OWLv2 with Student Solutions Manual eBook for Ebbing/Gammon's General Chemistry, 11th Edition, [Instant Access], 4 terms (24 months)
OWLv2 with Student Solutions Manual eBook for Ebbing/Gammon's General Chemistry, 11th Edition, [Instant Access], 4 terms (24 months)
11th Edition
ISBN: 9781305864900
Author: Darrell Ebbing; Steven D. Gammon
Publisher: Cengage Learning US
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Textbook Question
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Chapter 16, Problem 16.157QP

Weak base B has a pKb of 6.78 and weak acid HA has a pKa of 5.12.

  1. a Which is the stronger base, B or A?
  2. b Which is the stronger acid, HA or BH+?
  3. c Consider the following reaction:

B ( a q ) + HA ( a q ) BH + ( a q ) + A ( a q )

Based on the information about the acid/base strengths for the species in this reaction, is this reaction favored to proceed more to the right or more to the left? Why?

  1. d An aqueous solution is made in which the concentration of weak base B is one half the concentration of its acidic salt, BHCl, where BH+ is the conjugate weak add of B. Calculate the pH of the solution.
  2. e An aqueous solution is made in which the concentration of weak acid HA twice the concentration of the sodium salt of the weak acid, NaA. Calculate the pH of the solution.
  3. f Assume the conjugate pairs B/BH+ and HA/A are capable of being used as color-based end point indicators in acid–base titrations, where B is the base form indicator and BH is the acid form indicator, and HA is the acid form indicator and A is the base form indicator. Select the indicator pair that would be best to use in each of the following titrations:
    1. (1) Titration of a strong acid with a strong base.
      1. (i) B/BH+
      2. (ii) HA/A
    2. (2) Titration of a weak base with a strong acid.
      1. (i) B/BH+
      2. (ii) HA/A

(a)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation:

A weak base B has a pKb of 6.78 and a weak acid HA has a pKa of 5.12.

The stronger base, B or A has to be found

Concept Introduction:

Strength of acid and base:

The strength of acid and base depends on the pKa and pKb value.

  • Smaller the pKa value, stronger is the acid
  • Larger the pKa value, weaker is the acid
  • Smaller the pKb value, stronger is the base
  • Larger the pKb value, weaker is the base

Henderson-Hasselbalch equation :

The pH can be calculated using Henderson-Hasselbalch equation as follows,

pH = pKa + log[conjugate base][weak acid]pH = pKa + log[A-][HA]

Equivalence point:

The equivalence point in titration is the point where the amount of standard titrant solution (in moles) and the unknown concentration analyte solution (in moles) becomes equal.

In other words, the equivalence point is the point obtained in a titration once a stoichiometric amount of reactant has been added.

Hydrolysis of salt of the weak base that is formed determines the pH of the solution at the equivalence point and it will fall in the pH region of 4 – 6.

After the equivalence point, the pH decreases to a level just greater than the pH of the strong acid titrant.

Equivalence point can be detected by the addition of indicator.

Answer to Problem 16.157QP

The stronger base is B

Explanation of Solution

To Find: The stronger base, B or A

Given data:

A weak base B has a pKb of 6.78 and a weak acid HA has a pKa of 5.12

The stronger base, B or A :

The strong or weak base can be found from the pKb value.

The given pKb value for base is 6.78

The given pKa value for acid is 5.12

The pKb value for A is calculated as follows and compared.

pKa + pKb  =14           pKb =14pKa =145.12 =8.88

The strong base will have small pKb value

The pKb value of A is greater than B

Hence, B is the stronger base

Conclusion

The stronger base was found as B

(b)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation:

A weak base B has a pKb of 6.78 and a weak acid HA has a pKa of 5.12.

The stronger acid, HA or BH+ has to be found

Concept Introduction:

Strength of acid and base:

The strength of acid and base depends on the pKa and pKb value.

  • Smaller the pKa value, stronger is the acid
  • Larger the pKa value, weaker is the acid
  • Smaller the pKb value, stronger is the base
  • Larger the pKb value, weaker is the base

Henderson-Hasselbalch equation :

The pH can be calculated using Henderson-Hasselbalch equation as follows,

pH = pKa + log[conjugate base][weak acid]pH = pKa + log[A-][HA]

Equivalence point:

The equivalence point in titration is the point where the amount of standard titrant solution (in moles) and the unknown concentration analyte solution (in moles) becomes equal.

