The invention relates to a light deflection technique for deflecting light in a desired direction by tilting a reflecting mirror in the direction of x-axis or y-axis of a plane according to the application of an electric signal. Specific scan patterns can be generated by maneuvering the reflecting mirror through a desired range of angles in two dimensions.
The ability to scan laser beams by way of reflection from a tiltable mirror serves many purposes in optics. The most general of tilt scanners provide two-dimensional angle scanning from a single reflective surface and are fully programmable. In the visible-light regime, this is typically achieved by using a piezo tilt stage. Piezo tilters, however, have rather a small angle scanning range and require expensive high-voltage drive electronics.
For example, a tilting mirror arrangement used for scanning is described in U.S. Pat. No. 4,708,420 to Liddiard. For this device, a scanning mirror is connected via flexible joints to piezoceramic drive elements that are arranged parallel to the mirror surface. This scanning device is complex and the scanning mirror arrangement is very large so that the piezoceramic drive elements can tilt the mirror through a large angle. This results from the small deflection of the piezoceramic drive elements, which is proportional to the length of these elements. This arrangement is thus not suited to tilt small mirrors through a large angular range when the drive mechanism behind the tilting mirror is to be limited to the dimensions of the mirror surface.
U.S. Pat. No. 4,383,763 to Hutchings et al. describes a tilting mirror apparatus in which the mirror is mounted on a tilting point and is moved by piezoelectric ceramics. Here also, the dimensions of the mirror have to be very large if the tilting mirror is to be tilted through at least 1 degree.
U.S. Pat. No. 4,660,941 to Hattori et al describes a tilting mirror in which the movement of the tilting mirror is effected by piezoelectric elements which act on the mirror via levers. This arrangement is also not suitable for tilting a small mirror through at least 1 degree.
A piezoelectric beam reflector is described in U.S. Pat. No. 5,170,277 to Bard in which the mirror member is directly attached to the piezoelectric element. This device has the disadvantage that the mirror has no defined pivot point when pivoting. Finally, U.S. Pat. No. 4,691,212 to Solcz et al. describes a piezoelectric beam reflector that is used in a scanning arrangement. The disadvantage of this apparatus is that a given deflection angle cannot be rigidly maintained when the pivot point is to remain stationary. As is apparent, the art is in need of a compact tiltable mirror that has a large scanning angle range.
In a related area, extreme ultraviolet (EUV) lithography is an emerging technology in the microelectronics industry. It is one of the leading candidates for the fabrication of devices with feature sizes of 70 nm and smaller. Synchrotron radiation facilities provide a convenient source of EUV radiation for the development of this technology. Though not under serious consideration for high-volume commercial fabrication applications, synchrotron sources play an extremely important role in the development of EUV lithography technology. Being readily available, highly reliable, and efficient producers of EUV radiation, synchrotron radiation sources are well suited to the development of EUV lithography. These sources are currently used for a variety of at-wavelength EUV metrologies such as reflectometry, interferometry and scatterometry.
In the case of synchrotron radiation sources, there are three types of sources: bending magnets, wigglers, and undulators. In bending magnet sources, the electrons are deflected by a bending magnet and photon radiation is emitted. Wiggler sources comprise a so-called wiggler for the deflection of the electron or of an electron beam. The wiggler includes a multiple number of alternating poled pairs of magnets arranged in a series. When an electron passes through a wiggler, the electron is subjected to a periodic, vertical magnetic field; the electron oscillates correspondingly in the horizontal plane. Wigglers are further characterized by the fact that no coherency effects occur. The synchrotron radiation produced by a wiggler is similar to that of a bending magnet and radiates in a horizontal steradian. In contrast to the bending magnet, it has a flow that is reinforced by the number of poles of the wiggler.
Finally, in the case of undulator sources, the electrons in the undulator are subjected to a magnetic field with shorter periods and a smaller magnetic field of the deflection pole than in the case of the wiggler, so that interference effects of synchrotron radiation occur. Due to the interference effects, the synchrotron radiation has a discontinuous spectrum and radiates both horizontally and vertically in a small steradian element, i.e., the radiation is strongly directed.
