Continued on next page

Similar documents
H H H O. Pre-Lab Exercises Lab 6: Organic Chemistry. Lab 6: Organic Chemistry Chemistry Define the following: a.

Determination of a Chemical Formula

Properties of Alcohols and Phenols Experiment #3

Amino Acids, Peptides, and Proteins

Recovery of Elemental Copper from Copper (II) Nitrate

experiment5 Understanding and applying the concept of limiting reagents. Learning how to perform a vacuum filtration.

AN EXPERIMENT IN ALCHEMY: COPPER TO SILVER TO GOLD 2005, 2000, 1996 by David A. Katz. All rights reserved

Experiment 7: Titration of an Antacid

Determining the Quantity of Iron in a Vitamin Tablet. Evaluation copy

Properties of Acids and Bases

Laboratory 22: Properties of Alcohols

CHM 130LL: ph, Buffers, and Indicators

EXPERIMENT 10: TITRATION AND STANDARDIZATION

Enzyme Pre-Lab. Using the Enzyme worksheet and Enzyme lab handout answer the Pre-Lab questions the pre-lab must be complete before beginning the lab.

COMMON LABORATORY APPARATUS

Lab 25. Acid-Base Titration and Neutralization Reactions: What Is the Concentration of Acetic Acid in Each Sample of Vinegar?

PREPARATION AND PROPERTIES OF A SOAP

The Empirical Formula of a Compound

Estimation of Alcohol Content in Wine by Dichromate Oxidation followed by Redox Titration

Dissolving of sodium hydroxide generates heat. Take care in handling the dilution container.

Table 1. Common esters used for flavors and fragrances

Colorimetric Determination of Iron in Vitamin Tablets

ph units constitute a scale which allows scientists to determine the acid or base content of a substance or solution. The ph 0

SOLUBILITY OF A SALT IN WATER AT VARIOUS TEMPERATURES LAB

Ascorbic Acid Titration of Vitamin C Tablets This lab will be completed individually! Make sure you come prepared!

Reaction Stoichiometry and the Formation of a Metal Ion Complex

Distillation Experiment

Austin Peay State University Department of Chemistry CHEM Empirical Formula of a Compound

Vitamin C Content of Fruit Juice

Household Acids and Bases

Acetic Acid Content of Vinegar: An Acid-Base Titration E10-1

SYNTHESIS AND ANALYSIS OF A COORDINATION COMPOUND OF COPPER

Properties of Acids and Bases

Juice Titration. Background. Acid/Base Titration

Synthesis of Aspirin and Oil of Wintergreen

1. Qualitative Analysis of Chromium, Iron, and Copper

EXPERIMENT 7 Reaction Stoichiometry and Percent Yield

CHEMICAL REACTIONS OF COPPER AND PERCENT YIELD KEY

(1) Hydrochloric acid reacts with sodium hypochlorite to form hypochlorous acid: NaOCl(aq) + HCl(aq) HOCl(aq) + NaCl(aq) hypochlorous acid

CH204 Experiment 2. Experiment 1 Post-Game Show. Experiment 1 Post-Game Show continued... Dr. Brian Anderson Fall 2008

This compound, which contains two carbon atoms with a C-OH structure on one end of the molecule is ethanol, commonly called ethyl alcohol.

PART I: PREPARATION OF SOLUTIONS AND STANDARDIZATION OF A BASE

In this experiment, we will use three properties to identify a liquid substance: solubility, density and boiling point..

CHEM 2423 Recrystallization of Benzoic Acid EXPERIMENT 4 - Purification - Recrystallization of Benzoic acid

Physical and Chemical Properties and Changes

The Chemistry of Carbohydrates

Synthesis of Fragrant Esters

Prussian blue and cyanotype printing

To determine the equivalence points of two titrations from plots of ph versus ml of titrant added.

