EP0736171A1

EP0736171A1 - Fast spectroscopic ellipsometer

Info

Publication number: EP0736171A1
Application number: EP95905090A
Authority: EP
Inventors: Wolfgang Fukarek
Original assignee: Max Planck Gesellschaft zur Foerderung der Wissenschaften eV
Current assignee: Max Planck Gesellschaft zur Foerderung der Wissenschaften eV
Priority date: 1993-12-20
Filing date: 1994-12-20
Publication date: 1996-10-09
Also published as: WO1995017662A1; DE4343490A1

Abstract

A high-speed ellipsometric measuring process for any number and sequence of measuring light wavelengths, suitable especially for the in situ measurement of processes on a substrate surface. A broad-band radiation source (1) and an opto-acoustically tunable filter (4) which can be controlled by a PC (10) are used for fast wavelength selection.

Description

Fast spectroscopic egg lipometer

The invention relates to an ellipsometric measuring method according to the preamble of claim 1 and a device for carrying it out.

Ellipsometry is an optical method of investigation, particularly in solid-state and surface physics, in which totally polarized light of a certain wavelength strikes the sample at a relatively large angle of incidence (close to the angle of total reflection). The reflected light is generally elliptically polarized. Depending on the frequency of the incident light, the polarization state of the reflected light, characterized by the direction and ratio of the main axes, and possibly also the absolute value of the amplitude are measured. In surface physics, ellipsometry is used to measure the optical constants and the thickness of thin layers, e.g. Oxide layers and films. It is also possible to analyze multilayer systems and inhomogeneous or anisotropic layers. Ellipsometric measurements can also be used for structure elucidation (roughness, density, microcrystallinity, composition).

Developments in the field of ellipsometry in recent years have led to the distinction between two types of egg ellipsometers. On the one hand, these are real-time in-situ ellipsometers, which are used in statu nascendi to measure at one or a few fixed wavelengths. The most important parameter of these devices is the measuring speed. It must be greater than the measurable change in the optical properties of the measurement object, which is caused by the process, for example the growth of a layer, on the layer or surface. The second group are spectroscopic egg lipometers, with which measurements are carried out quasi-continuously in a specific wavelength range.

In the case of egg lipometers for real-time in-situ measurements, a laser or a combination of several lasers is very often used as the light source. The quite simple construction of these devices is advantageous since no dispersive elements are required. The high intensity and quality of the laser beam is also advantageous. The main disadvantage of these egg lipometers is that spectroscopic measurements are in principle not possible with these designs. In addition, the measuring light wavelength is not freely selectable.

A large number of different arrangements are known for spectroscopic egg lipometers. The most widespread is the use of grating monochromators or grating / prism monochromators as the dispersive element and a Xe short-arc lamp or a halogen lamp as the light source. It is advantageous with these arrangements that monochromators are available which cover a very large spectral range (for example 200 ... 2000 nm), the order filters being changed automatically. These devices can also be used for real-time in-situ measurements if the monochromator is set to a fixed wavelength. If, however, measurements are to be carried out with several wavelengths, the achievable measuring speed decreases sharply due to the time required to move the grating (and possibly a filter). As a result, real-time measurements at several wavelengths with such a structure are not possible. A known alternative is to couple out several spectral lines at the output of the monochromator with the aid of light guides. However, a separate detector is required for each measuring light wavelength, and the position of the measuring light wavelengths can no longer be freely selected. When choosing between spectroscopic measurement and fast measurement with Some fixed wavelengths require a change in the beam path in these structures. In another known arrangement, with which real-time measurements are possible, an optical multichannel analyzer (OMA = Optical Multichannel Analyzer) is used as the detector unit. The typical measuring time of these devices for an ellipsometric spectrum is 1 s. These devices always measure in the entire spectral range of the OMA. It is not possible to increase the measuring speed by reducing the number of measuring light wavelengths. The correction of the spectral sensitivity of the OMA, the spectral intensity distribution of the light source and the spectral dependency of the absorption of the optical components of the egg lipometer can only be achieved with corrective filters in these arrangements, since measurements are carried out simultaneously at all wavelengths.

With all structures that use a monochromator or an OMA, the parallel measuring light beam must be focused on the input slit. Depending on the extent of the light source, the quality of the optics used and the maximum permissible slit opening at the desired spectral resolution, intensity losses in the measuring light can occur as a result.

It is accordingly an object of the present invention to provide an ellipsometric measuring method and a device for carrying out the method with which the possible uses of the ellipsometric measuring technique can be expanded. In particular, it is an object of the present invention to increase the measuring speed of the ellipsometric measuring technique when measuring with several wavelengths.

