Acids and Bases.

Acids and Bases

1 14 H2O H+ OH- Ex. HCl HSO3 Ex. NaOH KOH Base Acid Strong Weak Weak
Acetic Acid NH3 NaOH 7 H2O H+ OH- Base Acid Ex. HCl HSO3 Ex. NaOH KOH

Arrhenius Acids Substances that produce H+ (hydrogen ion, proton) in soln. Properties of acids are related to the H+ ions they produce Increase H+ concentration when added to H2O Decrease OH- concentration when added to H2O Decreases pH, x<7 Turn blue litmus paper red Sour No effect on phenolphthalein, stays colorless React with certain metals to produce salt and H2 The stronger the acid, the greater the hydrogen ion concentration in comparison to the OH- ion concentration

Arrhenius Acids Some definitions:
Not all compounds that contain hydrogens are acids. Ex. CH3COOH : acetic acid, i.e. Vinegar Only hydrogens in very polar bonds are ionizable. Hydrogen ions are stabilized by solvation. Some definitions: Monoprotic Acids – acids that contain one ionizable hydrogen. Ex. HNO3 Diprotic Acids – acids that contain two ionizable hydrogens. Ex. H2SO4 Triprotic Acids – acids that contain three ionizable hydrogens. Ex. H3PO4

Arrhenius Base Substances that produce OH- (hydroxide ion) in soln.
Properties of bases are related to the OH- ions they produce Increase OH- concentration when added to H2O Decrease H+ concentration when added to H2O Increases pH, x>7 Turn red litmus paper blue Bitter and slippery Turns colorless phenolphthalein, pink. Most bases are ionic compounds. The stronger the base, the greater the OH- ion concentration in comparison to H+ ion concentration

Bronsted-Lowry Acid Bronsted-Lowry Base
Substances that DONATE H+ (hydrogen ion, proton) in rx. H2O is an acid b/c it gives up an H+ and becomes OH- (a base) Substances that ACCEPT H+ in rx. NH3 is a base b/c it accepts the H+ and becomes NH4+ (an acid)

Conjugate Acids & Bases
Bronsted- Lowry Theory Conjugate Acids & Bases Conjugate - coupled, connected, or related, in particular. In the case of the reverse reaction the conjugate acid is the acid; H+ donor on the “product” side the conjugate base is base; H+ acceptor on the “product” side. In essence, the reversible reaction of ammonia and water has two acids and two bases.

Bronsted- Lowry Theory Conjugate Acids & Bases Which substance is the B-L acid (H+ donor)? Which substance is the B-L base (H+ acceptor)? What substance is the conjugate base? What substance is the conjugate acid?

Bronsted- Lowry Theory Conjugate Acids & Bases Conjugate acids are always paired with a base, and conjugate bases are always paired with an acid. A conjugate acid-base pair consists of two ions or molecules related by the loss or gain of one hydrogen ion.

Bronsted- Lowry Theory Conjugate Acids & Bases Which substance is the B-L acid (H+ donor)? Which substance is the B-L base (H+ acceptor)? What substance is the conjugate base? What substance is the conjugate acid? The chloride ion is the conjugate base of the acid HCl. The hydronium ion is the conjugate acid of the water base.

Amphoteric Substances
Bronsted- Lowry Theory Amphoteric Substances A substance that can act as either an acid or a base is said to be amphoteric. Water is amphoteric. In the reaction with hydrochloric acid, water accepts a proton and is therefore a base. In the reaction with ammonia, water donates a proton and is therefore an acid.

Lewis Acids and Bases A Lewis acid is a substance that can accept a pair of electrons to form a covalent bond. A Lewis base is a substance that can donate a pair of electrons to form a covalent bond. The Lewis definitions include all the Brønsted-Lowry acids and bases. This definition is more general than those offered by Arrhenius or by Brønsted and Lowry.

Acid Base Theories Summary
Acid-Base Definitions Type Acid Base Arrhenius H+ producer OH– producer Brønsted-Lowry H+ donor H+ acceptor Lewis electron-pair acceptor electron-pair donor The Lewis definition is the broadest. It extends to compounds that the Brønsted-Lowry theory does not classify as acids and bases.

Practice Problem Identify the Lewis acid and the Lewis base in this reaction between ammonia and boron trifluoride. NH3 + BF3 → NH3BF3 When a Lewis acid reacts with a Lewis base, the base donates a pair of electrons and the acid accepts the donated pair.

Additional Practice Problems
Identify the Lewis acid and Lewis base in each of the reactions. H+ + H2O  H3O+ AlCl3 + Cl-  AlCl4- Would you predict PCl3 to be a Lewis acid or a Lewis base in a typical reaction? Explain your prediction. KOH + HBr  KBr + H2O HCl + H2O  H3O+ + Cl- H+ is the Lewis acid, H2O is the Lewis base AlCl3 is the Lewis acid; Cl- is the Lewis base PCl3 would be a Lewis base, it has a nonbonding pair of electrons that it can donate KOH is the base, HBr is the acid HCl is the acid, H2O is the base

Question #7 on Page 593 7. Write equations for the ionization of HNO3,in water and the reaction of CO32- with water. For each equation, identify the hydrogen-ion donor and the hydrogen-ion acceptor. Then label the conjugate acid-base pairs in each equation. HNO3 + H2O  H3O+ + NO3- Hydrogen-ion donor (Acid): HNO3 Conjugate Base: NO3- Hydrogen- ion acceptor (Base): H2O Conjugate Acid: H3O+

Acid Base Indicators Substances that change colors in the presence of an acid or base.