Chem 100 Lab Experiment #9 - ACID/BASE INDICATORS

Solubility Product Constants

Austin Peay State University Department of Chemistry CHEM 1021 TESTING FOR ORGANIC FUNCTIONAL GROUPS

Taking Apart the Pieces

Vitamin C Content of Foods

Chemical Changes. Measuring a Chemical Reaction. Name(s)

18 Conductometric Titration

ph: Measurement and Uses

EXPERIMENT 12: Empirical Formula of a Compound

The most common active ingredient used in deodorants is aluminium chlorohydrate. But not all deodorants contain aluminium chlorohydrate:

ANALYSIS OF VITAMIN C

ACID-BASE TITRATIONS: DETERMINATION OF CARBONATE BY TITRATION WITH HYDROCHLORIC ACID BACKGROUND

OXIDATION-REDUCTION TITRATIONS-Permanganometry

Colorimetric Determination of Iron in Vitamin Tablets

Experiment 6 Coffee-cup Calorimetry

Evaluation copy. Case File 9. A Killer Cup of Coffee? GlobalTech manager dies

Lab #10 How much Acetic Acid (%) is in Vinegar?

THE ACTIVITY OF LACTASE

Paper Chromatography: Separation and Identification of Five Metal Cations

Reaction in a Bag. Scientific Method Demonstrations

Determination of the Mass Percentage of Copper in a Penny. Introduction

General Chemistry I (FC, 09-10) Lab #3: The Empirical Formula of a Compound. Introduction

Determination of Vitamin C of Citrus Juices. by Dr. Walter Scharf and Dr. Charles Malerich Natural Sciences, Baruch College New York, NY 10010

Neutralizing an Acid and a Base

Acids and Bases. AND a widemouth container of the following solids:

Determination of calcium by Standardized EDTA Solution

The Determination of an Equilibrium Constant

Calcium Analysis by EDTA Titration

STANDARDIZATION OF A SODIUM HYDROXIDE SOLUTION EXPERIMENT 14

Determination of Sodium Hypochlorite Levels in Bleach

EXPERIMENT 2 THE HYDROLYSIS OF t-butyl CHLORIDE. PURPOSE: To verify a proposed mechanism for the hydrolysis of t-butyl Chloride.

CHEMICAL DETERMINATION OF EVERYDAY HOUSEHOLD CHEMICALS

The Determination of Acid Content in Vinegar

Experiment 8 Synthesis of Aspirin

Acids & Bases Around the House Use a ph indicator to find acids and bases

SEPARATION OF A MIXTURE OF SUBSTANCES LAB

Enzymes Lab Pre-Lab Exercise

IODINE CLOCK. A Study of Reaction Rates.

DYES AND DYEING 2003 by David A. Katz. All rights reserved. Permission for classroom use provided original copyright is included.

Household Acids and Bases

Factors Affecting Enzyme Activity

Experiment 13H THE REACTION OF RED FOOD COLOR WITH BLEACH 1

Determining the Free Chlorine Content of Swimming Pool Water. HOCl H + + OCl. Evaluation copy

The Synthesis of trans-dichlorobis(ethylenediamine)cobalt(iii) Chloride

Molar Mass and the Ideal Gas Law Prelab

Measurement and Calibration

Concentrations and Dilutions of Food Dyes

Mixtures and Pure Substances

Sugar or Salt? Ionic and Covalent Bonds

Phosphates (ortho- and total)

Partner: Jack 17 November Determination of the Molar Mass of Volatile Liquids

Transcription:

