Abstract: An aluminum or copper alloy sputtering chamber includes a front surface, a back surface opposite the front surface, and a sputter trap formed on at least a portion of the front surface A coating of titanium particles is formed on the sputter trap.

Abstract: An aluminum or copper alloy sputtering chamber includes a front surface, a back surface opposite the front surface, and a sputter trap formed on at least a portion of the front surface A coating of titanium particles is formed on the sputter trap.

Abstract: A sputtering chamber component including a front surface, a back surface opposite the front surface, and a sputter trap formed on at least a portion of the back surface, and a coating of metallic particles formed on the sputter trap. The coating has a thickness from about 0.025 mm to about 2.54 mm (0.001 inches to about 0.1 inches) and is substantially free of impurities, and the particles of the coating are substantially diffused.

Abstract: A sputter trap formed on at least a portion of a sputtering chamber component has a plurality of particles and a particle size distribution plot with at least two different distributions. A method of forming a sputter trap having a particle size distribution plot with at least two different distributions is also provided.

Abstract: A sputter trap formed on at least a portion of a sputtering chamber component has a plurality of particles and a particle size distribution plot with at least two different distributions. A method of forming a sputter trap having a particle size distribution plot with at least two different distributions is also provided.

Abstract: A sputter trap formed on at least a portion of a sputtering chamber component has a plurality of particles and a particle size distribution plot with at least two different distributions. A method of forming a sputter trap having a particle size distribution plot with at least two different distributions is also provided.

Abstract: A sputtering chamber component including a front surface, a back surface opposite the front surface, and a sputter trap formed on at least a portion of the back surface, and a coating of metallic particles formed on the sputter trap. The coating has a thickness from about 0.025 mm to about 2.54 mm (0.001 inches to about 0.1 inches) and is substantially free of impurities, and the particles of the coating are substantially diffused.

Abstract: A sputter trap formed on at least a portion of a sputtering chamber component has a plurality of particles and a particle size distribution plot with at least two different distributions. A method of forming a sputter trap having a particle size distribution plot with at least two different distributions is also provided.

Abstract: A reference standard for calibrating an ultrasonic scanning apparatus comprising a first portion comprising a first material, a first face, and a second face opposite the first face. The reference standard also has a second portion comprising a second material, a first face, and a second face opposite the first face. The second face of the second portion is adjacent the first face of the first portion and forms an interface. The reference standard also includes a reference material extending axially through the first face of the first portion and the second face of the second portion. The first portion and second portion are configured to enclose the reference material such that the calibration standard is void free at an interface between the first material and the reference material and at an interface between the second material and the reference material.

Abstract: A sputtering target assembly for use in a vapor deposition apparatus, the sputtering target assembly comprising a sputtering surface; a sidewall extending from the sputtering surface at an angle to the sputtering surface; a particle trap formed of a roughness located along the sidewall and extending radially from the sputtering surface, wherein the roughness of the particle trap has a macrostructure and a microstructure.

Abstract: Sputtering targets having a reduced burn-in time are disclosed that comprise: a) a heat-modified surface material having a substantially uniform crystallographic orientation, wherein at least part of the surface material was melted during heat-treatment, and b) a core material having an average grain size. Sputtering targets are also disclosed that include a heat-modified surface material having network of shallow trenches, alternating rounded peaks and valleys in the surface of the target or a combination thereof, wherein at least part of the surface material was melted during heat-treatment, and a core material having an average grain size. Methods of producing sputtering targets having reduced burn-in times comprises: a) providing a sputtering target comprising a sputtering surface having a sputter material and a crystal lattice, and b) heat-modifying the sputtering surface in order to melt at least part of the surface material and modify the crystal lattice.

Abstract: Sputtering targets having reduced burn-in times are described herein that include: a) a machine-finished surface material having an average grain size, and b) a core material having an average grain size, wherein the machine-finished surface material has an average surface roughness (Ra) equal to or less than about the average grain size of at least one of the surface material or the core material. Sputtering targets having reduced burn-in times are described herein that include: a surface material, and a core material, wherein at least one of the surface material or the core material comprises a relatively band-free crystallographic orientation.