This object is achieved by the characterizing features of claim 1. Advantageous refinements are specified in the subclaims. The present invention consists in an ellipsometric measuring method with which in situ both time-resolved with any number of freely selectable measuring light wavelengths and non-time-resolved measurement can be carried out quasi-continuously without the need for a modification on the device. The invention has the advantage that the number and position of the measuring light wavelengths can be freely selected. In addition, the time required for setting the measuring light wavelength is considerably shortened compared to the methods known in the prior art and is independent of the previously set measuring light wavelength. It is not necessary to focus on an entry slit.

The invention is explained in more detail below with reference to the figures.

Show it:

Figure 1 is a schematic overall view of the ellipsometric measurement setup according to the invention.

2 shows a schematic overall view of an alternative embodiment of the ellipsometric measurement setup according to the invention; and

Fig. 3 is a schematic representation of the operation of an acousto-optical filter.

The measuring setup shown in FIG. 1 contains a spectrally broadband radiation source 1, such as a xenon lamp, with a spectral characteristic which preferably covers the entire visible and parts of the infrared spectral range. The broadband radiation beam is coupled into an optical waveguide 2, which is connected to an objective 3. The objective 3 is used to prevent the divergent radiation emerging from the optical waveguide 2 parallelize bundles or focus on the sample. For example, a zoom lens can be used as the lens 3. In the acousto-optical filter 4, a spectrally narrow-band, linearly polarized radiation beam is diffracted from the broadband input radiation. This is post-polarized with a polarizer 5, whereupon it strikes the flat surface of a sample 6 to be examined. The reflected radiation beam is generally elliptically polarized and strikes an analyzer 7 whose direction of polarization can be changed. The radiation intensity of the reflected radiation beam is measured behind the analyzer 7 by a radiation detector 8. The output signal of the radiation detector 8 is fed to a current-voltage converter / amplifier 9 or an analog / digital converter. Its output signal is fed into an input of a personal computer (PC) 10 and further processed there with suitable computer programs. In the embodiment of an egg lipometer shown, the polarization direction of the analyzer 7 is varied and the dependence of the radiation intensity on the angular position of the analyzer 7 is measured.

FIG. 2 shows an alternative embodiment of an egg lipometer according to the invention.

In this embodiment, the acousto-optically tunable filter (4) is arranged in the beam path behind the sample (6) in a modification of the measurement setup according to FIG. 1. In this configuration, the sample (6) is thus irradiated with spectrally broadband radiation, the wavelength selection only being carried out with the radiation beam reflected on the sample. The acousto-optically tunable filter (4), as shown here, is arranged between the analyzer (7) and the radiation detector (8).

The invention is equally applicable to both embodiments of egg ellipsometers. In a further common embodiment of an Eilipsometer, a phase-modulating element, for example an electro-optical retarder, is used instead of a rotating polarizer or analyzer.

A non-collinear acousto-optical filter 4 is shown schematically in FIG.

Such a filter is known per se in the prior art and e.g. in the company name "AOTF SPECTROSCOPY" by BRIMROSE, 5020 Campbell Blvd. , Baltimore, MD 21236.

The filter essentially consists of a TeO "crystal 43 with two plane-parallel ground end faces. An ultrasonic transducer 42 is applied on one side. The ultrasonic transducer is e.g. a piezoelectric transducer that converts an electrical signal from a high-frequency generator 41 into ultrasonic waves. Ultrasound waves 44 generated in this way propagate in the acousto-optical medium and are absorbed in an acoustic absorber 45 attached to the opposite crystal surface. The spectrally broadband radiation beam 46 falls into the crystal with a small angle of inclination against the ultrasonic wave front. As a result of the interaction of the light with the ultrasound waves, two diffracted, linearly polarized and monochromatic radiation beams 48 and 49 are generated. The non-diffracted radiation beam 47 (zero order) and the diffracted radiation beam 49 are masked out by means of a diaphragm device 50. The monochromatic radiation beam 48 is used for the measurement.

By varying the ultrasound frequency, ie the frequency of the electrical signal supplied to the ultrasound transducer 42, the wavelength of the diffracted radiation beams 48 and 49 can be adjusted. An angle dependency of the diffracted radiation beam of the wavelength can be corrected by using a prism positioned behind the filter.

A detailed description of the physical principles of such acousto-optical filters can be found, for example, in DE-OS 24 31 976.

The use of a non-collinear filter is a preferred embodiment of the present invention. However, a collinear type filter can also be used.

The number and position of the measuring wavelengths are determined beforehand for a measuring process. Each of these measuring wavelengths corresponds to a specific electrical signal frequency to be set on the high-frequency generator 41. This can of course be done, on the one hand, by manually operating the high-frequency generator 41. However, a personal computer PC 10 can also be connected to the high-frequency generator 41 by a signal line 11. In this way, the wavelength selection can be controlled by the PC. This can be done by manually entering the next measuring wavelength to be selected on the keyboard of the PC, whereupon the PC sends a signal to the high-frequency generator via the signal line 11 for setting the required high-frequency electrical frequency. However, an automatic measuring program can also run on the PC 10, which contains the measuring wavelengths to be used. In this case, after the measurement process for one measurement wavelength has elapsed, the program automatically calls the next measurement wavelength and sends a corresponding signal to the high-frequency generator 41 via the signal line 11. The sequence of the measuring process for a measuring wavelength can be indicated to the measuring program in a suitable manner, for example by the current-voltage converter / amplifier 9. The setting of the measuring Wavelength can thus occur very quickly and in a purely electronic way without mechanically moving parts and without changing the geometry of the measuring light beam.

