Lift pin actuators, actuator arrangements and semiconductor processing systems having lift pin actuators, and methods of making lift pin actuators and actuator arrangements

1 . A lift pin actuator, comprising: an actuator body arranged along a rotation axis having: a hub portion extending about the rotation axis; a first arm portion and a second arm portion extending outward from the hub portion and in a direction opposite the rotation axis, the second arm portion parallel to the first arm portion; and a pad portion radially separated from the hub portion by the first arm portion and the second arm portion, the pad portion coupling the first arm portion to the second arm portion, wherein the pad portion has an engagement surface that is orthogonal relative to the rotation axis and coplanar with the first arm portion and the second arm portion of the actuator body and configured to drive a lift pin above the engagement surface of the pad portion of the actuator body along the rotation axis. 2 . The lift pin actuator of claim 1 , wherein the pad portion is one of three (3) pad portions distributed circumferentially about the hub portion of the actuator body. 3 . The lift pin actuator of claim 1 , wherein the first arm portion and the second arm portion form a first arm pair of the actuator body, and wherein the actuator body has three (3) arm pairs distributed circumferentially about the hub portion of the actuator body. 4 . The lift pin actuator of claim 1 , wherein the actuator body is formed from a ceramic material, and wherein the actuator body is monolithically formed from a singular ceramic workpiece using a subtractive manufacturing technique. 5 . The lift pin actuator of claim 1 , wherein the hub portion has an upper surface defining an upper surface aperture therein, a lower surface defining a seating aperture therein, and an interior surface coupling the upper surface aperture to the seating aperture. 6 . The lift pin actuator of claim 5 , wherein the interior surface of the hub portion defines a plurality of planar faces distributed circumferentially about the rotation axis. 7 . The lift pin actuator of claim 6 , wherein the plurality of planar faces are angled relative to at least one of the upper surface and the lower surface at a planar surface angle that is between about 5 degrees and about 45 degrees. 8 . The lift pin actuator of claim 6 , wherein the interior surface of the hub portion defines a plurality of arcuate faces distributed circumferentially about the rotation axis, wherein the plurality of arcuate faces are substantially parallel to the rotation axis. 9 . The lift pin actuator of claim 6 , wherein one or more of the plurality of planar faces is bounded by an arcuate periphery having a base proximate the lower surface of the hub portion and an open end proximate the upper aperture of the hub portion, and wherein the one or more of the plurality of planar faces defining a relief channel therein extending from the open end to a location intermediate the open end and the base of the arcuate periphery. 10 . The lift pin actuator of claim 1 , wherein the hub portion of the actuator body has an annular segment and a plurality of merlon segments, wherein the plurality of merlon segments extend axially from the annular segment, and wherein the plurality of merlon segments axially separate the first arm portion and the second arm portion from the annular segment of the hub portion. 11 . An actuator arrangement, comprising: a lift pin actuator as recited in claim 1 ; an actuator tube member arranged along the rotation axis, wherein the lift pin actuator is seated on the actuator tube member; wherein the actuator tube member has an exterior surface defining a plurality of planar facets distributed circumferentially about the rotation axis; wherein the lift pin actuator has an interior surface with a plurality of planar faces distributed circumferentially about the rotation axis; and wherein each of the plurality of planar faces defined by the interior surface of the actuator member abuts a respective one of the plurality of planar facets defined by the exterior surface of the actuator tube member to locate the lift pin actuator on the actuator tube member. 12 . The actuator arrangement of claim 11 , wherein the exterior surface of the actuator tube member defines three (3) planar facets, wherein the interior surface of the lift pin actuator defines three (3) planar faces, and wherein each of the planar faces radially overlaps a respective one of the plurality of planar facets. 13 . The actuator arrangement of claim 11 , wherein the plurality of planar facets are angled relative to the rotation axis at a planar facet angle that is between about 5 degrees and about 45 degrees, and wherein the plurality of planar faces are angled relative to the rotation axis at a planar face angle substantially equivalent to the planar facet angle. 14 . The actuator arrangement of claim 11 , wherein the exterior surface of the actuator tube member defines a plurality a plurality of arcuate facets, wherein the interior surface of the lift pin actuator defines a plurality of arcuate faces, and wherein each of the plurality arcuate faces radially overlaps a respective one of the plurality of arcuate facets. 15 . The actuator arrangement of claim 14 , wherein each of the plurality of arcuate faces defined by the interior surface of the lift pin actuator are radially offset from a respective one of the plurality of arcuate facets defined by the exterior surface of the actuator tube member. 16 . The actuator arrangement of claim 14 , wherein the exterior surface of the actuator tube member defines three (3) arcuate facets distributed circumferentially about the rotation axis, and wherein the interior surface of the lift pin actuator defines three (3) arcuate faces distributed circumferentially about the rotation axis. 17 . The actuator arrangement of claim 11 , further comprising a shaft member arranged within the actuator tube member and supported for rotation about the rotation axis, wherein the plurality of planar facets and the plurality of planar faces radially overlap the shaft member. 18 . A semiconductor processing system, comprising: a chamber body; a lift pin actuator as recited in claim 1 arranged within the chamber body; an actuator tube member extending through a lower wall of the chamber body, the lift pin actuator seated on the actuator tube member; a shaft member arranged within the actuator tube member and supported for rotation about the rotation axis; and a substrate support seated on the shaft member with a plurality of lift pins slidably received therein, wherein the lift pin actuator is arranged axially between the lower wall of the chamber body and the plurality of lift pins and configured to seat and unseat substrates from the substrate support. 19 . A method of making a lift pin actuator, comprising: forming a lift pin actuator body from a singular workpiece body formed from a ceramic material using a boring or drilling operation and a milling operation by: defining a hub portion extending about a rotation axis; defining a first arm portion and a second arm portion extending outward from the hub portion and in a direction opposite the rotation axis, the second arm portion parallel to the first arm portion; defining a pad portion radially separated from the hub portion by the first arm portion and the second arm portion coupling the first arm portion to the second arm portion; and defining an engagement surface of the pad portion orthogonal relative to the rotation axis and coplanar with the first arm portion and the second arm portion of the actuator body