DE19545018A1 - Polarimeter for observation of angle of rotation in reactions - Google Patents

Abstract

The polarimeter uses a computer controlled polarimeter for measuring angle of rotation changes and reactions, and provides for automatic long-term observation, as, for example, in mutarotations. The dependency of the rotation on the wavelength is demonstrated by the use of two different wavelengths. For observing the temperature dependency of rotation value determination, the polarimeter has a warmable measuring cuvette which holds the trial temperature constant and a pump/stir system, mounted on a hydraulic lift, with which a second substance can be introduced during the measuring process.

Description

field of use

The invention relates to a device for observing Drehwin changes and reactions over a predefined time room and under constant test conditions.

purpose

The device is used for user-friendly measurement and graphi representation of angles of rotation and changes in angles of rotation over a certain period of time and to observe the tem temperature dependency when determining rotary values. Long-term measurement solutions with the device allow a kinetic consideration of Reactions (e.g. mutarotations). By measurements on two The effect of the rotary dis persion be occupied.

State of the art

As far as we know, there are polarimeters that measure the moment Determine the tan rotation value of a solution.

Critique of the state of the art

An observation of a change in the angle of rotation over a length Their period is very cumbersome with conventional polarimeters Lich, since the measurements are not automated. Reactions, at which the rotational value after adding a second educt changes can only be observed with increased effort. The heat of reaction in such reactions can with usual Devices are not removed, so that the rotation value changes becomes.

task

The invention has for its object the usual devices to complete.

solution

Construction of a temperature-controlled cuvette for keeping constant the test temperature. A second substance can be used during the ongoing measurement with a pump / stirring system in the Cuvette be given. With the computer control that is Measurements can be carried out without further control.

Further embodiment of the invention

The complete experimental set-up is in a "light-tight" Test box. A PC takes over the control and monitoring of the trial, so that very user-friendly measurements be made possible. The one programmed under Borland Pascal 7.0 "PolarDos 2.0" software allows the graphic display of the Measurement results. A glass jacket around the cuvette can measure temper the substance (external connection of a thermostat). A second substance for the purpose of measuring the angle of rotation in the case of reactions without much effort, a pump / agitator system was constructed. A little stirrer which is only briefly lowered into the cuvette by a lifting platform is mixed by a pump into the reaction vessel arrived second substance with the starting substance. The lifting stage is necessary to avoid the disturbing influence of the stirrer Avoid beam path. There are two different types for measurement light sources available (589 nm; 670 nm), d. H. the Ab Dependence on wavelength and angle of rotation can be achieved with the device to be examined.

Achievable advantages

The measurements with our device are more user-friendly too make because measurements over a longer period automa be monitored and carried out by the computer. Shoot changes in the angle of reactions can be the same Temperature can be observed.  

Description of several embodiments

The basic requirement of a measuring device is that it allows reproducible measured values, i. H. that the same results are obtained in the same experiments. To do this with the patent To check the registered polarimeter, we carried out several measurements under the same Experimental conditions by, d. H. we determined the angle of rotation of an optically active one several times Substance. The test results were approximately constant in all measurements.

At the beginning of an experiment, the polarimeter is correctly connected to the computer and started the control program. When a mode is started, the calibration window opens automatically. With The device is calibrated to an optically inactive liquid in the cuvette. The cuvette is then filled with the measuring solution without bubbles and streaks (35 ml) and in Beam path fixed with the cooling hoses. A second liquid substance (maximum 5 ml) can can optionally be added to the pump vessel to make them into a long-term measurement to be pumped into the cuvette to the measurement solution at a specific time. In the program, the Trial options customized and the trial started.

This chapter describes various possible uses of a polarimeter.

1. Angle of rotation at different wavelengths

Our polarimeter offers the possibility of measuring by measuring at two different wavelengths To show dependence of the rotation on the wavelength. This normal rotational dispersion that too It was discovered in the early 19th century by F. ARAGO and B. BOT, that the angle of rotation decreases with increasing wavelength. With the following experiment, the effect can be demonstrated will.

Preparation: 13.59 g (-) - fructose are completely dissolved in 50 ml of water and with laser and LED light is examined for its angle of rotation. The expected rotation value should be at 589 nm Wavelength is around α = -25 ° (calculated). To determine the average 5 measurements are sufficient.

In this experiment, however, it should be noted that the fructose changes its angle of rotation after some time changes (mutarotation). The two measurements should therefore take place one after the other without a break be performed.

Result: At the wavelength of 589 nm we got an average rotation of α = -23.94 °. As expected, the laser light gave us a significantly lower rotation value of only α = -20.48 °.

2. Determination of specific angle of rotation

The determination of specific angles of rotation is possible with our polarimeter, since we have the Test conditions (measurement at 589 nm, 1 dm cell length, room temperature, certain Concentration).