In other words, the equivalence point is the point obtained in a titration once a stoichiometric amount of reactant has been added.

Hydrolysis of salt of the weak base that is formed determines the pH of the solution at the equivalence point and it will fall in the pH region of 4 – 6.

After the equivalence point, the pH decreases to a level just greater than the pH of the strong acid titrant.

Equivalence point can be detected by the addition of indicator.

Answer to Problem 16.157QP

The stronger acid is HA

Explanation of Solution

To Find: The stronger acid, HA or BH+

The stronger acid, HA or BH+ :

The strong or weak acid can be found from the pKa value.

The given pKb value for base is 6.78

The given pKa value for acid is 5.12

The pKa value for BH+ is calculated as follows and compared.

pKa + pKb  =14           pKa =14pKa =146.78 =7.22

The strong acid will have small pKa value

The pKa value of BH+ is greater than HA

Hence, HA is the stronger acid

Conclusion

The stronger acid was found as HA

(c)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation:

A weak base B has a pKb of 6.78 and a weak acid HA has a pKa of 5.12.

Consider the reaction B(aq) + HA(aq)BH+(aq)+A-(aq) , whether the given reaction favored to proceed more to the right or more to the left has to be explained

Concept Introduction:

Strength of acid and base:

The strength of acid and base depends on the pKa and pKb value.

  • Smaller the pKa value, stronger is the acid
  • Larger the pKa value, weaker is the acid
  • Smaller the pKb value, stronger is the base
  • Larger the pKb value, weaker is the base

Henderson-Hasselbalch equation :

The pH can be calculated using Henderson-Hasselbalch equation as follows,

pH = pKa + log[conjugate base][weak acid]pH = pKa + log[A-][HA]

Equivalence point:

The equivalence point in titration is the point where the amount of standard titrant solution (in moles) and the unknown concentration analyte solution (in moles) becomes equal.

In other words, the equivalence point is the point obtained in a titration once a stoichiometric amount of reactant has been added.

Hydrolysis of salt of the weak base that is formed determines the pH of the solution at the equivalence point and it will fall in the pH region of 4 – 6.

After the equivalence point, the pH decreases to a level just greater than the pH of the strong acid titrant.

Equivalence point can be detected by the addition of indicator.

Answer to Problem 16.157QP

The given reaction favored to proceed more to the right side

Explanation of Solution

To Explain: Whether the given reaction favored to proceed more to the right or more to the left

Given data:

Consider the reaction B(aq) + HA(aq)BH+(aq)+A-(aq)

The acid-base neutralization reaction favours the side of reaction bearing weaker base and weaker acid.

Hence, the given reaction will be favoured more to the right side

Conclusion

The given reaction favored to proceed more to the right side

 (d)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation:

A weak base B has a pKb of 6.78 and a weak acid HA has a pKa of 5.12.

The pH of the aqueous solution in which the concentration of weak base B is one half the concentration on its acidic salt, BHCl has to be calculated

Concept Introduction:

Strength of acid and base:

The strength of acid and base depends on the pKa and pKb value.

  • Smaller the pKa value, stronger is the acid
  • Larger the pKa value, weaker is the acid
  • Smaller the pKb value, stronger is the base
  • Larger the pKb value, weaker is the base

Henderson-Hasselbalch equation :

The pH can be calculated using Henderson-Hasselbalch equation as follows,

pH = pKa + log[conjugate base][weak acid]pH = pKa + log[A-][HA]

Equivalence point:

The equivalence point in titration is the point where the amount of standard titrant solution (in moles) and the unknown concentration analyte solution (in moles) becomes equal.

In other words, the equivalence point is the point obtained in a titration once a stoichiometric amount of reactant has been added.

Hydrolysis of salt of the weak base that is formed determines the pH of the solution at the equivalence point and it will fall in the pH region of 4 – 6.

After the equivalence point, the pH decreases to a level just greater than the pH of the strong acid titrant.

Equivalence point can be detected by the addition of indicator.

Answer to Problem 16.157QP

The pH of the aqueous solution in which the concentration of weak base B is one half the concentration on its acidic salt, BHCl was calculated is 6.92

Explanation of Solution

To Calculate: The pH of the aqueous solution in which the concentration of weak base B is one half the concentration on its acidic salt, BHCl

Given data:

An aqueous solution is prepared in which the concentration of the weak base B is one half the concentration on its acidic salt, BHCl

pH calculation:

BHCl salt contains BH+ and Cl ions.

