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 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: A sputtering target is described herein that comprises: a) a target surface component comprising a target material; b) a core backing component having a coupling surface and a back surface, wherein the coupling surface is coupled to the target surface component; and c) at least one surface area feature coupled to or located in the back surface of the core backing component, wherein the surface area feature increases the resistance, resistivity or a combination thereof of the core backing component.

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.

Abstract: A sputtering target is described herein that comprises: a) a target surface component comprising a target material; b) a core backing component having a coupling surface and a back surface, wherein the coupling surface is coupled to the target surface component; and c) at least one surface area feature coupled to or located in the back surface of the core backing component, wherein the surface area feature increases the effective surface area of the core backing component. Additional sputtering targets comprises: a) an integrated target surface component and core backing component, wherein the surface component and the backing component comprise the same target material or a material gradient; and b) at least one surface area feature that is on or integrated into the core backing component, wherein the surface area feature increases the effective component of the core backing component.

Abstract: The invention includes backing plates having coolant deflectors with at least a portion of each of the deflectors being nonlinear. Projections projecting from the backing plate are configured to insert into openings within a sputtering target. The invention includes targets having at least one opening to receive a fastener extending into the target through a back surface. The invention includes a target assembly having projections projecting from the backing plate and insertable within openings within the target. The invention includes a target assembly having a plurality of coolant deflectors disposed between the target and the backing plate. A segment of each of the deflectors is nonlinear. The invention includes methods of cooling a target. Coolant deflectors are disposed within a gap between the target and a backing plate with coolant deflectors being nonlinear along at least a portion of their length.

Abstract: The invention includes a target construction having a sputtering region and a flange region laterally outward relative to the sputtering region. The flange region has a front surface disposed on a front face of the construction and a back surface opposing the front surface. An o-ring groove is disposed within the flange region. The o-ring groove has a planar base surface which has a first width and has an orifice disposed along the front surface of the flange. The orifice has a second width as measured parallel relative to the base surface. The second width is greater than the first width. The flange surfaces can additionally be protected from rubbing by a layer of protective material.