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Homework answers / question archive / Experiment 6 Determination of the Equilibrium Constant for Bromocresol Green   Reading assignment:  Chang, Chemistry 10th edition, Chapter 15:  Acids and Bases, sections 1-5

Experiment 6 Determination of the Equilibrium Constant for Bromocresol Green   Reading assignment:  Chang, Chemistry 10th edition, Chapter 15:  Acids and Bases, sections 1-5

Chemistry

Experiment 6

Determination of the Equilibrium Constant for Bromocresol Green

 

Reading assignment:  Chang, Chemistry 10th edition, Chapter 15:  Acids and Bases, sections 1-5.

 

Goals

To determine the acid dissociation constant (Ka) for bromocresol green (BCG), an acid-base indicator.

 

Discussion Acid-base indicators are often used to demonstrate the end-point of an acid-base reaction.  Examples include phenolphthalein and the mixture of indicators used in universal indicator solution.  Acid-base indicators are weak acids that dissociate into a hydronium ion (H3O+) and a conjugate base anion (In).   This dissociation can be represented through the following equation and equilibrium expression:

HIn (aq)  +  H2O (l)   ?  H3 O+ (aq)  +  In- (aq)        Ka= [H3 O+ ][In- ] weakacid hydronium conjugatebase [ HIn ] indicator                  ion indicator

In order for a compound to be a useful indicator, the acidic form (HIn) and the basic form (In) of the indicator should differ in color.  Since equilibrium in acidic solution favors the formation of HIn, this species is called the acidic form of the indicator.  Likewise, the In form is called the basic form since it is favored in basic solutions.  An equilibrium mixture of the indicator will be colored according to the relative concentration of each form of the indicator.  The position of the equilibrium and, therefore, the relative concentration of the two forms of the indicator will depend on the H3O+ concentration, [H3O+] or in shorthand notation [H+].

The absorption curve of an indicator at different pH values can be studied to determine the equilibrium constant of the indicator.  In this experiment, we will determine the equilibrium constant of bromocresol green (BCG).  BCG is an indicator that is yellow in acidic solutions blue in basic solutions.  When dissolved in water the conjugate pair (acidic and basic forms) display different absorption spectra since they possess

 

Department of Physical Sciences Kingsborough Community College The City University of New York Spring 2012

Experiment 5:  Determination of the Equilibrium Constant for Bromocresol Green

                        1

 

 

For simplicity we'll use the following symbols to represent bromocresol green:

 

H2B      The protonated form of the indicator

HB      The deprotonated form of the indicator

NaHB The sodium salt of the deprotonated form of the indicator

B2–       The fully deprotonated form of the indicator

 

The sodium salt of bromocresol green ionizes completely in water:

NaHB (aq)      Na+ (aq)  +  HB(aq)

 

The HBform, which is a monoprotic acid, then partially dissociates to give B–2: HB(aq)  +  H2O (l)  ?  H3O+ (aq)   +  B2– (aq) 

Writing the dissociation without water (shorthand notation), we have

HB– (aq) ? H+(aq) + B2-(aq)        K=

 

 

acidicform(yellow)       basicform(blue)

HB is the acidic form and is yellow in solution.  B2– is the basic form and is blue in solution.  

Taking logarithms of the above equation gives

logK=log [H+   ]+log

 

 

 

where we have rearranged and noted that pH = –log [H+].

This is a linear equation.  A plot of log

 versus pH should yield a straight line with a slope of 1 (m

 

= 1) and an intercept equal to log K, where K is a concentration equilibrium constant.  So our strategy will be to measure the ratio log

 as a function of pH and use this data to determine the equilibrium constant for the dissociation of bromocresol green.

 

 

 

Absorbance and Spectrophotometry

Solutions that possess colors absorb visible light energy of specific wavelengths.  Recall that a red solution appears red because it absorbs much of the blue-green part of the spectrum (complementary colors).  Measurements of the amount of light absorbed by a substance at each wavelength (color) can be graphed giving an “absorption curve.”  The shape of this curve depends almost entirely on the electronic structure of the substance and is almost unique for each substance.  Thus the curve serves as an aid to identification and, with the aid of modern theory, a clue to the structure of a substance.

