Dispersoid reinforced alloy powder and method of making

We claim: 1. As-atomized alloy particles, each comprising a matrix metal comprising Au, an environmental resistance-imparting alloying element substantially in solid solution in the matrix metal to provide a particle alloy matrix, and dispersoids formed in-situ in the particle alloy matrix during atomization, wherein the dispersoids comprise a dispersoid-forming element and a reactive species wherein the dispersoid-forming element has a greater tendency to react with the reactive species than does the alloying element and wherein the particles include a surface compound thereon formed during atomization by reaction of the reactive species and the alloying element, said surface compound being less thermodynamically stable than said dispersoids. 2. The particles of claim 1 having at least a surface region that contains the dispersoids. 3. The particles of claim 2 wherein the surface region has a thickness greater than 1 micrometer. 4. The particles of claim 1 wherein the alloying element is selected from the group consisting of Cr, Mo, W, V, Nb, Ta, Ti, Zr, Ni, Si and B. 5. The particles of claim 1 wherein the dispersoid-forming element is selected from the group consisting of Sc, Y, and a Lanthanide series element having an atomic number from 57 to 71 to be more thermodynamically stable than the surface compound. 6. The particles of claim 5 wherein the dispersoid-forming element is selected from the group consisting of Ti, Ce, Sr, Zr, Mg, Hf, Be, and Si. 7. The particles of claim 1 wherein the dispersoids comprise a refractory compound that comprises oxygen, nitrogen, carbon, boron, silicon, or fluorine. 8. A deposit comprising the atomized alloy particles of claim 1 deposited on a support. 9. A consolidated body comprising the particles of claim 1 that are vacuum hot pressed, hot isostatic pressed, hot extruded, or direct hot powder forged. 10. A consolidated body comprising the deposit of claim 8 that is hot extruded or hot forged. 11. The particles of claim 1 wherein the surface compound comprises a surface oxide formed by reaction of the reactive species that comprises oxygen and the alloying element. 12. A sintered body comprising previously atomized alloy particles, each particle comprising a matrix metal comprising Au, an environmental resistance-imparting alloying element substantially in solid solution in the matrix metal to provide a particle alloy matrix, and dispersoids formed in-situ in the particle alloy matrix during atomization and wherein the particles include a surface compound thereon formed during atomization by reaction of a reactive species and the alloying element, wherein said particles of said sintered body are sintered together and wherein the surface compound formed on the particles during atomization by reaction of the reactive species and the alloying element functions during sintering as a source of the reactive species to form more dispersoids in the sintered body. 13. A sintered body comprising a deposit comprising previously atomized particles deposited on a support, each particle comprising a matrix metal comprising Au, an environmental resistance-imparting alloying element substantially in solid solution in the matrix metal to provide a particle alloy matrix, and dispersoids formed in-situ in the particle alloy matrix during atomization wherein the particles include a surface compound thereon formed during atomization by reaction of a reactive species and the alloying element, wherein the particles of said sintered body are sintered together and wherein the surface compound formed on the particles during atomization by reaction of the reactive species and the alloying element functions during sintering as a source of the reactive species to form more dispersoids in the sintered body.