costs for gas turbines and jet engine components. The Al—Ni—Ru-M alloys have a number of properties, namely: 
     (1) Greatly increased stability with respect to oxidation compared to commercially available MCrAlY bond coats (BC) in which M is normally Co, Ni or Co/Ni. 
     (2) Amazingly low thermal conductivity compared to other intermetallic compounds, including conventional B2 phases. 
     (3) Satisfactory plastic deformability and other mechanical properties which are characteristic of ruthenium aluminides. 
     (4) High melting points, which ensure correspondingly low diffusion rates within the alloys. 
     (5) Thermal expansion coefficients which are close to those of the substrates made from superalloys. 
     These Al—Ni—Ru-M alloys can therefore be used as coatings which protect against environmental influences and as thermal barriers for blades and vanes of gas turbines and jet engines used in high-temperature and corrosive environments. 
     It should be noted that this alloy may also contain other components in small amounts, e.g. as impurities, provided that the properties as a thermal and corrosion-inhibiting barrier layer are retained. 
     By way of example, it is also possible to use combinations such as Al—Ni—Ru—Ir, Al—Ni—Ru—Si, but also alloys such as Al—Ni—Ru—Cr—Ir, etc., i.e. with more than one component of type M, with the corresponding advantageous properties. 
     Combinations with either a single component M or with two different components of this type are particularly advantageous. 
     According to a first preferred embodiment of the alloy according to the invention, x=26–60, preferably x=40–55. As an alternative or in addition, y may be 10–50, preferably y=10–40. It is also possible for z to be selected in the range from 5–40, preferably z=10–35, and/or for y+z to be in the range from 30–70, preferably in the range from y+z=35–55. The variable u is preferably set within the following range: O&lt;u&lt;=40, preferably u=5–30. 
     According to a further preferred embodiment, the alloy is distinguished by the fact that it includes at least two different, thermodynamically stable phases of type B2. It has been found that if two such phases with different compositions are present, particularly advantageous properties of the coatings are obtained. 
     Furthermore, the present invention relates to a process for producing a compound as described above in which the components are melted together under shielding gas. This melting operation can be carried out in an arc. 
     It has proven particularly advantageous for the compound to be annealed after it has been melted together under shielding gas, particularly preferably in a furnace. This takes place, for example, at a temperature in the range from 900 to 1100 degrees Celsius for a time of more than one week, preferably in the region of 4 weeks. After the annealing, the material is advantageously cooled in the furnace. The annealing may in this case be carried out in a structured manner, for example stepwise, in which case it is possible to use a scheme with a temperature which increases in steps or decreases in steps or a combination of such schemes. 
     A preferred embodiment of the process according to the invention is characterized in that the compound is applied to a material as a coating, in particular to a substrate made from a superalloy, for which purpose it is possible to use in particular processes such as plasma spraying (e.g. air plasma spraying, APS; vacuum plasma spraying, VPS; low-pressure plasma spraying, LPPS) or high-velocity methods (e.g. high-velocity oxyfuel spraying, HVOF), if appropriate followed by annealing and/or by aluminizing. 
     Moreover, the present invention relates to the use of a compound or alloy as described above, preferably produced according to one of the processes as described above. The material is in this case to be used as material for a component which is exposed to high temperatures and which in particular is exposed to hot, possibly corrosive gases and/or has hot gases flowing around it. This may be a component of a gas turbine or a compressor or a jet engine, particularly preferably a blade or guide vane of a gas turbine or a compressor or a jet engine. 