Preparation: Dissolve a weighed amount of a substance in 100 ml of distilled water. Man should ensure that the solution is bubble-free and at a temperature of 20 ° C in the cuvette is filled. The current rotation value at the wavelength of 589 nm is determined.

Result: The measured rotation value α, the Concentration c in g / 100 ml and the cuvette length / (1 dm) and receives the specific angle of rotation the substance used.

Example: Calculating the specific angle of rotation of fructose:

We achieved a percentage deviation of 4.23%. The literature value for fructose is [α] = -91.97 °.

3. Determination of concentration

With the optical rotation capacity of a known substance, its concentration can be determined determine.

Preparation: You measure the current rotation value of a solution of unknown concentration at 589 nm.

Result: The solution concentration is calculated using the concentration equation.

Example: The rotational value of a fructose solution of α = -44.85 ° at wavelength 589 is obtained nm, 1 dm cell length and room temperature. This results in the concentration with the specific rotation value of [α] = -91.97 °:

The measuring solution had a concentration of 48.77 g / 100 ml.

4. Inversion of sucrose

An aqueous solution of the disaccharide cane sugar (sucrose) is not stable. The Raw sugar molecule breaks down to form the monosaccharides β-fructose and α-glucose (same Molarity). The two monosaccharides immediately build up a chemical equilibrium, so that too β-glucose and α-fructose are formed. After a while, there are no more sucrose particles Solution before. The sucrose is strongly clockwise in solution ([α] = + 66.5 °). After the reaction dominates the strong left-turning fructose ([α] = -91.97 °) compared to the relatively weak clockwise glucose ([α] = + 52.7 °), so that the angle of rotation from initially clockwise turns to the left. This effect is called inversion.

Chemical equation

Preparation: Dissolve 12 g sucrose in 35 ml distilled water (34.29 g / 100 ml) and fill it Cell free of bubbles. Then add 5 ml to the pump vessel that has been rinsed with the pump solution concentrated hydrochloric acid (36%). in the Select the program "PolarDos 2.0" the mode "course measurement". The Trial duration after the The addition of hydrochloric acid is this Approach around 2000 s.

Result: The (average) rotation value from the beginning
In the end, α = + 18.525 ° in our measurement reached a value of α = -6.825 °. We calculated an average course from several test series (diagram 1).

Diagram 1: Inversion measured with our polarimeter

The acceleration of the hydrolytic cleavage after the Acid addition is based on the catalytic Effect of hydronium ions (H₃O⁺) attributed, d. H. the higher the concentration of H₃O⁺ ions is, the faster the end products are formed.

The initial rotation value (literature) at 589 nm of the sucrose directly after the dissolution is after the Equation at

In the final state there is a mixture of

in front. From this can to get the final speed of

to calculate (Measurement at 670 nm: α = -6.825 °). The deviations in the initial value are 18.75% or at 1.41% at the final speed. The difference between the calculated and measured value is with the different wavelengths (literature: 589 nm; measurement: 670 nm) (Rotational dispersion), whereby measurement errors cannot be excluded.  

5. Mutarotation of α- and β-glucose

Mutarotation is a change in the angle of rotation of an optically active one over time Substance.

This effect is observed especially with sugar solutions that have been left for a long time will. An intramolecular rearrangement of sugar molecules from the α to the β form and conversely, the change in the angle of rotation over time explains. If one dissolves α- or β-glucose in water, it provides a chemical equilibrium state develops after some time.

Chemical equation

Preparation: An α-glucose solution with a concentration of 4.375 g in 35 ml of water becomes bubble and Filled into the test cell free of streaks. It will change the angle of rotation over 2.5 hours observed. The attempt will then analogously with β-glucose repeated.

Result: With the α-glucose falls the rotational value of measured 95.55 ° to 49.725 ° after the Attempt. The rotation value of the β-glucose solution rises from 17.55 ° 47.775 °. You extrapolate it Limit of both Test results at our average Measurement results at 48.75 °. The α-glucose changes that Angle of rotation by 46.8 °, the β-glucose by 31.2 °. Of the So equilibrium can be by

in other words, 40% of the α- or 60% beta form before (literature: 36.1% and 63.9%). The measurement error was included in our measurement 6.1%.

Diagram 2: Observation of the mutarotation with our polarimeter

Claims (3)

1. Computer-controlled device for measuring angles of rotation and angles of rotation characterized in that it offers the possibility of an automatic long-term observation using the PC. 2. Pump / stirring system mounted on a lifting platform. 3. Temperature-controlled measuring cell, characterized in that a further substance in the Stir the measuring solution and keep the test temperature constant can be.