There is provided an exposure apparatus including a first light shielding unit including a first light shielding member and a second light shielding member, which include end potions facing each other in a scanning direction and in which a relative distance therebetween in the scanning direction can be changed, and arranged at a position away from a conjugate plane of a surface to be illuminated to a side of a light source, and a second light shielding unit including a third light shielding member and a fourth light shielding member, which include end portions facing each other in the scanning direction and in which a relative distance therebetween in the scanning direction can be changed, and arranged at a position away from the conjugate plane to a side of the surface.

An actuator device for aligning an element includes at least one first actuator unit, which is secured to a support structure, for a first setting range and a second actuator unit, which is able to be secured to the element, for a second setting range. The second actuator unit is connected to an output element of the first actuator unit so that the positioning of the second actuator unit is adjustable by an adjustment of the output element. The first actuator unit has an adjusting element and a fixing element, which is able to be secured to the support structure. The fixing element secures the output element in a force-locking manner in an operating state of the element. The fixing element is furthermore configured to release the force-locking connection in a setting state of the element to enable an adjustment of the output element via the adjusting element.

There is provided an exposure apparatus including a first light shielding unit including a first light shielding member and a second light shielding member, which include end potions facing each other in a scanning direction and in which a relative distance therebetween in the scanning direction can be changed, and arranged at a position away from a conjugate plane of a surface to be illuminated to a side of a light source, and a second light shielding unit including a third light shielding member and a fourth light shielding member, which include end portions facing each other in the scanning direction and in which a relative distance therebetween in the scanning direction can be changed, and arranged at a position away from the conjugate plane to a side of the surface.

Embodiments described herein relate to a dynamically controlled lens used in lithography tools. Multiple regions of the dynamic lens can be used to transmit a radiation beam for lithography process. By allowing multiple regions to transmit the radiation beam, the dynamically controlled lens can have an extended life cycle compared to conventional fixed lens. The dynamically controlled lens can be replaced or exchanged at a lower frequency, thus, improving efficiency of the lithography tools and reducing production cost.

A projection exposure apparatus for semiconductor technology includes an optical arrangement with an optical element having an optically effective surface. The optical arrangement also includes an actuator embedded in the optical element. The actuator is outside the optically effective surface and outside the region located behind the optically effective surface. The optical arrangement is set up to deform the optically effective surface.

A semiconductor lithography projection exposure apparatus includes a sensor reference including reference elements. The apparatus also includes an optical element, which includes a main body comprising receiving elements receiving the reference elements. The optical element further includes a referential surface that is an optically active surface of the optical element. The reference elements are arranged to determine a position and an orientation of the optical element. A method includes aligning a sensor reference with respect to a referential surface in a semiconductor lithography projection exposure apparatus.

A semiconductor lithography projection exposure apparatus includes a sensor reference including reference elements. The apparatus also includes an optical element, which includes a main body comprising receiving elements receiving the reference elements. The optical element further includes a referential surface that is an optically active surface of the optical element. The reference elements are arranged to determine a position and an orientation of the optical element. A method includes aligning a sensor reference with respect to a referential surface in a semiconductor lithography projection exposure apparatus.

A method for determining a component of optical characteristic of a patterning process. The method includes obtaining (i) a plurality of desired features, (ii) a plurality of simulated features based on the plurality of desired features and an optical characteristic of a patterning apparatus, and (iii) a performance metric (e.g., EPE) related to a desired feature of the plurality of desired features and an associated simulated feature of the plurality of simulated features; determining a set of optical sensitivities of the patterning process by computing a change in value of the performance metric based on a change in value of the optical characteristic; and identifying, based on the set of optical sensitivities, a set of components (e.g., principal components) of the optical characteristic that include dominant contributors in changing the value of the performance metric.

Apparatus for and method of aligning optical components such as mirrors to facilitate proper beam alignment using an image integration optical system is used to integrate images from multiple optical features such as from both left mirror bank and right mirror bank to present the images simultaneously to the camera system. A fluorescent material may be used to render a beam footprint visible and the relative positions of the footprint and an alignment feature may be used to align the optical feature.

A field facet system for a lithography apparatus includes an optical element. The optical element includes a base section having an optically effective surface. The optical element also includes a plurality of lever sections provided at a rear side of the base section facing away from the optically effective surface. In addition, the field facet system includes two or more actuating elements configured, with the aid of the lever sections acting as levers, to apply in each case a bending moment to the base section to elastically deform the base section and thus to alter a radius of curvature of the optically effective surface. The actuating elements are arranged in series as viewed along a length direction of the optical element.