     In this context, it is preferable for the compound to be in the form of a coating, particularly preferably for the surface which is directly exposed to the hot gases, with a further functional layer, in particular for promoting bonding or for providing a further barrier action, optionally being present beneath the coating. Alternatively, however, it is also possible for a further layer, for example of yttrium-stabilized zirconium, to be provided on a layer of material according to the invention. A coating of this type may have a thickness in the range from 10–400 μm, particularly preferably in the range from 100 to 200 μm. 
     Furthermore, the present invention relates to a coating with an alloy as described above and/or a part or component of a gas turbine or steam turbine or of a jet engine having a coating of this type. In this case, the alloy of type Al—Ni—Ru-M is typically applied to a substrate made from superalloy, which has optionally been covered with a bond coat preferably of type MCrAlY (BC, in which M is normally Co, Ni or Co/Ni). The layer of the alloy according to the invention in this case, by way of example, has a thickness in the range from 100–500 μm. It is optionally possible for a further ceramic layer, in particular of yttrium-stabilized zirconium (YSZ), to be arranged on this layer of the alloy. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The invention is to be explained in more detail below on the basis of exemplary embodiments in conjunction with the drawings, in which: 
         FIG. 1  shows diagrammatic illustrations of possible thermal barrier coatings made from Al—Ni—Ru-M alloys, in which the upper side is exposed to the gases; 
         FIG. 2  shows an example of the characterization of alloy 4 and alloy 5, a) X-ray diffractogram (λ=Cu) for alloy 4 annealed at 900° C., b) SEM image for alloy 4, c) X-ray diffractogram (λ=Cu) for alloy 5 annealed at 900° C., d) SEM image for alloy 5; 
         FIG. 3  shows an isothermal section through the phase diagram of AlNiRu at 900° C., in which solid lines denote known equilibrium states including known tie lines, dashed lines indicate predicted equilibria, and the regions comprising β phases are hatched; 
         FIG. 4  shows the increase in weight of Al—Ni—Ru-M B2 alloys compared to commercially available MCrAlY as a function of the oxidation time under laboratory atmosphere at a) 950° C. and b) 1050° C.; 
         FIG. 5  shows the oxidation characteristics of the ruthenium-rich alloys 9 and 13, a) X-ray diffractogram for 9; b) X-ray diffractogram for 13, in which a square standing on end in each case indicates the β phase, a circle represents the α-Al 2 O 3  phase and a square on its side represents Ru, c) SEM image for 9, d) SEM image for 13, with the oxidation at 950° C. in each case indicated on the left-hand side and the oxidation at 1050° C. in each case indicated on the right-hand side; 
         FIG. 6  shows the oxidation characteristics of a nickel-rich alloy 11, a) X-ray diffractogram, in which a square standing on end in each case represents the β phase, a circle represents the α-Al 2 O 3  phase and a square resting on its side represents Ru, b) SEM image of a specimen oxidized at 950° C., c) SEM image of a specimen oxidized at 1050° C.; 
         FIG. 7  shows the oxidation characteristics of alloy 14, a) X-ray diffractogram, in which a square standing on end in each case represents the β phase, a circle represents the α-Al 2 O 3  phase and a square resting on its side represents Ru, b) SEM image of a specimen oxidized at 950° C., c) SEM image of a specimen oxidized at 1050° C.; 
         FIG. 8  shows thermal conductivities for B2 alloys, a) temperature dependency of the thermal conductivity of Al—Ni—Ru-M alloys compared to AlFe, in which the data for AlFe originate from Reddy B. V., Deevi S. C., (2000), Intermetallics, 8,1369, b) dependency of the thermal conductivity of various B2 alloys on the Al concentration at room temperature (data from Terada Y., Ohkubo K., Nakagawa K., Mohri T., Suzuki T., (1995), Intermetallics, 3,347); and 
