Abstract: Substrate transport systems, apparatus, and methods are described. The systems are adapted to efficiently put or pick substrates at a destination by rotating a boom linkage to a position adjacent to the destination and then independently actuating an upper arm link housing and one or more wrist members to put or pick one or more substrates at the destination wherein the wrist member is independently actuated relative to the forearm link housing and the motion of the forearm link member is kinematically linked to the motion of the upper arm link housing. Numerous other aspects are provided.

Abstract: Boom drive apparatus for substrate transport systems and methods are described. The boom drive apparatus is adapted to drive one or more multi-arm robots rotationally mounted to the boom to efficiently put or pick substrates. The boom drive apparatus has a boom including a hub, a web, a first pilot above the web, and a second pilot below the web, a first driving member rotationally mounted to the first pilot, a second driving member rotationally mounted to the second pilot, a first driven member rotationally mounted to the boom above the a web, a second driven member rotationally mounted to the boom below the a web, and a first and second transmission members coupling the driving members to driven members located outboard on the boom. Numerous other aspects are provided.

Abstract: Embodiments of substrate transfer robot blades to engage and support a substrate during transfer are provided herein. In some embodiments, a substrate transfer robot may include a blade body having a blade support surface; and a plurality of compliant pads, each comprising a contact surface and an opposite bottom surface supported by the body and arranged to support a substrate when disposed on the substrate transfer robot blade.

Abstract: Embodiments include multi-arm robots for substrate transport systems that include a boom, first and second forearms rotationally coupled to the boom, the second forearm being shorter than the first forearm, a first wrist member rotationally coupled to the first forearm, and a second wrist member rotationally coupled to the second forearm. Each of the boom, first and second forearms, and the first and second wrist members are configured to be independently rotated to carry out substrate motion profiles. Electronic device processing systems and methods of transporting substrates are described, as are numerous other aspects.

Abstract: Boom drive apparatus for substrate transport systems and methods are described. The boom drive apparatus is adapted to drive one or more multi-arm robots rotationally mounted to the boom to efficiently put or pick substrates. The boom drive apparatus has a boom including a hub, a web, a first pilot above the web, and a second pilot below the web, a first driving member rotationally mounted to the first pilot, a second driving member rotationally mounted to the second pilot, a first driven member rotationally mounted to the boom above the a web, a second driven member rotationally mounted to the boom below the a web, and a first and second transmission members coupling the driving members to driven members located outboard on the boom. Numerous other aspects are provided.

Abstract: Systems, apparatus and methods for transporting substrates between system components of an electronic device manufacturing system are provided. The systems and apparatus include an electrostatic end effector having a base, an electrode pair on the base, and spacer members for spacing the substrate from the electrode pairs to provide a gap between the electrode pair and the substrate. Methods of the invention as well as numerous other aspects are provided.

Abstract: Substrate transport systems, apparatus, and methods are described. The systems are adapted to efficiently put or pick substrates at a destination by rotating a boom linkage to a position adjacent to the destination and then independently actuating an upper arm link housing and one or more wrist members to put or pick one or more substrates at the destination wherein the wrist member is independently actuated relative to the forearm link housing and the motion of the forearm link member is kinematically linked to the motion of the upper arm link housing. Numerous other aspects are provided.

Abstract: The present invention provides methods, apparatus, and systems for a wrist assembly including a housing having a cap and a bottom, at least one pivot at least partially enclosed in the housing and adapted to be coupled to a robot arm, and a belt coupled to the pivot and adapted to rotate the pivot about a bearing. The bottom of the housing is adapted to reflect heat away from the at least one pivot and the bearing.

Abstract: Methods and apparatus are provided for the use of a dual Selective Compliant Assembly Robot Arm (SCARA) robot. In some embodiments two SCARAs are provided, each including an elbow joint, wherein the two SCARAs are vertically stacked such that one SCARA is a first arm and the other SCARA is a second arm, and wherein the second arm is adapted to support a first substrate, and the first arm is adapted to extend to a full length when the second arm supports the first substrate, and wherein the first substrate supported by the second arm is coplanar with the elbow joint of the first arm, and the second arm is further adapted to move concurrently in parallel (and/or in a coordinated fashion) with the first arm a sufficient amount to avoid interference between the first substrate and the elbow joint of the first arm. Numerous other embodiments are provided.