The prepared solution is a buffer solution composing the weak base B and its conjugate acid BH+

Using Henderson-Hasselbalch equation, the pH can be calculated as follows,

pH = pKa+ log[base][acid]

The pKa value for BH+ is 7.22

On considering the concentration of BHCl as x M, then the concentration of base B will be 0.5x M. Thus,

pH  = 7.22+ log(0.5x)x =7.22+ log(0.50) =6.92

Therefore, the pH of the given solution is 6.92

Conclusion

The pH of the aqueous solution in which the concentration of weak base B is one half the concentration on its acidic salt, BHCl was calculated as 6.92

(e)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation:

A weak base B has a pKb of 6.78 and a weak acid HA has a pKa of 5.12.

The pH of the aqueous solution in which the concentration of weak acid HA is twice the concentration of the sodium salt of the weak acid, NaA has to be calculated.

Concept Introduction:

Strength of acid and base:

The strength of acid and base depends on the pKa and pKb value.

  • Smaller the pKa value, stronger is the acid
  • Larger the pKa value, weaker is the acid
  • Smaller the pKb value, stronger is the base
  • Larger the pKb value, weaker is the base

Henderson-Hasselbalch equation :

The pH can be calculated using Henderson-Hasselbalch equation as follows,

pH = pKa + log[conjugate base][weak acid]pH = pKa + log[A-][HA]

Equivalence point:

The equivalence point in titration is the point where the amount of standard titrant solution (in moles) and the unknown concentration analyte solution (in moles) becomes equal.

In other words, the equivalence point is the point obtained in a titration once a stoichiometric amount of reactant has been added.

Hydrolysis of salt of the weak base that is formed determines the pH of the solution at the equivalence point and it will fall in the pH region of 4 – 6.

After the equivalence point, the pH decreases to a level just greater than the pH of the strong acid titrant.

Equivalence point can be detected by the addition of indicator.

Answer to Problem 16.157QP

The pH of the aqueous solution in which the concentration of weak acid HA is twice the concentration of the sodium salt of the weak acid, NaA is4.82

Explanation of Solution

To Calculate: The pH of the aqueous solution in which the concentration of weak acid HA is twice the concentration of the sodium salt of the weak acid, NaA

Given data:

An aqueous solution is prepared in which the concentration of the weak acid HA is twice the concentration of the sodium salt of the weak acid, NaA

pH calculation:

NaA salt contains Na+ and A ions.

The prepared solution is a buffer solution composing the weak acid HA and its conjugate base A

Using Henderson-Hasselbalch equation, the pH can be calculated as follows,

pH = pKa+ log[base][acid]

The pKa value for A is 5.12

On considering the concentration of HA as x M, then the concentration of base A will be 0.5x M. Thus,

pH  = 5.12+ log(0.5x)x =5.12+ log(0.50) =4.82

Therefore, the pH of the given solution is 4.82

Conclusion

The pH of the aqueous solution in which the concentration of weak acid HA is twice the concentration of the sodium salt of the weak acid, NaA was calculated as 4.82

(f)

Expert Solution
Check Mark
Interpretation Introduction

Interpretation:

A weak base B has a pKb of 6.78 and a weak acid HA has a pKa of 5.12.

The conjugate pairs that can be used as a best indicator for the given titrations has to be selected.

  1. (1) Titration of strong acid with a strong base
  2. (2) Titration of weak base with a strong acid

Concept Introduction:

Strength of acid and base:

The strength of acid and base depends on the pKa and pKb value.

  • Smaller the pKa value, stronger is the acid
  • Larger the pKa value, weaker is the acid
  • Smaller the pKb value, stronger is the base
  • Larger the pKb value, weaker is the base

Henderson-Hasselbalch equation :

The pH can be calculated using Henderson-Hasselbalch equation as follows,

pH = pKa + log[conjugate base][weak acid]pH = pKa + log[A-][HA]

Equivalence point:

The equivalence point in titration is the point where the amount of standard titrant solution (in moles) and the unknown concentration analyte solution (in moles) becomes equal.

In other words, the equivalence point is the point obtained in a titration once a stoichiometric amount of reactant has been added.

Hydrolysis of salt of the weak base that is formed determines the pH of the solution at the equivalence point and it will fall in the pH region of 4 – 6.

After the equivalence point, the pH decreases to a level just greater than the pH of the strong acid titrant.

Equivalence point can be detected by the addition of indicator.