         FIG. 9  shows X-ray diffractograms for B2 structure-based Al 50 Ni 40 Ru 10  coatings which have been obtained using vacuum plasma spraying (VPS) and plasma methods (air plasma spraying APS) compared to the original annealed alloy. 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Thermal degradation and oxidation of components of gas turbines or jet engines under the simultaneous action of high temperature and oxidation or a corrosive environment restrict the possible operating temperature (which reduces the possible efficiency of the turbine) and lead to a reduction of the service life of the components (with an associated increase in maintenance costs). A modem system protecting against thermal loading and oxidation may generally be considered as a three-layer structure: a superalloy substrate SX based on nickel (Ni), a bond coat (BC, MCrAlY or nickel aluminides) and an outer layer of a thermally insulating oxide (thermal barrier coating, TBC, normally YSZ). 
     Unfortunately, composite structures assembled in this way lead to spallation of the YSZ layer in hot and aggressive environments. This occurs on account of a poor match between the coefficients of thermal expansion of the metallic and ceramic parts of the component, on account of the formation of a mixture of different oxides, with the inclusion of spinels, which form at the interface between YSZ/BC, on account of harmful interdiffusion, etc. On the other hand, YSZ, in addition to its unique thermal insulation properties, also has a number of drawbacks, specifically for example inadequate mechanical integrity, high relative density, oxygen permeability, etc. 
     During systematic analysis of Al—Ni—R-M alloys with a B2-type-based structure, it can be observed that these alloys have very high melting points and are highly stable with respect to oxidation yet have an unexpectedly low thermal conductivity. Accordingly, these B2 Al—Ni—Ru-M alloys may perform various functions, such as 
     (i) protection against oxidation, 
     (ii) as a bond coat, and 
     (iii) thermal insulation. 
     The alloys can be used as BC together with or instead of existing types of bond coats. Possible layer structures are summarized in  FIG. 1 .  FIG. 1   a ) shows a structure in which the proposed layer is located between the YSZ layer arranged at the surface and the BC layer arranged directly on the superalloy SX. In a structure of this type, the layer of MCrAlY BC typically has a thickness of from 100 to 300 μm, the layer of AlNiRuM typically has a thickness of from 100 to 300 μm, and the layer of YSZ typically has a thickness of from 100 to 300 μm. The thickness is in this case dependent on the manner of application, for example in the case of APS a layer of YSZ with a thickness in the range from 100–400 μm is produced, whereas in the case of EBPVD (electron beam physical vapor deposition) a thickness of 100–150 μm is produced. In  FIG. 1   b ), the BC layer is omitted and the proposed layer is located between the surface layer of YSZ and the layer of superalloy SX. Composite structures of this type ensure improved adhesion of the YSZ layer to the metallic parts of the component and, moreover, ensure a significantly improved resistance to oxidation and/or corrosion. The layer of AlNiRuM in this case typically has a thickness of from 100 to 300 μm, and that of YSZ typically has a thickness of from 100 to 300 μm. 
     Alternatively, the Al—Ni—Ru-M alloys of a certain composition may be used instead of the BC and YSZ layers and may at the same time perform the abovementioned functions of the bond coat and the TBC function of YSZ. This covering coating comprising just one layer will have a significantly greater resistance to mechanical cracking than the existing multilayer compositions.  FIG. 1   c ) shows an arrangement in which the proposed layer is at the surface and is located above a BC layer on the layer of superalloy SX. In a structure of this type, the layer AlNiRuM typically has a thickness of from 300 to 800 μm, while that of MCrAlY BC has a thickness of from 100 to 300 μm. Lastly,  FIG. 1   d ) illustrates a structure in which just a single layer of the proposed material is arranged on the layer of superalloy SX. The single layer of AlNiRuM in a structure of this type typically has a thickness of from 300 to 1000 μm. 
     Experimental Data 
     The Al—Ni—Ru-M alloys were melted in an arc melting process using a permanent electrode made from tungsten under argon atmosphere with a titanium-oxygen getter in a water-cooled copper furnace. Then, the cast alloys were annealed under an argon atmosphere at 900° C. or 1100° C. for 4 weeks. The original composition, the annealing states and the results of the study are compiled in Table 1 and in  FIG. 2 and 3 . 
     