In lithographic applications, the partial coherence of the illumination (sigma) is often defined as the ratio of the illumination angular range to the numerical aperture of the imaging (projection optical) system. The illumination angular range is also referred to as the divergence of the source. Undulator radiation is much like a laser source in that it produces highly-coherent light of very low divergence. A typical EUV undulator beamline produces a sigma of less than 0.1 whereas lithographic applications nominally require a sigma of 0.5 or higher. Although less coherent than undulator radiation, bending magnet radiation is also typically too coherent to be directly used for lithography.
As EUV lithography technology matures, more lithographic printing stations will be required for resist and process development. Proliferation of these systems has been slowed by the lack of reliable and cost-effective EUV sources. It would be greatly desirable to alleviate the dearth of EUV sources for lithographic process development applications in the form of small-field static microsteppers through the use synchrotron radiation. The relatively high coherence of these sources, however, has precluded them from being used more extensively for actual lithography studies. Relevant process development applications require much more incoherence than is inherently provided by synchrotron sources. This is especially true of undulator sources that otherwise would be highly desirable for their large EUV power capabilities.
A new coherence controlling illuminator that is described in U.S. Pat. No. 6,798,494 to Naulleau addressed some of these problems. This illuminator allows the effective coherence of a synchrotron beamline to be tailored to photolithography applications by using an angular scanning element and a stationary low-cost spherical mirror to re-image the scanning mirror to the reticle plane of the lithographic optic. One significant advantage of this illumination system is that it enables the generation of arbitrary divergence patterns by way of controlling the particular scan configuration. This is of great importance for lithographic process development systems as it enables a single illumination system and source to model a wide variety of divergence patterns that might be generated by the variety of commercial sources and illuminators under development. Hence one process development tool would enable a large number commercial-style tools to be simulated in terms of illumination divergence characteristics greatly increasing the utility of the process development tool.
By design the Naulleau illuminator enables in si tu arbitrary control of the illumination coherence properties (or pupil fill), however, achieving arbitrary and switchable control of the pupil fill requires specialized electronics. In early implementations of the scanning illuminator, conventional function generators were used to generate the scan signals but this made it very difficult to change illumination properties and to achieve complicated fill patterns. What is needed are fully in situ programmable and rapidly switchable drive electronics meeting the requirements of a lithographic process development tool.
The present invention is based in part on the development of a magnetic-coil driven tiltable stage which can be made extremely compact and vacuum compatible thereby allowing it to be readily used in the vacuum ultraviolet and extreme ultraviolet regimes as well as the visible-light regime. Moreover, thick-substrate-glass mirrors, which serve as ideal substrates for high efficiency reflective coatings, can be incorporated into the stage to operate as scanners. Such coatings are crucial for near-normal-incidence EUV applications. The drive electronics for the scanner is fully in situ programmable and rapidly switchable.
In one aspect, the invention is directed to a mirror mounted tilt stage that includes: (a) a base unit, (b) a frame having a mirror mounted thereon wherein the mirror has a reflective surface, (c) a single pivot member having a distal end that is attached to the base unit and a proximal end that pivotally supports the frame such that the frame can pivot in two directions, (d) at least one actuator for tilting the frame; and (e) means for driving the actuators to move the reflective surface through a desired range of angles in two nonparallel, preferably orthogonal, planes.
In another aspect, the invention is directed to method for producing a reflected light scan pattern that includes the steps of: (a) providing a mirror mounted tilt stage as described above, (b) directing a beam of light into the reflective surface, (c) moving the reflective surface through a range of angles in two nonparallel planes to scan the beam through a set of angles to create the scan pattern on a target plane such as the entrance pupil of an illumination optics.
FIGS. 13 to 16 are scan patterns that are formed on targets and that were generated by a scanned EUV beam in vacuum.
As shown in
As shown in
The mirror mounted tilt stage further includes a mechanism for tilting the mirror in a desired direction and to a desired extent about the support point. As shown in
The poles of the permanent magnets are preferably arranged so that the north and south poles of one assembly are oppositely arranged relative to those positioned on the opposite side of the stage. As shown in
In another aspect of the present invention, the two-axes tilt scanner employs an electronic drive system that is preferably completely programmable. In one embodiment, the drive system comprises a two-channel system that employs three FLASH programmable microprocessors which are commercially available from Microchip Technology, Inc. (Chandler, Ariz.). One microprocessor is used for each of the three modular functional blocks as shown in
The first modular block (the function block) provides for the basic scan function such, for example, as a circle, stripe, or ellipse. This is achieved through two drive channels, one for each scan axis. Each drive channel can be programmed to put out arbitrary 8-bit resolution analog voltages using conventional microprocessor programming techniques in combination with the DACs. The repeat-rate of this basic pattern is also programmable and controlled by the function block. For example, to generate a basic circle, channel A of the function block would be programmed to put out a sine wave and channel B of the function block would be programmed to put out a sine wave 90 degrees out of phase with channel A. The function waveforms can be defined with up to 8000 data points.