Abstract: In one aspect, a first apparatus is provided that is adapted to transfer a substrate between a transfer chamber and a processing chamber. The first apparatus includes a robot having a first blade, a second blade spaced from the first blade, and a central hub coupled to the first blade by at least a first arm and coupled to the second blade by at least a second arm. The first blade and the second blade are spaced so as to allow (a) both blades to simultaneously extend through a slit valve that separates a transfer chamber from a processing chamber coupled to the transfer chamber when the robot is positioned within the transfer chamber; and (b) the first and second blades to transfer substrates to and remove substrates from the processing chamber without raising or lowering the first and second blades or the robot. Numerous other aspects are provided.

Abstract: Systems, apparatus and methods for transporting substrates between system components of an electronic device manufacturing system are provided. The systems and apparatus include an electrostatic end effector having a base, an electrode pair on the base, and spacer members for spacing the substrate from the electrode pairs to provide a gap between the electrode pair and the substrate. Methods of the invention as well as numerous other aspects are provided.

Abstract: Systems, methods and apparatus are provided for moving substrates in electronic device manufacturing. In some aspects, end effectors having a base portion and at least three pads are provided. Each of the pads has a contact surface, and at least one of the contact surfaces has a curved shape. A substrate supported by the end effector may be moved at a relatively high lateral g-force without significant slipping relative to the pads. Additional aspects are provided.

Abstract: Methods and apparatus are provided for the use of a dual Selective Compliant Assembly Robot Arm (SCARA) robot. In some embodiments two SCARAs are provided, each including an elbow joint, wherein the two SCARAs are vertically stacked such that one SCARA is a first arm and the other SCARA is a second arm, and wherein the second arm is adapted to support a first substrate, and the first arm is adapted to extend to a full length when the second arm supports the first substrate, and wherein the first substrate supported by the second arm is coplanar with the elbow joint of the first arm, and the second arm is further adapted to move concurrently in parallel (and/or in a coordinated fashion) with the first arm a sufficient amount to avoid interference between the first substrate and the elbow joint of the first arm. Numerous other embodiments are provided.

Abstract: Embodiments of the present invention relates to high temperature anti-droop end effectors for transferring semiconductor substrates. One embodiment of the present invention provides an end effector for using with a substrate handler. The end effector comprises a free end having a substrate supporting plane configured to support a substrate and positioned that substrate at a first angle relative to a horizontal plane. The end effector comprises a fixed end configured to be mounted to the substrate handler, wherein the end effector is mounted to the substrate handler at a position that the substrate supporting plane is at a second angle relative to the horizontal plane when no substrate is disposed on the free end, and the first angle is different from the second angle.

Abstract: The present invention provides methods, apparatus, and systems for a wrist assembly including a housing having a cap and a bottom, at least one pivot at least partially enclosed in the housing and adapted to be coupled to a robot arm, and a belt coupled to the pivot and adapted to rotate the pivot about a bearing. The bottom of the housing is adapted to reflect heat away from the at least one pivot and the bearing.

Abstract: In one aspect, a first apparatus is provided that is adapted to transfer a substrate between a transfer chamber and a processing chamber. The first apparatus includes a robot having a first blade, a second blade spaced from the first blade, and a central hub coupled to the first blade by at least a first arm and coupled to the second blade by at least a second arm. The first blade and the second blade are spaced so as to allow (a) both blades to simultaneously extend through a slit valve that separates a transfer chamber from a processing chamber coupled to the transfer chamber when the robot is positioned within the transfer chamber; and (b) the first and second blades to transfer substrates to and remove substrates from the processing chamber without raising or lowering the first and second blades or the robot. Numerous other aspects are provided.

Abstract: The present invention provides a robot blade for supporting substrates in a processing system. More particularly, the invention provides a blade comprising a contact cup flexibly attached thereto to compensate for inaccurate alignment between the blade and a substrate and allow accurate alignment and flush contact between the contact cup and a substrate. The substrate can then be reliably secured to the blade when retrieved from a face-down position, with the blade positioned above the substrate.

Abstract: Apparatus for retaining a workpiece in a process chamber of a semiconductor wafer processing system. The apparatus has a thermal transfer element, an electrostatic chuck on top of the thermal transfers element and a clamping ring that secures the chuck to the thermal transfer element in a predefined orientation. The detachable, "keyed" chuck permits rapid exchange of wafer support platforms for increased productivity and consistent placement of same upon the thermal transfer element for reliable processing conditions.