       
         
               
             
               
               
               
               
               
               
             
               
               
               
               
               
               
               
               
             
               
               
               
               
               
               
               
               
             
           
               
                 TABLE 1 
               
             
             
               
                   
               
               
                 Characterization of Al-Ni-Ru-M alloys, annealed at 900 or 1100° C. for 4 weeks 
               
             
          
           
               
                   
                   
                   
                   
                   
                 Solidus/ 
               
               
                   
                 Overall 
                 Annealing 
                 Phase 1 
                 Phase 2 
                 liquidus 
               
             
          
           
               
                 No. 
                 composition 
                 T, ° C. 
                 Composition 
                 Structure 
                 Composition 
                 Structure 
                 T, ° C. 
               
               
                   
               
             
          
           
               
                  1 
                 Al 46 Ni 28 Ru 26   
                 900 
                 Al 46 Ni 18 Ru 36   
                 β1(B2) 
                 Al 465 Ni 35 Ru 185   
                 β2(B2) 
                 — 
               
               
                  2 
                 Al 43 Ni 29 Ru 28   
                 900 
                 Al 46 Ni 17 Ru 37   
                 β1(B2) 
                 Al 28 Ni 64 Ru 8   
                 γ 
                 — 
               
               
                  3 
                 Al 515 Ni 265 Ru 22   
                 900 
                 Al 64 Ni 2 Ru 34   
                 Al 2 Ru 
                 Al 505 Ni 29 Ru 205   
                 β2(B2) 
                 — 
               
               
                  4* 
                 Al 65 Ni 20 Ru 15   
                 900 
                 Al 65 Ni 4 Ru 31   
                 Al 2 Ru 
                 Al 60 Ni 36 Ru 4   
                 Al 3 Ni 2   
                 — 
               
               
                  5 
                 Al 50 Ni 37 Ru 10 Si 3   
                 900 
                 — 
                 — 
                 Al 50 Ni 37 Ru 10 Si 3   
                 β2(B2) 
                 &gt;1500 
               
               
                  6 
                 Al 47 Ni 37 Ru 10 Fe 6   
                 1100 
                 — 
                 — 
                 Al 47 Ni 37 Ru 10 Fe 6   
                 β2(B2) 
                 &gt;1500 
               
               
                  7 
                 Al 46 Ni 34 Ru 10 Fe 10   
                 1100 
                 Al 46 Ni 28 Ru 17 Fe 9   
                 β1(B2) 
                 Al 46 Ni 36 Ru 7 Fe 11   
                 β2(B2) 
                 1590/1800 
               
               
                  8** 
                 Al 46 Ni 28 Ru 9 Fe 17   
                 1100 
                 Al 50 Ni 24 Ru 10 Fe 16   
                 β1(B2) 
                 Al 22 Ni 47 Ru 3 Fe 28   
                 γ 
                 — 
               
               
                  9 
                 Al 45 Ni 12 Ru 43   
                 900 
                 Al 45 Ni 12 Ru 43   
                 β1(B2) 
                 — 
                 — 
                 &gt;2100 
               
               
                 10 
                 Al 46 Ni 29 Ru 25   
                 900 
                 Al 46 Ni 18 Ru 36   
                 β1(B2) 
                 Al 465 Ni 35 Ru 185   
                 β2(B2) 
                 1870/2090 
               
               
                 11 
                 Al 44 Ni 45 Ru 11   
                 900 
                 — 
                 — 
                 Al 44 Ni 45 Ru 11   
                 β2(B2) 
                 1745/1875 
               
               
                 12 
                 Al 42 Ni 48 Ru 10   
                 900 
                 Al 28 Ni 69 Ru 4   
                 γ 
                 Al 43 Ni 46 Ru 11   
                 β2(B2) 
                 1645/1910 
               
               
                 13 
                 Al 45 Ni 235 Ru 29 Cr 25   
                 900 
                 Al 45 Ni 185 Ru 345 Cr 2   
                 β1(B2) 
                 Al 45 Ni 305 Ru 21 Cr 35   
                   
                 1830/2080 
               
               
                 14 
                 Al 44 Ni 29 Ru 24 Ir 3   
                 900 
                 Al 44 Ni 19 Ru 335 Ir 35   
                 β1(B2) 
                 Al 44 Ni 40 Ru 145 Ir 15   
                 β2(B2) 
                 1880/2100 
               
               
                   
               
               
                 *Alloy also contains small quantities of a phase based on Al 13 Ru 4   
               
               
                 **Alloy also contains small quantities of a phase based on Al 2 Ru. 
               
             
          
         
       
     
       FIG. 2  shows examples of the characterization of alloys of type Al—Ni—Ru. In this figure, a) shows a powder X-ray diffraction pattern (XRD) using λ-Cu radiation for alloy of type 4 from Table 1, annealed at 900° C.  FIG. 2   b ) shows images from a scanning electron microscope (SEM, in back-scatter) for alloy 4, with the light phase representing the β1-Al 46 Ni 18 Ru 36  and the dark phase representing the β2-Al 46.5 Ni 45 Ru 8.5 .  FIG. 2   c ) once again shows powder X-ray diffraction patterns (XRD) using λ-Cu radiation for the alloy of type 5 from Table 1, annealed at 900° C.  FIG. 2   e ) shows images taken by a scanning electron microscope (SEM, in back-scatter) for alloy 5, with the light phase representing the β1-Al 46 Ni 17 Ru 37  and the dark phase representing the γ′-Al 28 Ni 64 Ru 8 . 
       FIG. 3  shows an isothermal section through the phase diagram of AlNiRu at 900° C. In this figure, solid lines indicate known equilibrium states, including known tie lines. Dashed lines indicate predicted equilibria. The regions comprising βphases are hatched. 
     To investigate the physical properties, specimens were partially remelted, with a view to closing up pores which are present at the surface. Moreover, they were subjected to a high isostatic pressure procedure (HIP), cf. in this respect Table 2. 
     