At a given wavelength the amount of light absorbed by a solute is proportional to its molar concentration, thus providing a widely used method of concentration analysis.  The Beer-Lambert Law states that A = εlc, where A = absorbance, ε  = a constant characteristic of the absorbing molecule, l = path length, c = concentration.  In our case, ε and l are each constant (known absorbing substance and a path length determined by the width of the cuvette).  Thus the absorbance is proportional to the concentration in this experiment.

A spectrophotometer is an instrument used for measuring the amount of absorption at different wavelengths.  Many such instruments are now commercially available.  Some are designed to operate in the region of visible light, some in infra-red regions, some in ultra-violet and still others in several of these energy bands.  You will use either a Spectronic 301 Spectrophotometer or a Genesys 20

Spectrophotometer to measured absorbance in this experiment.  Both instruments are designed for use in the visible portion of the spectrum (400 to 700 nanometers, nm).  

Determining the Equilibrium Constant

If the acidic form (HB) and basic form (B2–) of an indicator both absorb light, then the ratio

 

 

can be determined by measuring the absorption of light at the wavelength at which one of the forms absorbs a lot and the other form absorbs a little.

Plots of the absorption of light of various wavelengths (λ) versus wavelength for bromocresol green in its basic form and in its acidic form are shown in the chart to the right.  Such graphs are called absorption spectra. 

 

The graph shows that the basic form has maximum absorption (AII) at λmax.  The absorbance of the acidic form (AI) is small at λmax (almost zero). 

If we start with a solution of the pure basic form (B2–) and add an acid to the solution (for example, acetic acid), then some of the basic form will be converted to the acid form (HB).  Then the absorbance at λmax will drop because the acidic form absorbs almost no light at λmax.  This change may be visible in that the solution will change from blue to yellow.

of Physical Sciences Kingsborough Community College The City University of New York

Experiment 6:  Determination of the Equilibrium Constant for Bromocresol Green

3

We will call an absorbance measurement with a mixture of the acidic and basic forms of the indicator Ax.  In fact, all absorbance values along the vertical line drawn at λmax in the graph are Ax values.  These points all lie between AII and AI.

Referring back to the equation, log

=pH+logK , we see that in order to calculate the equilibrium

 

constant, K, different ratios of

 must be found for different pH values.  When these are plotted, a straight line with slope of one and y-intercept of log K is obtained.  The relationship between the absorbance data at λmax and the ratio
 is found from the following equation:

 

[B2--]]= AAIIx- -A Ax I  where

[HB

AI  = absorbance of the solution when all indicator is in the acidic form (pure HIn).

AII = absorbance of the solution when all indicator is in the basic form (pure In).

Ax  = absorbance of the solution when both some acidic and some basic form are present

 

Procedure

Equipment:   UV-vis spectrophotometer, two cuvettes, pipette pump, three 250-mL beakers, 100-mL graduated cylinder, 2-mL pipet, 10-mL graduated cylinder, Kimwipes, USB flash drive.  Chemicals: 1.00 M acetic acid (HAc), 3.00 x 10-4 M bromocresol green (BCG), 0.200 M sodium acetate (NaAc), cuvette containing acidic form of BCG obtained from your instructor.

Use eye protection for this experiment.

Students will work in groups as assigned by the instructor.  

Part 1:  Absorbance Spectrum of Bromocresol Green in Basic and Acidic Solutions

1.  We will need four solutions to perform this experiment.  The instructions for making the first three are given in the text below.  The fourth solution has already been prepared and will be distributed by your instructor in a cuvette.  All solutions should be prepared in a graduated cylinder since volume markings on beakers are good to only 5%.