1 Breathalyzer Reaction Introduction A breathalyzer (breath analyzer) is a device for estimating blood alcohol content (BAC) from a breath sample. The invention of the breathalyzer provided law enforcement with a non-invasive test providing immediate results to determine an individual's BAC at the time of testing. It does not, however, determine an individual's level of intoxication, as this varies by a subject's individual alcohol tolerance. The BAC test result itself can vary between individuals consuming identical amounts of alcohol, due to gender, weight, and genetic pre-disposition. Breath analyzers do not directly measure blood alcohol content or concentration, which requires the analysis of a blood sample. Instead, they estimate BAC indirectly by measuring the amount of alcohol in one's breath. There are several types of breathalyzer devices. Regardless of the type, each device has a mouthpiece, a tube through which the suspect blows air, and a sample chamber where the air goes. To measure alcohol in the breath, a suspect breathes into the device. The breath sample is bubbled into a vial which contains a mixture of chemicals that react with alcohol. The reaction of the alcohol results in a color change of the solution in the vial; the degree of color change is directly related to the level of alcohol in the expelled air. To determine the amount of alcohol in that air, the color of the reacted mixture is compared to the color of an unreacted mixture in another vial. The breathalyzer device then gives a readout that indicates the degree of color change and, hence, the level of alcohol in the suspect s breath. Ethanol, the alcohol present in alcoholic beverages, has the chemical formula C 2 H 5 OH. There are many other chemicals that are classified as alcohols, but they have different names and chemical formulas. For example, rubbing alcohol is called isopropanol and has the chemical formula C 3 H 7 OH. Continued on next page

2 The Chemical Reaction Used by the Breathalyzer Ethanol reacts with dichromate ion in acidic solution according to the chemical equation shown below. In this reaction, dichromate ion is converted to chromium ion. In solution the dichromate ion has an orange color, but the chromium ion is blue-green. This reaction is easily observed because the orange color disappears as dichromate ion is used up, and the blue-green color appears as chromium ion forms. 2-2 Cr 2 O 7 + 3 C 2 H 5 OH + 16 H + 4 Cr 3+ + 3 C 2 H 3 O 2 H + 11 H 2 O dichromate ion ethanol acid chromium ion acetic acid water orange color colorless colorless blue-green color colorless colorless If there is enough ethanol present to react with all of the dichromate ion and use it up in the reaction, the orange color will disappear entirely and the solution will become blue-green. On the other hand, there may be only a little ethanol present relative to the amount of dichromate ion present in other words, there is not enough ethanol to react with and use up all of the dichromate ion. In this case, some orange-colored dichromate ion remains after the reaction, along with some blue-green chromium ion that has formed due to the reaction with the small amount of ethanol present. This mixture of orange and blue-green ions will produce a solution that is a golden yellow color. The exact shade of golden yellow will depend on the relative amounts of orange dichromate and blue-green chromium ions in the mixture. For instance, more dichromate will give the solution an orange-yellow color; more chromium ion will give the solution a greenish-yellow color. In the breathalyzer test, the breath sample is bubbled into a vial which contains a solution of dichromate ion. Any ethanol in the breath sample reacts with the dichromate ion according to the reaction above, and the solution changes to a shade of golden yellow as a result of the reaction. The reacted mixture in this vial is compared to another vial which contains dichromate ion but no ethanol (so it will be bright orange). The difference in color between the two vials gives an indication of the amount of ethanol in the suspect s breath. In this experiment, you will carry out the breathalyzer reaction in test tubes. Rather than determining the amount of ethanol in a breath sample, you will determine the amount of ethanol in a wine sample.

3 Breathalyzer Reaction Prelab Name 1. The concentration of alcohol in one s is directly proportional to the concentration of alcohol in one s blood. 2. The device used to measure the alcohol content of a person s breath is the. 3. There are many different compounds that are classified as alcohols. For example, the alcohol found in rubbing alcohol is a different chemical compound than the alcohol present in alcoholic beverages. Ethanol is the name of the alcohol in alcoholic beverages. What is the chemical formula for ethanol? 4. The color of dichromate ion in solution is. The color of chromium ion in solution is. 5. Which chemical should you handle with care in this experiment (see next page)? What is the first thing you should do if you get some on your skin?