       
         
               
             
               
               
               
               
               
               
               
             
           
               
                 TABLE 2 
               
             
             
               
                   
               
               
                 Parameters used for the HIP 
               
             
          
           
               
                 Speci- 
                   
                 Temperature 
                 Pressure 
                   
                   
                 Duration of 
               
               
                 mens 
                 State 
                 (° C.) 
                 (bar) 
                 Vessel 
                 Filler 
                 the HIP (h) 
               
               
                   
               
               
                 9–14 
                 Bulk 
                 1360 
                 1300 
                 Stainless 
                 BN 
                 3 
               
               
                   
                   
                   
                   
                 steel 
               
               
                   
               
             
          
         
       
     
     All these alloys were analyzed using X-ray powder diffraction methods (XRD). A scintag X-ray powder diffractometer with a germanium detector using copper radiation was used. Scanning electron microscope images (SEM) were carried out in back-scatter mode at 10 kV acceleration voltage in a Hitachi S-900 “in-lens” field emission scanning electron microscope with a standard Everhard-Thornley SE detector and a YAG-type BSE detector. Energy-dispersive X-ray spectroscopy (EDS) was carried out at an acceleration voltage of 15 to 30 kV, using a “LEO 1530” analyzer using the VOYAGER software package. Electron microprobe analysis (EPMA) was carried out using a “CAMECA SX50” microanalyzer. The result was that it was possible to unambiguously confirm the existence of a miscibility gap between AlRu and AlNi phases in the ternary AlNiRu system. 
     The phase transition temperatures were determined using differential thermal analysis (DTA) on a “Perkin Elmer DTA 7” appliance up to a temperature of 1500° C. using aluminum trioxide crucibles under high-purity argon with heating and cooling rates of 10° C. per minute. A differential thermal appliance “HT-DTA-3” was used to measure melting points above 1500° C., as described in Kocherzhinskiy Y. A., Shishkin E. A., Vasilenko V. I., (1971), Phase diagrams of the metallic systems, ed. Ageev N. V. and Ivanov O. S., Moskau: Nauka, 245. It was operated up to 2200° C. using hafnium dioxide and scandium trioxide crucibles using W/W-20Re thermoelectric elements under high-purity helium with heating and cooling rates of 50° C. per minute. The melting points of Al—Ni—Ru-M alloys are compiled in Table 1. All the specimens analyzed had high melting points, making these alloys predestined for use as high-temperature coatings. The highest melting point observed among the alloys studied even exceeds 2100° C. 
     Oxidation tests were carried out under standard atmosphere at 950° C. and 1050° C. using MCrAlY as internal standard. The oxidation of Al—Ni—Ru-M B2 alloys is slower than that of commercially available MCrAlY, cf. in this respect  FIG. 4 . The protective α-Al 2 O 3  surface layer is developed after just 100 to 150 hours under oxidation at 950° C. and 1050° C. This protective layer is (i) single-phase, (ii) dense, (iii) does not contain any significant level of nickel or ruthenium and (iiii) has good bonding to the coating. A dense, continuous ruthenium underlayer is formed between the α-Al 2 O 3  layer and the alloy for a composition with a ruthenium content of &gt;25 atomic %. The layer may (i) contain significant quantities of chromium or iridium and (ii) has good bonding to the surface layer and to the coating. There are no significant differences in the oxidation mechanism of Al—Ni—Ru-M B2 alloys at 950° C. and 1050° C., cf. in this respect  FIGS. 5 to 7 . The oxidation resistance of the studied B2-based structures formed from nickel-ruthenium aluminides is significantly better than that measured for the reference alloy MCrAlY. 
     Laser flash methods were used to measure the thermal conductivity. It was measured in an appliance of type “TC-3000H/L SINKU-RIKO” as described in the following references: Parker W. J., Jenkins R., Burner C. P., Abort G. L., (1961), J. Appl. Phys., 32(9), 1679; Namba S., Kim P. H. and Arai T., (1967), J. Appl. Phys., 36(8), 661. Al—Ni—Ru-M B2 alloys of a certain composition had a surprisingly low thermal conductivity compared to other intermetallic compounds, including conventional B2 phases. The ternary Al—Ni—RuB2 alloys already have a lower thermal conductivity than Al—Ni and Al—Co B2 structure-based phases. If ruthenium is substituted for iron, the thermal conductivity is reduced by approximately a factor of 3 at room temperature, cf. in this respect  FIG. 8 . 
     The measurements of the coefficients of thermal expansion (CTE) were carried out using an appliance of type DIL 402C (push-rod) dilatometer, produced by NETZSCH. The specimens were cut into rods with a diameter of 5 mm and a length of approximately 5 mm. The appliance was operated in a temperature range from 20° C. to 1000° C. The temperature was changed at a rate of 5° C. per minute. The reproducibility was verified by measuring each specimen 3 times. The measurements were carried out under an argon atmosphere, which was sufficient to prevent oxidation. 
     The good correspondence between the coefficients of thermal expansion of B2 structure-based Al—Ni—Ru-M alloys and those of the substrates made from advanced CMSX-4 alloy can be seen from Table 3. 
     