  1. Bromocresol green in sodium acetate solution:  Add 5.00 ml of 3 x 10–4 M bromocresol green solution and 5.00 mL of 0.200 M sodium acetate (NaAc) solution to a 100-mL graduated cylinder.  Dilute to 100.0 mL with deionized water and pour quantitatively (this means all of the solution) into a clean, dry 250-mL beaker.  This solution should be blue and will be referred to as the basic solution.  The sodium acetate concentration in this solution is 0.0100 M.
  2. Acetic acid solution:  Rinse the graduated cylinder with distilled water, add 25.0 mL of the 1.00 M acetic acid (HAc) solution and dilute to 100.0 mL with deionized water.  Pour this solution quantitatively into a clean, dry 250-mL beaker.  The concentration of the acetic acid in this solution is 0.250 M.
  3. Blank Solution:  Add 5 mL of 1.00 M acetic acid and 5 mL of 0.200 M sodium acetate to a 100 mL graduated cylinder and dilute with deionize water to 100 mL.
  4. Bromocresol green solution in hydrochloric acid:  The instructor will supply a cuvette containing a BCG solution that has excess acid (HCl) added to it.  This solution should be yellow.

A Note About Measuring Absorbance Using the Spectrophotometer and Use of the Blank Solution.  Spectrophotometry measurements generally require that the absorbance of a blank solution be measured in order to counteract any absorbance or scattering of light from air, the container, solvents, and solutes.  Once a “blank” has been performed, the instrument compares these signal losses from measurements of the signal coming from the sample.  So a “blank” should always be performed prior to making a measurement at a particular wavelength.  Likewise, when the wavelength setting of a spectrophotometer is changed (for example, from 400 nm to 420 nm) the amount of light reaching the detector can change.  For that reason, it is necessary to perform a blank measurement again.  If the wavelength setting isn’t changed then a blank measurement isn’t usually needed.  However, optical and electronic properties of the spectrophotometer can “drift” over time.  So if the instrument has been sitting for more than a few minutes, it’s a good idea to re-perform a blank, even if the wavelength hasn’t been changed.  When in doubt, re-perform a blank measurement.

  1. Measure the absorption spectrum of the solution containing BCG in sodium acetate (basic BCG solution) and the BCG solution containing HCl (acidic BCG solution) beginning at 380 nm and ending at 680 nm at 20 nm intervals.  Record these measurements in the Data Sheet.

of Physical Sciences Kingsborough Community College The City University of New York Experiment 5:  Determination of the Equilibrium Constant for Bromocresol Green

 

  1. Review the absorbance data and locate the greatest value of the absorbance for the basic solution.  Note what wavelength this absorbance corresponds to.  Now measure the absorbance of the basic BCG solution and the acidic BCG solution at 5 nm intervals from 20 nm below to 20 nm above this wavelength.  For example, if the wavelength of maximum absorbance occurs at 520 nm, make measurements at 5 nm intervals from 500 nm to 540 nm.  However, don’t duplicate readings—in this case don’t take readings at 500 nm, 520 nm, and 540 nm.  
  2. Pour the BCG in sodium acetate solution in the cuvette back into the 250-mL beaker, taking care not to lose any of the solution. 
  3. Return the cuvette containing the acidic form of BCG to your instructor.
  4. From the data taken for the basic and acidic forms, decide which wavelength is suitable for measuring Ax values and set the spectrophotometer at this wavelength.  The suitable wavelength, λmax, is the wavelength in which the basic form has a maximum absorbance and the acidic form has a very small absorbance. 

Part 2:  Effect of pH on Absorbance of Bromocresol Green

  1. Add precisely 2.00 mL of the 0.250 M acetic acid solution to the 250-mL beaker of BCG solution using a 2 mL pipet and a pipette pump.  Mix the solution with a glass stirring rod and measure the absorbance at λmax.  Pour the solution in the cuvette back into the 250-mL beaker.  Don’t throw the solution in the cuvette out.
  2. Add another 00 mL of the 0.250 M acetic acid solution, mix well, and measure the absorbance at λmax.  Again, pour the solution in the cuvette back into the beaker.  