Answer to Problem 16.157QP

The conjugate pairs that can be used as a best indicator for,

  1. (1) The titration of strong acid with a strong base is B/BH+
  2. (2) The titration of weak base with a strong acid is HA/A

Explanation of Solution

To Select: Among the conjugate pairs (i) B/BH+ or (ii) HA/A that can be used as a best indicator for the titration of strong acid with a strong base

The indicator for an acid-base titration is depends on the pKa value which overlaps with the pH of the equivalence point.

Since a strong acid-strong base titration gives a neutral solution at the point of equivalence, the choice of indicator must have pKa value close to 7.

Among the given conjugate pairs,  B/BH+ and HA/A ,

The pKa for is BH+ 7.22

The pKa of HA is 5.12

Therefore,  B/BH+ indicator would be the appropriate indicator for the titration of strong acid with a strong base.

To Select: Among the conjugate pairs (i) B/BH+ or (ii) HA/A that can be used as a best indicator for the titration of weak base with a strong acid

The indicator for an acid-base titration is depends on the pKa value which overlaps with the pH of the equivalence point.

Since a weak base-strong acid titration gives a solution of the conjugate acid of the weak base at the point of equivalence, the choice of indicator must have pKa less than 7.

Among the given conjugate pairs,  B/BH+ and HA/A ,

The pKa for is BH+ 7.22

The pKa of HA is 5.12

Therefore, HA/A indicator would be the appropriate indicator for the titration of weak base with a strong acid

Conclusion

The conjugate pairs that can be used as a best indicator for,

  1. (1) The titration of strong acid with a strong base was found as B/BH+
  2. (2) The titration of weak base with a strong acid was found as HA/A

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Chapter 16 Solutions

OWLv2 with Student Solutions Manual eBook for Ebbing/Gammon's General Chemistry, 11th Edition, [Instant Access], 4 terms (24 months)