       
         
               
             
               
               
               
             
               
               
               
             
               
               
               
             
           
               
                 TABLE 3 
               
             
             
               
                   
               
               
                 Technical coefficients of thermal expansion 
               
               
                 α = [(1/1 0 )/ΔT][×10 −6 , K −1 ] 
               
               
                 for the B2 structure-based alloys 8 (Al 46 Ni 28 Ru 9 Fe 17 ) 
               
               
                 and advanced CMSX-4 alloy. 
               
             
          
           
               
                   
                 α[×10 −6 , K −1 ] 
                   
               
             
          
           
               
                   
                   
                 Advanced 
               
               
                 T, ° C. 
                 Alloy 8 
                 CMSX-4 
               
               
                   
               
             
          
           
               
                 20 
                 — 
                 — 
               
               
                 100 
                 12.75 
                 11.59 
               
               
                 200 
                 13.80 
                 11.99 
               
               
                 300 
                 14.17 
                 12.33 
               
               
                 400 
                 14.49 
                 12.68 
               
               
                 500 
                 15.02 
                 13.03 
               
               
                 550 
                 15.32 
                 13.22 
               
               
                 600 
                 15.55 
                 13.41 
               
               
                 650 
                 15.73 
                 13.61 
               
               
                 700 
                 15.85 
                 13.82 
               
               
                 750 
                 15.92 
                 14.05 
               
               
                 800 
                 15.96 
                 14.30 
               
               
                 850 
                 16.03 
                 14.57 
               
               
                 900 
                 16.11 
                 14.87 
               
               
                 950 
                 16.16 
                 15.23 
               
               
                 1000 
                 16.19 
                 15.66 
               
               
                   
               
             
          
         
       
     
     The original alloys for the coating were produced in a vacuum induction melting furnace under 140 mbar partial pressure of high purity 8.4 argon at 75 kW 2000 Hz and in a magnesium oxide crucible at a temperature of approximately 1800° C. 
     A powder was formed using the “counter-stream milling method” using an appliance of type 100 AFG (HOSOKAWA ALPINE AG &amp; Co. OHG, Germany) under a nitrogen atmosphere. The measured parameters were d 50 =30 μm, d 100 =63 μm. The Malvern method was used to measure the particle size distribution. 
     The coatings were applied to the substrates made from superalloy SX, which consisted of advanced CMSX-40® (Cannon Muskegon Corporation, Michigan, US), using methods such as vacuum plasma spraying (VPS), plasma methods (air plasma spraying, APS) and high-velocity oxy-fuel (HVOF). The thickness of the coating of Al—Ni—Ru-M varied from 100 to 300 μm. 
     The compatibility between the coatings and the superalloy substrates SX was investigated using the diffusion coupling approach. The diffusion pairs were brought together by annealing cylindrical specimens in molybdenum vessels at 1100° C. under a vacuum of 10 −6  bar for 15 hours, followed by annealing at the same temperature and in vacuo for 50 hours without any additional mechanical pressure loading. 
     The analysis of coatings using XRD, SEM, EDS, EPMA and WD-XRF methods (wavelength dispersive X-ray fluorescence) confirmed their B2-based structure. The WD-XRF measurements were carried out using an appliance of type Analytical PW2400 (PANalytical) produced by Philips with an Rh X-ray tube at the Eidgenössischen Materialprüfungs- and Forschungsanstalt EPMA Dübendorf. The UniQuant4 software package was used for data processing. 
     The sufficient hardness and low porosity of the coatings can be seen from Table 4. 
     
