Birefringence measurement system

Details Birefringence measurement system Birefringence measurement system

1999-05-24

2002-10-29

Stafira, Michael P. (Department: 2877)

Optics: measuring and testing

By polarized light examination

Reexamination Certificate

active

06473179

ABSTRACT:

TECHNICAL FIELD
This application relates to a system and method for precise measurement of linear birefringence properties of a transparent sample.
BACKGROUND
Many important optical materials exhibit birefringence. Birefringence means that different linear polarizations of light travel at different speeds through the material. These different polarizations are most often considered as two components of the polarized light, one being orthogonal to the other.
Birefringence is an intrinsic property of many optical materials, and may also be induced by external forces. Retardation or retardance represents the integrated effect of birefringence acting along the path of a light beam traversing the sample. If the incident light beam is linearly polarized, two orthogonal components of the polarized light will exit the sample with a phase difference, called the retardance. The fundamental unit of retardance is length, such as nanometers (nm). It is frequently convenient to express retardance in units of phase angle (waves, radians, or degrees) which is proportional to the retardance (nm) divided by the wavelength of the light (nm). An “average” birefringence for a sample is sometimes computed by dividing the measured retardation magnitude by the thickness of the sample.
The two orthogonal polarization components described above are parallel to two orthogonal axes, which are determined by the sample and are called the “fast axis” and the “slow axis.” The fast axis is the axis of the material that aligns with the faster moving component of the polarized light through the sample. Therefore, a complete description of the retardance of a sample along a given optical path requires specifying both the magnitude of the retardance and the relative angular orientation of the fast (or slow) axis.
The need for precise measurement of birefringence properties has become increasingly important in a number of technical applications. For instance, it is important to specify and control the residual linear birefringence (hence, the attendant induced retardance) in optical elements used in high precision instruments employed in semiconductor and other industries. The optics industry thus has a need for a highly sensitive instrument for measuring linear birefringence in optical components. This need has been largely unmet, especially with respect to measurements of low levels of retardance.
SUMMARY OF THE INVENTION
The present invention is directed to a practical system and method for precisely measuring low-level birefringence properties of optical materials. The retardance magnitude and orientation of the fast axis are precisely calculated. The system permits multiple measurements to be taken across the area of a sample to detect and graphically display variations in the retardance across the sample area.
In a preferred embodiment, the system incorporates a photoelastic modulator for modulating polarized light that is then directed through a sample. The beam propagating from the sample is separated into two parts. These separate beam parts are then analyzed at different polarization directions, detected, and processed as distinct channels. The detection mechanisms associated with each channel detect the light intensity corresponding to each of the two parts of the beam. This information is employed in an algorithm for calculating a precise, unambiguous measure of the retardance induced by the sample and the orientation of the fast axis.
As one aspect of this invention, the system includes a beam-splitting member and detector arrangement that permits splitting the beam into two parts with minimal contribution to the retardance induced in the beam. Moreover, the presence of any residual birefringence in the optical system (such as may reside as static birefringence in the photoelastic modulator or in any of the optical components of the system) is accounted for in a number of ways. For example, certain of the system components are arranged or mounted to minimize the chance that strain-induced birefringence may be imparted into the element. A reliable calibration technique is also provided.
The system permits the low-level birefringence measurements to be taken at any of a plurality of locations across the area of the sample. The measurements are compiled in a data file and graphically displayed for quick analysis.
In one embodiment of the invention, the optical components of the system are arranged to measure the birefringence properties of a sample that is reflectively coated on one side, thereby permitting measurement of birefringence properties even though the sample is not completely light transmissive.
Other advantages and features of the present invention will become clear upon study of the following portion of this specification and drawings.


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