DE6604638U - POLARIMETERS - Google Patents

Description

Utility model registration

Bodenseewerk Perkin-Elmer & Co., GmbH., Überlingen / Bodensee

Polarimeter

The innovation "relates to a polarimeter with a source polarized Light in front of a sample and an analyzer behind the sample, means for generating a periodic Rotation of the polarization plane of the polarized light a central layer, a detector acted upon by the light passing through the analyzer, filter means,

f which of the Detektorsigna.l only the component with the

j simple frequency of the periodic rotation of the polarization

^! Let the tion plane take effect, means for changing the said central position of the polarization plane and a quarter-wave plate in the beam path in front of the sample «

Two quantities are characteristic of the polarization behavior of a sample: the optical rotation and the circular dichotomy, roism. The optical rotation is caused by

j that right and left circularly polarized light are different Finds fallow indices. This makes the plane of polarization of incident linearly polarized light that As is well known, one can think of a right-hand and a left-hand circularly polarized component as being composed. If circular dichroism occurs, the extinction constants are for right and left circularly polarized Light different. Linearly polarized light then becomes elliptically polarized light.

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The wavelength dependence of these quantities is of particular interest. Spectropolarimeters are therefore provided in which the radiation is passed through a monochromator, so that each time a whole spectral range is scanned

For measuring the optical rotation or optical eotation dispersion in spectropolarimeters, an arrangement is known in which the radiation from a light source or a monochromator passes through a polarizer, the exiting linearly polarized light hits an analyzer behind which a radiation detector is arranged, and through the sample the polarizer is rotated by an adjustment motor according to the detector signal ₀ To generate a suitable detector signal, the polarizer executes torsional vibrations around its central position, so that a periodic rotation of the polarization plane of the light takes place. If the central position of the plane of polarization of the light striking the analyzer is perpendicular to the direction of transmission of the analyzer, then only a signal with twice the oscillation frequency of the polarizer occurs at the detector. If, on the other hand, the central position of the plane of polarization of the light falling on the analyzer is not perpendicular to the direction of transmission of the analyzer, then a component will also appear in the detector signal which corresponds to the simple oscillation frequency of the polarizer. This signal can thus serve as a measure for the rotation of the mean polarization direction, that is to say for the optical rotation caused by the sample, and can be brought into effect via suitable filter means. This can be an electrical filter element that suppresses the higher harmonics, in particular double the five-round frequency. It can be a Ferrari motor for adjusting the polarizer, one winding with the detector signal and the other winding with it

an alternating voltage of the simple polarizer oscillation frequency is charged. The oscillation of the polarization plane can be caused by mechanical oscillations of the polarizer be generated. However, a Faraday modulator can also be used. Similarly, the rotation of the plane of polarization for the purpose of adjustment by rotating the polarizer or by being arranged behind it in the beam path This is done using the Faraday effect. The subsequent rotation of the plane of polarization of the light falling on the sample, which is necessary for the adjustment, is a measure for the optical rotation in the sample.

To measure the circular dichroism, it is known to directly determine the difference in the absorption of right and left circularly polarized Measure light. For this purpose a polarization prism is provided through which a linearly polarized Beam is generated. This "bundle" falls on an electro-optic crystal that forms an alternating current field exposed so that it becomes birefringent and out of the incident linearly polarized light alternately makes right and left circularly polarized light. This alternately

Right and left circularly polarized light passes through the sample and then falls on a photoelectric receiver. For example, if the sample is left circularly polarized more strongly absorbed than right circularly polarized, then " during the half-wave, during which the light is left circularly polarized is, a lower luminous flux falls on the receiver than during the other half-wave in which the light is right circularly polarized. An alternating current signal is generated at the receiver. The ratio of the occurring at the recipient The alternating current signal to the direct current signal, which also occurs, serves as a measure of the circular dichroism. Such Arrangement only allows the measurement of circular dehroism. For measuring the optical erosion dispersion

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must be a completely different device, such as the one described above Kind, to be provided.

For this reason, an arrangement has been proposed in which the circular dichroism is not derived from the difference in absorption but rather from the ellipticity of that which is leaving the sample Light is determined, and at what circular dehroismua and optical rotational dispersion can be measured simultaneously and with one and the same device. At the proposed Arrangement, a light beam emanating from a monochromator also penetrates a polarizer, a Faraday modulator, the sample and an analyzer, behind which a detector is arranged. It is there, however, between that Polarizer downstream Faraday modulator and the sample a Lambdavxertelplatte arranged. Another Faraday modulator is arranged in front of the analyzer. The two Faraday modulators are operated at different frequencies, and the two basic frequencies are filtered out and are used to control a servomotor for rotation of the polarizer or analyzer. Here is the rotation of the polarizer from the optical axis of the Lambda xertel plate a measure of the circular dichroism, the rotation of the analyzer a measure of the optical rotation. It is here a special device with double adjustment by rotating the polarizer and the analyzer required «

In contrast, the innovation is based on the task of a polarimeter to create with which with a minimum of effort with a single device both optical rotation as circular dichroism can also be measured.