4 Breathalyzer Reaction Procedure Caution! The chromic acid solution (which contains the dichromate ion) used in this experiment is very corrosive and a strong oxidizing agent. Be very careful in handling and pouring this solution. Wear your safety glasses at all times. If you happen to spill some of this solution on yourself, immediately wash the affected area with plenty of cold water, then report the accident to the instructor. If you spill some of the solution on the lab bench, inform the instructor so that he/she can clean up the spill. A. Preparation of Color Standards for Comparison to the Wine Sample 1. Note: It is important that volumes be measured accurately and precisely! For a given step, use the type of pipet indicated. If you are unsure which type of pipet to use, or how to use it, ask the instructor. Use the 10 ml pipets provided to place the following amounts of distilled water and 0.1% ethanol solution into 11 large test tubes. Measure the volumes very carefully, because the accuracy of your measurements will determine how well this experiment turns out! When you are finished, each tube will contain a total of 10 mls of liquid. Test tube # 1 2 3 4 5 6 7 8 9 10 11 mls ethanol solution: 0 1 2 3 4 5 6 7 8 9 10 mls distilled water: 10 9 8 7 6 5 4 3 2 1 0 Mix the contents of each large test tube well with a glass stirring rod. If you stir the test tubes beginning with tube #1 and working up to tube #11 in order, there is no need to clean the stirring rod between test tubes. 2. Label 11 small test tubes with the numbers 1 to 11 using a wax pencil (do not try to use tape as labels). Using a 1 ml volumetric pipet, take 1 ml of liquid out of each of the large test tubes and place it into the small test tube with the corresponding number. If you begin with tube #1 and work in order up to tube #11, there is no need to clean the pipet between test tubes. After this, you will have a set of 11 small test tubes, each containing 1 ml of liquid. 3. Obtain a new Pasteur pipet and use it to add 20 drops of H 2 SO 4 (sulfuric acid) to each of the small test tubes. Then obtain another new Pasteur pipet and use it to add 1 drop of chromic acid solution (containing the dichromate ion) to each test tube. When finished, save the two pipets because you will need them later. Mix the contents of the small test tubes well with a glass stirring rod by beginning with tube 1 and working up to tube 11 in order (then there is no need to rinse the stirring rod between tubes). 4. Set up a hot water bath by filling a large beaker about 1/4 full with distilled water and placing it on a hot plate. Heat the water to ~80 o C. If it becomes too hot (~90 o C or higher), add a little cold water to cool it down. Try to find a setting on the hot plate that maintains the temperature near 80 o C. Then place the 11 small test tubes into the water bath and heat them for 5 minutes.

5 5. Remove the test tubes from the water bath and observe the colors of the solutions. Record your observations on the report sheet. Keep the water bath set up because you will need it later. B. Determination of the Ethanol Content of the Wine Sample The 11 small test tubes contain known amounts of ethanol since you carefully measured the amount of the 0.1% ethanol solution that went into each tube; the table below shows the % ethanol in each test tube. The 11 test tubes provide a set of color standards so that you can see the color produced as increasing known amounts of ethanol react with the dichromate ion. The more ethanol in a test tube, the fewer orange dichromate ions remain after the reaction, and the more blue-green chromium ions produced (see the chemical reaction in the introduction). Test tube # 1 2 3 4 5 6 7 8 9 10 11 % ethanol by mass-volume 0.00 0.01 0.02 0.03 0.04 0.05 0.06 0.07 0.08 0.09 0.10 Note: % ethanol by mass-volume means: mass of ethanol (in grams) per 100 ml of liquid. Example: 0.1 gram of ethanol in 100 ml of liquid: (0.1 g / 100 ml) x 100% = 0.1% Next you will mix chromic acid with a wine sample and observe the color that results when the ethanol in the wine reacts with the dichromate ion. The amount of ethanol in the wine is unknown. In order to determine the percentage of ethanol in the wine, you will compare the color of the wine sample to the 11 test tubes containing known amounts of ethanol. For instance, if the wine sample has the same shade of color as test tube #4, you can conclude that the wine sample contains 0.03% ethanol by mass-volume (see table above). 1. Use a clean 1 ml volumetric pipet to place 1 ml of the diluted wine into another small test tube. (Note: the wine has been diluted 100-fold with water by the stockroom manager.) Use the Pasteur pipet you saved from step 3 above to add 20 drops of H 2 SO 4 (sulfuric acid) to this test tube. Then use the other Pasteur pipet you saved to add 1 drop of chromic acid solution to the test tube. Stir the contents of the tube with a glass stirring rod. Place the tube in the hot water bath at 80 o C for 5 minutes. 2. Compare the wine sample test tube to the 11 standards and determine which one it best matches. Record this on the report sheet. Then calculate the concentration of ethanol in the wine by following the steps on the report sheet. 3. Discard the contents of all small test tubes (which contain chromium, a heavy metal) in the waste bottle provided by the instructor. Discard the contents of the large test tubes (which contain only water and ethanol) down the drain.

