A lithography system includes a table body, a wafer stage, a first sliding member, a second sliding member, a first cable, a first bracket, a rail guide, and a first protective film. The first sliding member is coupled to the wafer stage. The second sliding member is coupled to an edge of the table body, in which the first sliding member is coupled to a track of the second sliding member. The first bracket fixes the first cable, the first bracket being coupled to a roller structure, in which the roller structure includes a body and a wheel coupled to the body. The rail guide confines a movement of the wheel of the roller structure. The first protective film is adhered to a surface of the rail guide, in which the roller structure is moveable along the first protective film on the surface of the rail guide.

A semiconductor substrate stage for carrying a substrate is provided. The semiconductor substrate stage includes a base layer, a magnetic shielding layer disposed on the base layer, a carrier layer disposed on the magnetic shielding layer, and a receiver disposed on the carrier layer. The receiver is configured to receive a microwave signal from a signal source electrically isolated from the receiver, and the microwave signal is used for controlling the movement of the semiconductor substrate stage.

A contamination trap for use in a debris mitigation system of a radiation source, the contamination trap comprising a plurality of vanes configured to trap fuel debris emitted from a plasma formation region of the radiation source; wherein at least one vane or each vane of the plurality of vanes comprises a material comprising a thermal conductivity above 30 W m.sup.−1K.sup.−1.

A semiconductor substrate stage for carrying a substrate is provided. The semiconductor substrate stage includes a base layer, a magnetic shielding layer disposed on the base layer, a carrier layer disposed on the magnetic shielding layer, a receiver disposed on the carrier layer, a storage layer disposed between the base layer and the magnetic shielding layer, and a magnetic shielding element disposed on the carrier layer and surrounding the receiver.

Systems, apparatuses, and methods are provided for manufacturing a substrate table. An example method can include forming a vacuum sheet including a plurality of vacuum connections and a plurality of recesses configured to receive a plurality of burls disposed on a core body for supporting an object such as a wafer. Optionally, at least one burl can be surrounded, partially or wholly, by a trench. The example method can further include using the vacuum sheet to mount the core body to an electrostatic sheet including a plurality of apertures configured to receive the plurality of burls. Optionally, the example method can include using the vacuum sheet to mount the core body to the electrostatic sheet such that the plurality of recesses of the vacuum sheet line up with the plurality of burls of the core body and the plurality of apertures of the electrostatic sheet.

A method includes transferring a wafer over a wafer stage on a wafer table. The wafer table includes a table body, a wafer stage, a first sliding member, a second sliding member, a first cable, a first bracket and a second bracket, and a stopper. The second sliding member is movable along a first direction, in which the first sliding member is coupled to a track of the second sliding member, the first sliding member being movable along a second direction vertical to the first direction. The first bracket and the second bracket are connected by a leaf spring. The method includes moving the wafer stage toward the edge of the table body, such that the wafer stage pushes the first cable outwardly, such that the leaf spring is moved toward a first protective film on a surface of the stopper facing the leaf spring.

An optical element reflects radiation, such as EUV radiation. The optical element includes a substrate with a surface to which a reflective coating is applied. The substrate has at least one channel through which a coolant can flow. The substrate is formed from fused silica, such as titanium-doped fused silica, or a glass ceramic. The channel has a length of at least 10 cm below the surface to which the reflective coating is applied. The cross-sectional area of the channel varies by no more than +/−20% over the length of the channel.

A reticle-masking structure is provided. The reticle-masking structure includes a magnetic substrate and a paramagnetic part disposed on the magnetic substrate. The paramagnetic part includes a plurality of fractions disposed on a plurality of protrusion structures. In some embodiments, the fractions are irregularly arranged. A method for forming a reticle-masking structure and an extreme ultraviolet apparatus are also provided.

A semiconductor substrate stage for carrying a substrate is provided. The semiconductor substrate stage includes a base layer, a magnetic shielding layer disposed on the base layer, a carrier layer disposed on the magnetic shielding layer, and a receiver disposed on the carrier layer. The receiver is configured to receive a microwave signal from a signal source electrically isolated from the receiver, and the microwave signal is used for controlling the movement of the semiconductor substrate stage.

An apparatus includes a first substrate, a second substrate, and an intermediate layer disposed between the first and second substrates. The intermediate layer is configured to be a first point of failure or breakage of the apparatus under an applied force. The apparatus can further include a bonding layer disposed between the first and second substrates. The bonding layer is configured to bond the intermediate layer to the first and second substrates. The apparatus can further include a fastener coupled to the first and second substrates. The fastener is configured to secure the intermediate layer to the first and second substrates. The intermediate layer can include a coating applied to the first substrate or the second substrate. The apparatus can further include a second intermediate layer disposed between the first substrate and the fastener or the second substrate and the fastener.