Ch. 16.4 - Benzoic acid, HC7H5O2, and its salts are used as...Ch. 16.4 - Which of the following aqueous solutions has the...Ch. 16.5 - The chemical equation for the hydrolysis of...Ch. 16.5 - What is the concentration of formate ion, CHO2, in...Ch. 16.5 - One liter of solution was prepared by dissolving...Ch. 16.6 - What is the pH of a buffer prepared by adding 30.0...Ch. 16.6 - Suppose you add 50.0 mL of 0.10 M sodium hydroxide...Ch. 16.6 - Prob. 16.5CCCh. 16.6 - The beaker on the left below represents a buffer...Ch. 16.7 - What is the pH of a solution in which 15 mL of...Ch. 16.7 - What is the pH at the equivalence point when 25 mL...Ch. 16.7 - Prob. 16.16ECh. 16 - Write an equation for the ionization of hydrogen...Ch. 16 - Prob. 16.2QPCh. 16 - Briefly describe two methods for determining Ka...Ch. 16 - Describe how the degree of ionization of a weak...Ch. 16 - Prob. 16.5QPCh. 16 - Phosphorous acid, H2PHO3, is a diprotic acid....Ch. 16 - Prob. 16.7QPCh. 16 - Write the equation for the ionization of aniline,...Ch. 16 - Which of the following is the strongest base: NH3,...Ch. 16 - Do you expect a solution of anilinium chloride...Ch. 16 - Prob. 16.11QPCh. 16 - The pH of 0.10 M CH3NH2 (methylamine) is 11.8....Ch. 16 - Define the term buffer. Give an example.Ch. 16 - What is meant by the capacity of a buffer?...Ch. 16 - Prob. 16.15QPCh. 16 - If the pH is 8.0 at the equivalence point for the...Ch. 16 - Which of the following salts would produce the...Ch. 16 - If you mix 0.10 mol of NH3 and 0.10 mol of HCl in...Ch. 16 - Hydrogen sulfide, H2S, is a very weak diprotic...Ch. 16 - If 20.0 mL of a 0.10 M NaOH solution is added to a...Ch. 16 - Aqueous Solutions of Acids, Bases, and Salts a For...Ch. 16 - The pH of Mixtures of Acid, Base, and Salt...Ch. 16 - Which of the following beakers best represents a...Ch. 16 - You have 0.10-mol samples of three acids...Ch. 16 - Prob. 16.25QPCh. 16 - You have the following solutions, all of the same...Ch. 16 - Prob. 16.27QPCh. 16 - A chemist prepares dilute solutions of equal molar...Ch. 16 - Prob. 16.29QPCh. 16 - Prob. 16.30QPCh. 16 - You are given the following acidbase titration...Ch. 16 - The three flasks shown below depict the titration...Ch. 16 - Write chemical equations for the acid ionizations...Ch. 16 - Write chemical equations for the acid ionizations...Ch. 16 - Acrylic acid, whose formula is HC3H3O2 or...Ch. 16 - Heavy metal azides, which are salts of hydrazoic...Ch. 16 - Boric acid, B(OH)3, is used as a mild antiseptic....Ch. 16 - Formic acid, HCHO2, is used to make methyl formate...Ch. 16 - C6H4NH2COOH, para-aminobenzoic acid (PABA), is...Ch. 16 - Barbituric acid. HC4H3N2O3, is used to prepare...Ch. 16 - A solution of acetic acid, HC2H3O2, on a...Ch. 16 - A chemist wanted to determine the concentration of...Ch. 16 - Hydrofluoric acid, HF, unlike hydrochloric acid,...Ch. 16 - Chloroacetic acid, HC2H2ClO2, has a greater acid...Ch. 16 - What is the hydronium-ion concentration of a 2.00...Ch. 16 - What is the hydronium-ion concentration of a 3.00 ...Ch. 16 - Phthalic acid, H2C8H4O4, is a diprotic acid used...Ch. 16 - Carbonic acid, H2CO3, can be found in a wide...Ch. 16 - Write the chemical equation for the base...Ch. 16 - Write the chemical equation for the base...Ch. 16 - Butylamine, C4H3NH2 is a weak base. A 0.47 M...Ch. 16 - Trimethylamine, (CH3)3N, is a gas with a fishy,...Ch. 16 - What is the concentration of hydroxide ion in a...Ch. 16 - What is the concentration of hydroxide ion in a...Ch. 16 - Note whether hydrolysis occurs for each of the...Ch. 16 - Note whether hydrolysis occurs for each of the...Ch. 16 - Prob. 16.57QPCh. 16 - Prob. 16.58QPCh. 16 - For each of the following salts, indicate whether...Ch. 16 - Note whether the aqueous solution of each of the...Ch. 16 - Decide whether solutions of the following salts...Ch. 16 - Decide whether solutions of the following salts...Ch. 16 - Obtain a the Kb value for NO2; b the Ka value for...Ch. 16 - Prob. 16.64QPCh. 16 - What is the pH of a 0.025 M aqueous solution of...Ch. 16 - Calculate the OH concentration and pH of a 0.0025...Ch. 16 - Calculate the concentration of pyridine, C5H5N, in...Ch. 16 - What is the pH of a 0.30 M solution of...Ch. 16 - Calculate the degree of ionization of a 0.75 M HF...Ch. 16 - Calculate the degree of ionization of a 0.22 M...Ch. 16 - What is the pH of a solution that is 0.600 M HCHO2...Ch. 16 - What is the pH of a solution that is 0.20 M KOCN...Ch. 16 - What is the pH of a solution that is 0.10 M CH3NH2...Ch. 16 - What is the pH of a solution that is 0.15 M...Ch. 16 - A buffer is prepared by adding 39.8 mL of 0.75 M...Ch. 16 - A buffer is prepared by adding 115 mL of 