 

  1. Repeat this procedure with a third and fourth 2.00 mL increment of the 0.250 M acetic acid solution.  There should now be a total of 8.00 mL of 0.250 M acetic acid solution added to the BCG solution.

 

  1. Rinse all solutions down the drain and clean any glassware used in the experiment before performing any calculations.

 

 

Data Sheet                                           

 

Absorbance Data at 5 nm Intervals

Wavelength (nm)

Absorbance

(basic form)

Absorbance

(acidic

form)

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Name                                                                          Partner                                                 

            

Absorbance Data at 20 nm Intervals

wavelength (nm)

Absorbance (basic form)

Absorbance

(acidic

form)

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Partner                                                            

 

 

 

    

    

 

Volume of Acetic Acid Solution Added (mL)

Absorbance AX

2.00

 

4.00

 

6.00

 

8.00

 

λmax = ______________ nm.    This is the wavelength having the largest absorbance of all the data you took for the basic form in the above tables.

 

 

 

 

 

 

 

 

Calculations

We will use graphical analysis to produce an absorbance spectrum of bromocresol green in basic and acidic solutions.  Both spectra should be represented on the same chart. Vernier Graphical Analysis and Microsoft Excel are appropriate programs for this exercise.  The instructions below are for Graphical Analysis.

  1. Open Graphical Analysis on the computer.
  2. Enter the combined absorbance data for the acidic form and base formic.  Sort the data by wavelength.  Label this data column (y-axis) “basic form”and enter “absorbance” for the units.  Label the x-axis “wavelength” with units of “nm.”  
  3. To graph the acidic form absorbance values in Graphical Analysis, you will need to add a second column to the Data Table Window.  Do this by selecting New Column in the Data menu and choosing Manually Entered.  Label the acidic data “acidic form” and enter “absorbance” for the units.  

Choose different point protectors for each of the two absorbance curves.  Put a legend on the graph.  This way you will be able to distinguish the curves.

 

  1. You have now plotted two absorption spectra for bromocresol green—the blue basic form and the yellow acidic form.  Also, in addition to AI and AII, you should have a precise measurement of the absorbance (Ax) of the bromocresol green solution at four different pH values.  All these measurements have been taken at λmax, the wavelength where the absorbance of the basic form of the indicator is at a maximum and the absorbance of the acidic form is very low.  The next three pages can be used to perform the series of calculations required to find Ka for bromocresol green.  

Name                                                                          Partner                                                 

            

 Partner                                                           

 

 

1.  Finding the number of moles of sodium acetate (NaC2H3O2) in solution A

 

Molarity of sodium acetate solution on bottle                                                                            

            

Volume of sodium acetate solution used in dilution in milliliters       

 

Volume of sodium acetate solution used in dilution in liters (1000 mL =  1L)     

 

Moles of sodium acetate solution used in dilution (n = MV)       

 

 

2.  Finding the molarity of acetic acid (HC2H3O2) in solution B

 

Molarity of acetic acid solution on bottle         

 

Volume of acetic acid solution used in dilution in milliliters                                                      

 

Volume of acetic acid solution used in dilution in liters                                                             

 

Moles of acetic acid solution used in dilution (n = MV)                                                            

 

Total volume of solution in dilution in milliliters                                                                       

 

Total volume of solution in dilution in liters (1000 mL =  1 L)                                                   

 

Molarity of acetic acid in diluted solution (M = n/V)                                                                 

 

 

1.  Moles of Acetic Acid

Now we need to calculate the number of moles of acetic acid each time we added 2.00 mL of acetic acid solution to the bromocresol green solution in Part 2.  The volume of acetic acid solution added was 2.00 mL through 8.00 mL.  Convert these volumes to liters.  The molarity of the acetic acid solution was calculated on the previous page and is the same for each addition.  The moles of acetic acid added can be found from n = MV.

 

Volume of

Acetic Acid

Solution Added (mL)

Volume of

Acetic Acid

Solution

Added

(L)

Molarity of

Acetic Acid

Solution

(mol/L)*

M = n/V

Moles of

Acetic Acid

Added

(mol)

2.00 mL

 

 

 

4.00 mL

 

 

 

6.00 mL

 

 

 

8.00 mL

 

 

 

*From the previous page.  This amount should be the same for each addition.