The innovation is still based on the task of a polarimeter set up for measuring the optical rotation

to equip with simple means in such a way that the Measurement of circular dichroism permitted.

The innovation is also based on the task of circular dichroism to measure in such a way that the measurement is independent of the optical rotation.

The innovation is based on a polarimeter in the input mentioned type and consists in the fact that the quarter wave plate can optionally be switched into the beam path.

Thus, with a single device and using the same optical elements, the same detector and a single servomotor or the like, the circular dichroism as well as the optical rotation can be measured for the adjustment. However, the measurement does not take place at the same time; instead, one or the other variable is measured alone, which is quite desirable in some cases. When the quarter wave plate is removed from the beam path, the device operates in the manner described above and measures the optical rotation. The angle of rotation of the polarizer is directly equal to the optical rotation in the sample. If, on the other hand, a lambda wave plate is inserted into the beam path between the polarizer and the sample, a "signal component of frequency W ₁ " results as a first approximation.

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- ** -OJ r \ V i-iy-i r \ I * —f - / Z /

/ * \ TT Tr * J ^ O 1 t> -l- «· C- 'S y OU ö c. <UU ο C. L- ^{u J} - ^

^{w1 2} cos 2ik sin 2 <z cos 2 isT. "o ^ sin W ₁ 1,

whereby the following terms were chosen:

^ = Angle between the forward direction of the polarizer and the fast axis of the quarter wave plate.

σ— = angle between the direction of transmission of the analyzer and the fast axis of the quarter wave plate.

CC = optical rotation of the sample.

'-> = angle of ellipticity of circular iohroism.

- ^ o = oscillation angle of the polarizer or the polarization plane of the incident light.

Cl <j = visual oscillation frequency of the polarizer «, X- = intensity of the incident light beam.

From equation (1) it can be seen that the signal component with the frequency W ₁ becomes zero when

(2) tg 25 = tg 2 7.5

is. At this point there is also a phase jump of the signal by 180 °. If the polarizer is rotated as a function of this signal U ₁ until the signal disappears, then the angular position C of the polarizer relative to the fast axis of the quarter wave plate immediately gives the ellipticity of the circular dichroism of the sample.

It is noteworthy that in the arrangement according to the innovation, the angle ^ in the balanced state is independent of the optical Rotation'X is because the term cos 2 ((/.--y) at zero putting the expression in brackets in equation (1) is dropped. That is by no means a matter of course and with comparable others Orders not the case.

An exemplary embodiment of the innovation is shown in the figure and described below:

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With 1 is a polarizer "denotes, on the sound one Monochromator a bundle of light of intensity I falls.

The linearly polarized light passes through the sample 2, an analyzer 3, when the optical rotation is measured and falls on a detector 4. The polarizer oscillates at a frequency w ^. Yon the detector signal is by means of of a filter 5, the signal component of the frequency w ^ sifted out and controls an actuator 7 via an amplifier 6. The actuator 7 rotates the polarizer 1. At In this mode of operation, the polarizer 1 is rotated until the central position around which the plane of polarization is reached oscillates in front of the analyzer 3, is perpendicular to the direction of passage of the analyzer. If there is no sample in the If the beam path is, the polarizer 1 is in its central position crossed to the analyzer 3ο for measurement of circular dichroism, a quarter-wave plate 8 is placed in the beam path between polarizer 1 and sample 2 introduced whose fast axis is perpendicular to the direction of passage of the analyzer 3. As shown above, the polarizer 1 is now rotated by an angle £ against the fast axis of the quarter-wave plate, which corresponds to the ellipticity angle ^ '], of circular dichroism.

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Claims (1)

• ι 3ο Claim to protection Polarimeter, in which the following along an optical axis Components are arranged: (a) a light source (b) an oscillating polarizer that can be rotated by a servomotor * is (c) a quarter wave plate (d) a sample cell (e) a fixed analyzer, the forward direction perpendicular to the fast axis of the quarter wave plate, and (f) a detector characterized in that the quarter-wave plate (8) can be moved out of the beam path. "» Mhnttll »