The function block, as illustrated in the circuit diagram in
The second block (the gain block) provides for amplitude control of the function block output. This enables time variable gain control of the basic function. As with the function block, the gain block allows for the 8-bit resolution control of the gain and timing control of the gain modulation. The output of this modular block is an analog waveform that is produced from the waveform generated by the function block multiplied by the time varying value generated by the microprocessor of the gain block. For example, to generate a solid disk from the circle function described above, the gain function could be programmed to change after each circle cycle ranging from a gain of zero to a gain appropriate for the desired disk size.
The gain block, as illustrated in the circuit diagram in
The third block (the offset block) provides for a DC offset value to be added to the function/gain signal produced by the first two blocks. This allows the pattern to be placed statically at any place within the angular range of the tilt mirror. Again, the offset block allows for the 8-bit resolution control of the DC offset and timing control of the offset modulation. This enables the amplitude-modulated function described above to be replicated at various positions over time. For example, to produce a bipolar scan pattern comprising two disk patterns that are offset spatially from each other, the offset block could be programmed to switch between two voltages with the switch rate set to match the time it takes to scan out the full disk described above. The voltage difference between the two voltages is set to produce the desired spatial separation of the disk-shape scan patterns.
The offset block, as illustrated in the circuit diagram in
A summing stage that sums the output (Function*Gain) from the gain module with the offset signal to produce a signal equal to (function*gain)+offset. The summing stage comprises op amp IC16, input resistors R21-R22, and feedback resistor R26, connected in an inverting summing amplifier configuration for channel A, and identically connected IC16B, R23-R24, and R25, for channel B.
The outputs from the DC offset module is coupled to the input of the power op amps that provides the modulated drive current to the scan coils on the tilt stage. The power op amps serves to provide a high impedance input for the offset module to drive. An example of the scan pattern that can be produced with the invention along with the scan characteristic controlled by each module is shown in
To generate the disk geometry indicated by the two circular patterns in
In
Complete reprogramming of the system can be achieved in approximately 1 minute. If more rapid switching is desired, the system described above can be replicated and a computer controlled analog multiplexer can be used to select the desired output. This is illustrated in the block diagram in
Even more generally the computer controlled analog multiplexer/demultiplexer could choose from one of the available function blocks, one of the available gain blocks, and one of the available offset blocks, greatly increasing the instantly available scan options by allowing the rapid selection of one permutation out of all possible permutations. This is illustrated in the block diagram in
A vacuum-compatible 2-dimensional tilt stage similar to that shown in
The tilt stage was equipped with four rare-earth permanent magnets that were attached on the backside of the aluminum mount. The four magnets and their associated coils and current sources operated as two push pull pairs. One pair controls x tilt and the other pair controls y tilt. Scanning was achieved by running current through the coils so that as current passed through one coil pair, one coil pulled on the magnet above it and the opposite coil pushed the magnet above it. The system is designed to operate somewhat below mechanical resonance, and a scanning frequency of approximately 85 Hz have been achieved.
The inventive tilt stage is particularly suited for EUV lithography applications wherein a beam of EUV radiation, which can be coherent or non-coherent, is scanned through a set of angles to create scan patterns at the entrance pupil of an illumination optics. Suitable lithographic optics are described, for example, in U.S. Pat. Nos. 6,226,346, 6,072,852, and 6,033,079 each to Hudyma and U.S. Pat. No. 6,188,513 to Hudyma et. al. which are all incorporated herein by reference.
Although only preferred embodiments of the invention are specifically disclosed and described above, it will be appreciated that many modifications and variations of the present invention are possible in light of the above teachings and within the purview of the appended claims without departing from the spirit and intended scope of the invention.
The U.S. Government has certain rights in this invention pursuant to Contract No. DE-AC03-76SF00098 between the United States Department of Energy and the University of California for the operation of the Lawrence Berkeley National Laboratory.