 

2.  Moles of Sodium Acetate (NaAc)

We also need to know the number of moles of sodium acetate used in the mixture for Part 2.  This was calculated on the previous page.  

 

3:  Calculating the pH of the acetate solutions

The following table shows the progression of the calculations needed to find the pH of each solution in Part 2.  We first use the moles of the acetic acid and the moles of sodium acetate (already calculated) to find the ratio of sodium acetate to acetic acid.  We then take the log (base 10) of this ratio.  The pH of a solution that contains a weak acid and its conjugate base is:  pH = pKa + log???   molNaAcmolHAc ??? .  The pKa for

acetic acid is 4.74. Find the pH of each solution.

  

Volume of

Acetic

Acid

Solution

Added

(mL)

Moles of

Acetic Acid* 

(mol)

 

Moles of

Sodium 

Acetate* 

(mol)

 

moles sodiumacetate molesacetic acid

log?? molNaAcmolHAc ???  

?

pKa of HAc

pH

2.00 mL

 

 

 

 

4.74

 

4.00 mL

 

 

 

 

4.74

 

6.00 mL

 

 

 

 

4.74

 

8.00 mL

 

 

 

 

4.74

 

*From 1.

 

 

 

 

 

 

4:  Equilibrium Constant K

To find the equilibrium constant (Ka) of bromocresol green we need to perform a plot of:

 

log

 versus pH where pH is the x-axis.  The following table shows the progression needed to find

 

values needed for this graph.  As a reminder (see page 3 for a more detailed discussion), AII is the absorbance of the basic form of bromocresol green at the wavelength of maximum absorbance (λmax).  This absorbance was determined in Part 1 of the experiment and is a constant.  AI is the absorbance of the acidic form of bromocresol green at the wavelength of maximum absorbance (λmax).  This absorbance was also determined in Part 1 of the experiment and is also a constant.  AX is the absorbance of the bromocresol green solution after 2.00 mL additions of acetic acid solutions were made.   With each addition of  acetic acid solution, the bromocresol green became slightly more dilute, causing its absorbance to decrease.  To compensate for this dilution use the following equation to correct for the dilution.  Enter the values of these corrections in the column “Corrected AX.”

Corrected Absorbance =AX ??100100mL+VmLadded ??? .  Note that, unlike AII and AI, Corrected AX varies.  To

 

?

complete the table, take the difference between Corrected AX and AI (Ax – AI), the difference between AII and AX (AII – Ax), and then take the ratio of these differences.  The log of this ratio is equal to log

.  Re-enter the pH values from Step 3 in the calculations.  Once you have completed the table you can construct the graph of log

 versus pH and find Ka.

 

 

            

AII

AI

Corrected Ax

Ax - A I

AII-Ax

 

log Ax -AI = log [B2--]]

AII-Ax   [HB

pH

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Report

  1. Hand in your original data tables, calculation tables, graphs, calculations and results.

 

  1. Clearly indicate in your report the value of the equilibrium constant of BCG, Ka, and how you calculated it.  Ka can be found from the yintercept (B):

 

B = log (Ka)

Ka = 10B

 

  1. When we calculate the pH of the solutions it’s found by using the following equation: pH=pK+log (molessodiumacetate )

( molesaceticacid ) Bromocresol green is a weak acid, just like acetic acid.  But our calculations assume that

bromocresol green doesn’t affect the overall acidity (pH) of the acetate solution.  Why is this a good assumption?  To prove this point, calculate the number of moles of bromocresol green (the indicator itself) in the sodium acetate solution and compare this number to the number of moles of sodium acetate and the number of moles of acetic acid used.  

 

  1. Type a discussion of your primary result.  Compare your result to literature values.  Discuss the accuracy of your result.  Be sure to list the sources of your literature values.

 

 

 

 

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