Hardfacing incorporating carbide particles

We claim: 1. An article comprising a hardfacing layer joined to a metal surface by the process of (a) fusion welding an austenitic stainless steel filler metal to the surface of a base metal, thereby generating a weld pool; and (b) adding a plurality of particles comprising tungsten carbide to the weld pool, wherein the austenitic steel filler metal comprises 18-35% Ni, and the volume fraction of tungsten carbide particles in the hardfacing layer is from 30% to 60%, and the particles have a size selected from the range of 12-25mesh, and wherein the hardfacinq comprises an outer zone, a middle zone and an inner zone, the inner zone being adjacent to the metal fusion bond, the outer zone being adjacent to the outer surface of the hardfacinq and the middle zone being between the inner and outer zones and the average chromium content of the matrix material in the outer zone is greater than the average chromium content of the matrix material in the inner zone. 2. The article of claim 1 , wherein the article is characterized by a relative magnetic permeability less than 1.75. 3. The article of claim 2 , wherein the base metal is selected from the group consisting of iron based alloys or nickel based alloys. 4. The article of claim 2 , wherein the base metal is an austenitic stainless steel. 5. The article of claim 1 , wherein the fusion welding process is a gas metal arc welding process. 6. The article of claim 1 , wherein the average chromium content of the matrix material in the outer zone is from 14 to 25 wt % chromium. 7. The article of claim 1 , wherein the average hardness of the matrix material in the outer zone is greater than the average hardness of the matrix material in the inner zone. 8. The article of claim 7 , wherein the average hardness of the matrix material in the outer zone of the hardfacing layer is from 35 to 55 HRC. 9. The article of claim 1 , wherein the hardfacing layer is substantially free of cracks. 10. A hardfacing layer joined to at least a portion of a metal surface by a metal fusion bond, the hardfacing layer comprising: (a) a matrix material comprising: (i) a first component comprising an iron based alloy, the iron based alloy further comprising chromium and nickel; and (ii) a second component comprising carbon, chromium, tungsten and iron; and (b) a plurality of particles comprising tungsten carbide substantially uniformly distributed in the matrix material, the volume fraction of particles in the hardfacing layer being from 30% to 60%; wherein the matrix material comprises 7 -28wt % Cr, 2.5 -35 wt % Ni, 5 -50 wt % W, and 30 -75 wt % Fe; and wherein the matrix material comprises dendrites of the first component and the second component is located in between the dendrites of the first component. 11. A hardfacing layer joined to at least a portion of a metal surface by a metal fusion bond, the hardfacing layer comprising: (a) a matrix material comprising: (i) a first component comprising an iron based alloy, the iron based alloy further comprising chromium and nickel; and (ii) a second component comprising carbon, chromium, tungsten and iron; and (b) a plurality of particles comprising tungsten carbide substantially uniformly distributed in the matrix material, the volume fraction of particles in the hardfacing layer being from 30% to 60%; wherein the matrix material comprises 7-28 wt % Cr, 2.535wt % Ni, 5-50 wt % W, and 30-75 wt % Fe; and wherein the hardfacing comprises an outer zone, a middle zone and an inner zone, the inner zone being adjacent to the metal fusion bond, the outer zone being adjacent to the outer surface of the hardfacing and the middle zone being between the inner and outer zones and the average chromium content of the matrix material in the outer zone is greater than the average chromium content of the matrix material in the inner zone. 12. The hardfacing layer of claim 11 , wherein average chromium content of the matrix material in the outer zone is from 14 to 25 wt % chromium. 13. A hardfacing layer joined to at least a portion of a metal surface by a metal fusion bond, the hardfacing layer comprising: (a) a matrix material comprising: (i) a first component comprising an iron based alloy, the iron based alloy further comprising chromium and nickel; and (ii) a second component comprising carbon, chromium, tungsten and iron; and (b) a plurality of particles comprising tungsten carbide substantially uniformly distributed in the matrix material, the volume fraction of particles in the hardfacing layer being from 30% to 60%; wherein the matrix material comprises 7-28 wt % Cr, 2.5-35 wt % Ni, 5-50 wt % W, and 30-75 wt % Fe; and wherein the hardfacing comprises an outer zone, a middle zone and an inner zone, the inner zone being adjacent to the metal fusion bond, the outer zone being adjacent to the outer surface of the hardfacing and the middle zone being between the inner and outer zones and the and the average hardness of the matrix material in the outer zone is greater than the average hardness of the matrix material in the inner zone. 14. The hardfacing layer of claim 13 , wherein the average hardness of the matrix material in the outer zone of the hardfacing layer is from 35 to 55 HRC. 15. An article comprising a hardfacing layer joined to a metal surface by the process of (a) fusion welding an austenitic stainless steel filler metal to the surface of a base metal, thereby generating a weld pool; and (b) adding a plurality of particles comprising tungsten carbide to the weld pool, wherein the austenitic steel filler metal comprises 18-28% Cr and 8-35% Ni, and the volume fraction of tungsten carbide particles in the hardfacing layer is from 30% to 60%, and the particles have a size selected from the range of 12-25mesh, and wherein the hardfacing comprises an outer zone, a middle zone and an inner zone, the inner zone being adjacent to the metal fusion bond, the outer zone being adjacent to the outer surface of the hardfacing and the middle zone being between the inner and outer zones and the average hardness of the matrix material in the outer zone is greater than the average hardness of the matrix material in the inner zone.