A microlithography optical system includes a projection objective and an illumination system that includes a temperature compensated polarization-modulating optical element. The temperature compensated polarization-modulating optical element includes a first polarization-modulating optical element of optically active material, the first polarization-modulating optical element having a first specific rotation with a sign. The temperature compensated polarization-modulating optical element includes also includes a second polarization-modulating optical element of optically active material, the second polarization-modulating optical element having a second specific rotation with a sign opposite to the sign of the first specific rotation.

An illumination optical apparatus includes a plurality of birefringent members made of a birefringent material and arranged in an optical path on an incidence side of an optical integrator. The members change a polarization state of illumination light such that first and second rays of the illumination light are polarized in different directions on the pupil plane. The birefringent members are arranged such that an optical path length of the first ray in the birefringent material is different from an optical path length of the second ray in the birefringent material, and are arranged so as to change the polarization state of the illumination light incident on the plurality of the birefringent members in a linear polarization state having a substantially single polarization direction such that each of the first and second rays is polarized in a substantially circumferential direction about the optical axis on the pupil plane.

A microlithography optical system includes a projection objective and an illumination system that includes a temperature compensated polarization-modulating optical element. The temperature compensated polarization-modulating optical element includes a first polarization-modulating optical element of optically active material, the first polarization-modulating optical element having a first specific rotation with a sign. The temperature compensated polarization-modulating optical element includes also includes a second polarization-modulating optical element of optically active material, the second polarization-modulating optical element having a second specific rotation with a sign opposite to the sign of the first specific rotation.

The invention relates to an optical system, in particular of a microlithographic projection exposure apparatus, with an optical system axis (OA) and a polarization-influencing optical arrangement. According to one aspect, the polarization-influencing optical arrangement comprises at least one polarization-influencing optical element, which has a monolithic design and linear birefringence, wherein the overall absolute value of the birefringence of all of the polarization-influencing optical elements deviates by at most 15% from the value lambda/2, wherein lambda is the working wavelength of the optical system, wherein the direction of the fast axis of this birefringence varies in a plane perpendicular to the optical system axis (OA) in the at least one polarization-influencing optical element, and wherein the distribution of the fast axis of the birefringence of the polarization-influencing optical element is brought about by radiation-induced defects, which are situated in at least one optically unused region of the element.

A microlithography optical system includes a projection objective and an illumination system that includes a temperature compensated polarization-modulating optical element. The temperature compensated polarization-modulating optical element includes a first polarization-modulating optical element of optically active material, the first polarization-modulating optical element having a first specific rotation with a sign. The temperature compensated polarization-modulating optical element includes also includes a second polarization-modulating optical element of optically active material, the second polarization-modulating optical element having a second specific rotation with a sign opposite to the sign of the first specific rotation.

A photolithography apparatus and a method for operating the photolithography apparatus are provided. The method includes steps of receiving a reticle assembly comprising a reticle protected by a pellicle membrane; transporting the reticle assembly to an exposure tool and securing the reticle assembly on a reticle stage of the exposure tool; determining a scanning speed profile based on a risk level rupture of the pellicle membrane; and preforming an exposure operation by driving the reticle stage according to the scanning profile.

A photolithography apparatus and a method for operating the photolithography apparatus are provided. The method includes steps of receiving a reticle assembly comprising a reticle protected by a pellicle membrane; transporting the reticle assembly to an exposure tool and securing the reticle assembly on a reticle stage of the exposure tool; determining a scanning speed profile based on a risk level rupture of the pellicle membrane; and preforming an exposure operation by driving the reticle stage according to the scanning profile.