A membrane cleaning apparatus for removing particles from a membrane, the apparatus including a membrane support and an electric field generating mechanism. The membrane support is for supporting the membrane. The electric field generating mechanism is for generating an electric field in the vicinity of the membrane when supported by the membrane support. The electric field generating mechanism may include: one or more collector electrodes; and a mechanism for applying a voltage across a membrane supported by the membrane support and the or each of the one or more collector electrodes.

A membrane cleaning apparatus for removing particles from a membrane, the apparatus including a membrane support and an electric field generating mechanism. The membrane support is for supporting the membrane. The electric field generating mechanism is for generating an electric field in the vicinity of the membrane when supported by the membrane support. The electric field generating mechanism may include: one or more collector electrodes; and a mechanism for applying a voltage across a membrane supported by the membrane support and the or each of the one or more collector electrodes.

A reticle cleaning system includes a casing, a reticle holder, and a static charge reducing device. The reticle holder is in the casing and configured to hold a reticle. The static charge reducing device is above the reticle holder and includes a fluid generator, an ionizer, and a static charge sensor. The fluid generator is configured to control a humidity condition in the casing. The ionizer is configured to provide ionized air molecules to the reticle. The static charge sensor is configured to detect a static charge value on the reticle, wherein the ionizer is between the fluid generator and the static charge sensor.

A reticle cleaning system includes a casing, a reticle holder, and a static charge reducing device. The reticle holder is in the casing and configured to hold a reticle. The static charge reducing device is above the reticle holder and includes a fluid generator, an ionizer, and a static charge sensor. The fluid generator is configured to control a humidity condition in the casing. The ionizer is configured to provide ionized air molecules to the reticle. The static charge sensor is configured to detect a static charge value on the reticle, wherein the ionizer is between the fluid generator and the static charge sensor.

A system is disclosed. The system includes a cleaning device and a scanner device. The cleaning device is configured to clean a mask. The scanner device is coupled to the cleaning device and is configured to receive the mask, a reference image and a real-time image that is captured at the mask. The reference image includes at least one first mark image having a plurality of mapping marks on the mask. The real-time image includes at least one second mark image having the plurality of mapping marks on the mask. The scanner device is configured to map the at least one second mark image in the real-time image with the at least one first image in the reference image, when a lithography exposing process is performed. A method is also disclosed herein.

Embodiments of a photomask removal apparatus for removing photoresist off of a photomask are provided herein. In some embodiments, a nozzle head for removing photoresist off of a photomask includes: a nozzle portion having a first side and an opposing second side and a flow path extending from the first side to the second side, wherein the flow path includes an orifice disposed between the first side and the second side and a nozzle that extends from the orifice to a nozzle exit on the second side, and wherein the flow path in the nozzle increases in width at an angle from the orifice to the second side; and a vacuum portion coupled to the nozzle portion, wherein the vacuum portion includes a first side and an opposing second side that faces the nozzle exit, wherein the vacuum portion includes a vacuum port extending from the second side.

A method is provided for fabricating a photolithographic mask. The method includes providing a transparent substrate; and forming an opaque layer on the transparent substrate. The method also includes writing layout patterns with at least one sub-resolution assistant feature with non-uniform size along a longitudinal direction to increase an adhesion force between the sub-resolution assistant feature with non-uniform size along the longitudinal direction and the transparent substrate in the opaque layer. Further, the method include cleaning residual matters generated by writing the layout patterns in the opaque layer. Further, the method also includes spin-drying the transparent substrate with the layout patterns and the sub-resolution assistant feature with non-uniform size along the longitudinal direction.

A method is provided for fabricating a photolithographic mask. The method includes providing a transparent substrate; and forming an opaque layer on the transparent substrate. The method also includes writing layout patterns with at least one sub-resolution assistant feature with non-uniform size along a longitudinal direction to increase an adhesion force between the sub-resolution assistant feature with non-uniform size along the longitudinal direction and the transparent substrate in the opaque layer. Further, the method include cleaning residual matters generated by writing the layout patterns in the opaque layer. Further, the method also includes spin-drying the transparent substrate with the layout patterns and the sub-resolution assistant feature with non-uniform size along the longitudinal direction.

An exposure machine and an exposure method are provided in some embodiments of the present disclosure. The exposure machine includes: a detection module, configured to detect whether there are attachments on the surface of a reticle: a cleaning device, configured to clean the attachments on the surface of the reticle; and an exposure module, configured to expose the reticle having no attachments detected.

The present application relates to a method for removing a particle from a photolithographic mask, including the following steps: (a) positioning a manipulator, which is movable relative to the mask, in the vicinity of the particle to be removed; (b) connecting the manipulator to the particle by depositing a connecting material on the manipulator and/or the particle from the vapor phase; (c) removing the particle by moving the manipulator relative to the photolithographic mask; and (d) separating the removed particle from the manipulator by carrying out a particle-beam-induced etching process which removes at least a portion of the manipulator.