Another advantage of the method according to the invention is that focusing on an entrance slit, e.g. when using a grating monochromator, is not required. Rather, in the present case, the measuring beam with its beam cross section traverses the acoustically optically tunable filter.

Another advantage of the method according to the invention is that the light intensity striking the radiation detector 8 can be electronically controlled. As a result, the spectral intensity distribution of the light source, the spectral dependence of the absorption of the optical components of the egg lipometer and the spectral sensitivity of the detector can be compensated so that the signal measured at the detector has no significant spectral dependency, so that the maximum dynamic range of the analog / Digital converter can be used. The control of the light intensity can e.g. by varying the radiation cross section of the spectrally broadband radiation beam in the acousto-optical filter or by varying the signal amplitude of the voltage signal generated in the high-frequency generator 41. In this case, information about the required signal amplitude is transmitted on the signal line 11 in addition to the information required for the wavelength selection.

Claims

PATENT CLAIMS

1. Ellipsometric measuring method, characterized by the use of an acousto-optically tunable filter (4) for tuning the measuring wavelength.

2. The method according to claim 1, characterized in that a spectrally broadband radiation beam (46) on the acousto-optically tunable filter (4) is directed that a spectrally narrow-band radiation beam (48) deflected in the acousto-optical filter (4) to the surface of one examining sample (6) is directed, and that the wavelength of the spectrally narrow-band radiation beam (48) is tuned with the acousto-optical filter.

3. The method according to claim 1, characterized in that a spectrally broadband radiation beam (46) is directed onto a sample to be examined (6), and that the radiation beam reflected on the sample (6) onto the acousto-optically tunable filter (4) is directed, and that the wavelength of a spectrally narrow-band radiation beam (48) diffracted in the acousto-optical filter (4) is tuned.

4. The method according to claim 1, characterized in that the acousto-optical filter (4) is supplied with a high-frequency voltage signal from a high-frequency generator (41) and that the tuning of the acousto-optical filter (4) takes place such that the frequency of the voltage signal is varied, and that the high-frequency generator (41) is connected via a signal line (11) to an output of a personal computer (PC) (10).

5. The method according to claim 4, characterized in that a number and sequence of measuring wavelengths is determined and that the measuring method is controlled by a measuring program in such a way by the PC (10) that the acoustic-optical filter after each measuring process completed for a measuring wavelength (4) to the next following measuring wavelength in the predetermined order of measuring wavelengths.

6. The method according to claim 5, characterized in that the PC (10) sends a signal to the high-frequency generator (41) for changing the frequency of the voltage signal.

7. The method according to claim 1, characterized in that the spectrally broadband radiation beam (46) is generated in a radiation source (1), that the radiation beam (46) is guided in an optical waveguide (2) and that the radiation beam (46) in one parallelized with the optical waveguide (2) lens (3) or on the sample

(6) is focused.

8. The method according to claim 4, characterized in that the radiation intensity of the spectrally broadband radiation beam (48) is varied by varying the amplitude of the high-frequency generator (41) supplied voltage signal or by varying the radiation cross section by means of a variable aperture.

9. The method according to any one of the preceding claims, characterized in that the spectrally narrow-band radiation beam (48) is directed at the output of the egg lipometer to a radiation detector (8), that the output signal of the radiation detector (8) a current-voltage converter / Amplifier (9) is supplied, and that the output signal of the current-voltage converter / amplifier (9) is fed to an input of the PC (10).

10. The device for performing the method according to one of the preceding claims, characterized by a radiation source (1) having a spectrally broadband

Radiation beam (46) generates a sample (6) to be examined and an acousto-optic arranged in the beam path from _s tunable

Filter (4).

11. The device according to claim 10, characterized in that the acousto-optical filter (4) is connected to a high-frequency generator (41).

12. The apparatus according to claim 11, characterized in that the high-frequency generator (41) for automatic or manual control of the measurement process is connected to an output of a PC (10).

13. The apparatus according to claim 10, characterized in that the acousto-optical fitler (4) is a non-collinear filter.

14. The apparatus according to claim 10, characterized in that the acousto-optical filter (4) is a collinear filter.

15. The apparatus according to claim 10, characterized in that the outlet opening of the radiation source (1) is connected to an optical waveguide (2), and that the Licht¬ waveguide (2) is connected at its outlet end to a zoom lens (3).