0.30 M...Ch. 16 - What is the pH of a buffer solution that is 0.10 M...Ch. 16 - A buffer is prepared by mixing 525 mL of 0.50 M...Ch. 16 - What is the pH of a buffer solution that is 0.15 M...Ch. 16 - What is the pH of a buffer solution that is 0.10 M...Ch. 16 - What is the pH of a buffer solution that is 0.15 M...Ch. 16 - What is the pH of a buffer solution that is 0.15 M...Ch. 16 - How many moles of sodium acetate must be added to...Ch. 16 - How many moles of hydrofluoric acid, HF, must be...Ch. 16 - What is the pH of a solution in which 15 mL of...Ch. 16 - What is the pH of a solution in which 35 mL of...Ch. 16 - A 1.24-g sample of benzoic acid was dissolved in...Ch. 16 - A 0.400-g sample of propionic acid was dissolved...Ch. 16 - Find the pH of the solution obtained when 32 mL of...Ch. 16 - What is the pH at the equivalence point when 22 mL...Ch. 16 - A 50.0-mL sample of a 0.100 M solution of NaCN is...Ch. 16 - Sodium benzoate, NaC7H5O2, is used as a...Ch. 16 - Calculate the pH of a solution obtained by mixing...Ch. 16 - Calculate the pH of a solution obtained by mixing...Ch. 16 - Salicylic acid, C6H4OHCOOH, is used in the...Ch. 16 - Cyanoacetic acid, CH2CNCOOH, is used in the...Ch. 16 - A 0.050 M aqueous solution of sodium hydrogen...Ch. 16 - A 0.10 M aqueous solution of sodium dihydrogen...Ch. 16 - Prob. 16.99QPCh. 16 - Calculate the base-ionization constants for PO43...Ch. 16 - Calculate the pH of a 0.072 M aqueous solution of...Ch. 16 - Calculate the pH of a 0.10 M aqueous solution of...Ch. 16 - An artificial fruit beverage contains 11.0 g of...Ch. 16 - A buffer is made by dissolving 12.5 g of sodium...Ch. 16 - Blood contains several acid base systems that tend...Ch. 16 - Codeine, C23H21NO3, is an alkaloid (Kb = 6 2 109)...Ch. 16 - Calculate the pH of a solution obtained by mixing...Ch. 16 - Calculate the pH of a solution made up from 2.0 g...Ch. 16 - Find the pH of the solution obtained when 25 mL of...Ch. 16 - What is the pH of the solution obtained by...Ch. 16 - Ionization of the first proton from H2SO4 is...Ch. 16 - Ionization of the first proton from H2SeO4 is...Ch. 16 - Methylammonium chloride is a salt of methylamine,...Ch. 16 - Sodium benzoate is a salt of benzoic acid,...Ch. 16 - Each of the following statements concerns a 0.010...Ch. 16 - Each of the following statements concerns a 0.10 M...Ch. 16 - A 0.288-g sample of an unknown monoprotic organic...Ch. 16 - A 0.239-g sample of unknown organic base is...Ch. 16 - a Draw a pH titration curve that represents the...Ch. 16 - a Draw a pH titration curve that represents the...Ch. 16 - The equilibrium equations and Ka values for three...Ch. 16 - Prob. 16.122QPCh. 16 - A 25.0-mL sample of hydroxylamine is titrated to...Ch. 16 - A 25.00-mL sample contains 0.562 g of NaHCO3. This...Ch. 16 - A solution made up of 1.0 M NH3 and 0.50 M...Ch. 16 - A solution is prepared from 0.150 mol of formic...Ch. 16 - An important component of blood is the buffer...Ch. 16 - An important component of blood is the buffer...Ch. 16 - Tartaric acid is a weak diprotic fruit acid with...Ch. 16 - Malic acid is a weak diprotic organic acid with...Ch. 16 - A quantity of 0.25 M sodium hydroxide is added to...Ch. 16 - A quantity of 0.15 M hydrochloric acid is added to...Ch. 16 - Prob. 16.133QPCh. 16 - Prob. 16.134QPCh. 16 - A 30.0-mL sample of 0.05 M HClO is titrated by a...Ch. 16 - Prob. 16.136QPCh. 16 - Prob. 16.137QPCh. 16 - Calculate the pH of a solution made by mixing 0.62...Ch. 16 - Cyanic acid, HOCN, is a weak acid with a Ka value...Ch. 16 - The Kb for NH3 is 1.8 105 at 25C. Calculate the...Ch. 16 - Ka for formic acid is 1.7 104 at 25C. A buffer is...Ch. 16 - K4 for acetic acid is 1.7 105 at 25C. A buffer...Ch. 16 - Prob. 16.143QPCh. 16 - Prob. 16.144QPCh. 16 - Prob. 16.145QPCh. 16 - Two samples of 1.00 M HCl of equivalent volumes...Ch. 16 - Prob. 16.147QPCh. 16 - Prob. 16.148QPCh. 16 - A solution of weak base is titrated to the...Ch. 16 - A buffer solution is prepared by mixing equal...Ch. 16 - The pH of a white vinegar solution is 2.45. This...Ch. 16 - The pH of a household cleaning solution is 11.50....Ch. 16 - What is the freezing point of 0.92 M aqueous...Ch. 16 - Prob. 16.154QPCh. 16 - A chemist needs a buffer with pH 4.35. How many...Ch. 16 - A chemist needs a buffer with pH 3.50. How many...Ch. 16 - Weak base B has a pKb of 6.78 and weak acid HA has...
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General Chemistry - Standalone book (MindTap Cour...
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General Chemistry | Acids & Bases; Author: Ninja Nerd;https://www.youtube.com/watch?v=AOr_5tbgfQ0;License: Standard YouTube License, CC-BY