       
         
               
             
               
               
               
             
               
               
               
             
           
               
                 TABLE 4 
               
             
             
               
                   
               
               
                 Hardness (Vickers hardness Hv) and porosity 
               
               
                 of B2 structure-based alloys of 
               
               
                 type Al 50 Ni 40 Ru 10   
               
             
          
           
               
                 Coating method 
                 Hv, 300 g, 30 s 
                 Porosity (%) 
               
               
                   
               
             
          
           
               
                 APS 
                 425.78 
                 8.5 
               
               
                 VPS 
                 629.63 
                 5.3 
               
               
                   
               
             
          
         
       
     
     The instrumentation used to measure the microhardness was as follows: A Zeiss Axioplan Microscope to generate an optical image, a Panasonic WV CD 50 instrument, CCD camera for recording the image, SONY monitor for representing the digitized image and ANTON PAAR MHT-4 computer for calculating the microhardness values from the applied load and the measured diagonals. 
     The porosity of the coatings was determined using the AnalySis software package (Soft Imaging System GmbH, Germany) with the aid of the scanning electron microscope images. 
     By way of non-limiting examples, an alloy or coating embodying principles of the present invention can have one or more of the following characteristics: M=Y and 0&lt;u≦0.5; the alloy has a thermal conductivity at room temperature of less than 6 Wm −1 K 1 ; the alloy has a thermal conductivity at 10000° C. of less than 15 Wm −1 K −1 ; the alloy has a coefficient of thermal expansion (CTE) of(10–20) 10 −6 K −1  in a temperature range from room temperature to 10000° C.; M=Ir, Pt, Rh, or Pd, and u=2–5; M=Cr and u=2–10; M=Fe and u=7–12; M=Zr or Hf, and 0≦u≦1; M=Y or Sc, and 0≦u≦1; M=Si, B, Nb, Mo, or W, and 0≦u≦2; M=Re or Ti, and 0≦u≦5; M=Ta and 0≦u≦10; x=46, y=34, z=10, and u=10; the CTE is (14–17) 10 −6  K 31 1  in a temperature range from room temperature to 10000° C.; the multinary alloy coating has a thickness up to 2000 μm; and the YSZ has a thickness in the range from 50–300 μm. 
     
       
         
               
             
               
               
               
             
           
               
                   
               
               
                 LIST OF DESIGNATIONS 
               
               
                   
               
             
             
               
                   
               
             
          
           
               
                   
                 YSZ 
                 Yttrium-stabilized zirconium 
               
               
                   
                 BC 
                 Bond coat 
               
               
                   
                 SX 
                 Superalloy 
               
               
                   
                 TBC 
                 Thermal barrier coating 
               
               
                   
                 XRD 
                 X-ray diffraction 
               
               
                   
                 SEM 
                 Scanning electron microscopy 
               
               
                   
                 HIP 
                 High isostatic pressure procedure 
               
               
                   
                 EDS 
                 Energy dispersive X-ray spectroscopy 
               
               
                   
                 EPMA 
                 Electron microprobe analysis 
               
               
                   
                 DTA 
                 Differential thermal analysis 
               
               
                   
                 CTE 
                 Coefficient of thermal expansion 
               
               
                   
                   
               
             
          
         
       
     
     While the invention has been described in detail with reference to preferred embodiments thereof, it will be apparent to one skilled in the art that various changes can be made, and equivalents employed, without departing from the scope of the invention. Each of the aforementioned documents is incorporated by reference herein in its entirety.