6 Breathalyzer Reaction Report Sheet Name A. Colors of Ethanol Standards Describe the pattern of color you observe in moving from tube #1 (no ethanol) to tube #11 (highest % of ethanol). (Here is an example to guide you: Tube #1 is colorless, and tubes #2-11 are blue the blue color is very pale in tube #2 but becomes increasingly darker in progressing from tube #2 to tube #11.) B. Ethanol Content of the Wine Sample 1. The diluted wine sample best matches the color of test tube #. 2. % ethanol by mass-volume in diluted wine sample: (Based on color comparison; see table on p. 5. % % ethanol by mass-volume means the number of grams of ethanol in 100 ml of wine. See p. 5 for an example.) 3. % ethanol by mass-volume in undiluted wine: (#2 X 100 since the wine was diluted 100-fold % by the stockroom manager) 4. % ethanol by volume in undiluted wine: (#3 0.789) % (% ethanol by volume means the number of mls of ethanol in 100 ml of wine.) 5. Proof of the undiluted wine: (#4 X 2) % ( Proof means twice the % alcohol by volume. Therefore, 100% ethanol would be 200 proof.)

7 Breathalyzer Reaction Postlab NAME 1. In the last calculation on the report sheet you determined the proof of the wine. What does proof mean with respect to alcoholic beverages? A beverage that is 180 proof contains % alcohol by volume. Does the proof you calculated agree with the usual proof range for wine of 16-30? 2. In all the alcohol solutions you prepared today, there was an excess of dichromate (in other words, there was more dichromate than ethanol). Therefore, there was dichromate left over after the reaction. Assume you have two alcohol solutions, described below, and you add dichromate to each of them. Solution 1 has twice as much ethanol as dichromate. Solution 2 has three times as much ethanol as dichromate. What color do you expect solution 1 to turn after heating it in a water bath? What color do you expect solution 2 to turn after heating it in a water bath? If the labels came off so that you didn t know which tube contained solution 1 and which contained solution 2, would you be able to tell them apart by their colors? YES or NO Explain your answer. 3. Imagine that you have a wine sample containing 14% ethanol by volume. After adding excess dichromate and heating the sample, it turns a yellowish color. Suppose that you prepare a sample of a different wine which also contains 14% ethanol by volume. However, this wine contains another compound (besides the ethanol) that is able to react with the dichromate ion and convert it to Cr 3+. After heating this sample, what do you expect to observe? Check the correct answer: It will be more orange than the first sample, appearing to have less ethanol than the first sample (less than 14%). It will be the same yellowish color as the first sample, appearing to have the same amount of ethanol as the first sample (exactly 14%) It will be more greenish-yellow than the first sample, appearing to have more ethanol than the first sample (more than 14%). EXPLAIN below why you chose the answer you did.

2026 © DocPlayer.net Privacy Policy | Terms of Service | Feedback  | Do Not Sell My Personal Information