Hydrogen Ions and Acidity
Section 2 Hydrogen Ions and Acidity

Ion Product Constant for Water
The ionization of water is a reversible reaction, so Le Châtelier’s principle applies. Adding either hydrogen ions or hydroxide ions to an aqueous solution is a stress on the system. In response, the equilibrium will shift toward the formation of water. The concentration of the other ion will decrease.

The ionization of water is a reversible reaction, so Le Châtelier’s principle applies. In any aqueous solution, when [H+] increases, [OH−] decreases. Likewise, when [H+] decreases, [OH−] increases.

Acidic HCl(aq) → H+(aq) + Cl−(aq) A solution in which [H+] is greater than [OH−] is an acidic solution. The [H+] is greater than 1 × 10−7M. Basic NaOH(aq) → Na+(aq) + OH−(aq) A basic solution is one in which [H+] is less than [OH−]. The [H+] is less than 1 × 10−7M. AKA alkaline solutions Acids Notes: When some substances dissolve in water, they release hydrogen ions. Bases Notes: When sodium hydroxide dissolves in water, it forms hydroxide ions in solution.

For aqueous solutions, the product of the hydrogen-ion concentration and the hydroxide-ion concentration equals × 10−14. The product of the concentrations of the hydrogen ions and the hydroxide ions in water is called the ion-product constant for water (Kw). Kw = [H+] × [OH−] = 1.0 × 10−14

Using the Ion Product Constant for Water
Sample Problem 19.2 Using the Ion Product Constant for Water If the [H+] in a solution is 1.0 × 10−5M, is the solution acidic, basic, or neutral? What is the [OH−] of this solution? [H+] is 1.0 × 10−5M, which is greater than 1.0 × 10−7M. Rearrange Kw = [H+] × [OH−]  [OH−] = Kw [H+] [OH −] = 1.0 × 10−9M

Relating pH to H+ Ion Concentration
Mathematically, pH is defined as the –log of H+ ion concentration of a soln. pH = -log[H+] or [H+] = 10-pH pH is a measure of how much H+ are in a solution. If H+ concen. Is not given as 1 x 10-x : Ex. [H+] = 5.4 x 10-8M pH = -log(5.4 x 10-8) = 7.3 Expressing [H+] in scientific notation can make it easier to calculate pH. If H+ is written in scientific notation and has a coefficient of 1, then the pH of the solution equals the exponent, with the sign changed from negative to positive.

Calculating pH To calculate the pH of an aqueous solution you need to know the concentration of the hydronium ion in moles per liter (molarity). The pH is then calculated using the expression: pH = - log [H3O+] Example: Find the pH of a M HCl solution. The HCl is a strong acid and is 100% ionized in water. The hydronium ion concentration is M. Thus: pH = - log (0.0025) = - ( ) = 2.60

Calculating pH more problems
Example: What is the pH of a solution with a hydrogen-ion concentration of × 10−10M? pH = - log [H3O+] pH = - log [4.2 x 10-10M] pH = - ( ) pH = (Base)

BELL RINGER Activity 1. 2.

Calculating the Hydronium Ion Concentration from pH
pH = - log [H3O+] Calculating the Hydronium Ion Concentration from pH The hydronium ion concentration can be found from the pH by the reverse of the mathematical operation employed to find the pH. [H3O+] = 10-pH Example: What is the hydronium ion concentration in a solution that has a pH of 8.34? 8.34 = - log [H3O+] = log [H3O+] [H3O+]= = 4.57 x 10-9 M

Calculating the Hydronium Ion Concentration from pH
The pH of an unknown solution is What is the hydrogen-ion concentration? 6.35 = - log [H3O+] = log [H3O+] [H3O+]= = 4.5 x 10-7 M

Calculate the [H+] for each solution. pH = 5.00 pH = 12.38
Practice Problems Calculate the [H+] for each solution. pH = 5.00 pH = 12.38 When the pH is a whole number, you can assume the coefficient to be 1 When the pH is a decimal, use the antilog. What are the hydrogen ion concentrations for solutions with the following pH values? pH = 4.00 pH = 11.55

Relationship between pH and pOH.
pH scale ranges from For aqueous solutions, the product of the hydrogen-ion concentration and the hydroxide-ion concentration equals 1.0 × 10−14. [H+] + [OH−] = 1.0 × 10−14

Calculating pOH To calculate the pOH of a solution you need to know the concentration of the hydroxide ion in moles per liter (molarity). The pOH is then calculated using the expression: pOH = - log [OH-] Example: What is the pOH of a solution that has a hydroxide ion concentration of 4.82 x 10-5 M? pOH = - log [4.82 x 10-5] = - ( ) = 4.32

Calculating pH from [OH−]
If you know the [OH−] of a solution, you can find its pH. You can use the ion-product constant to determine [H+] for a known [OH−]. Then you use [H+] to calculate the pH.

Practice Problem What is the pH of a solution if the [OH-] = 4.0 x 10-11M? Start with the ion-product constant to find [H+]. Rearrange the equation to solve for [H+]. [H+] = Kw [OH−] Kw = [OH−] × [H+] [H+] = 1.0 × 10−14 4.0 × 10−11 = 0.25 × 10−3M 3. [H+] = 2.5 × 10−4M 4. pH = −log[H+] = −log(2.5 × 10−4) pH = 3.60 = −(− )

Practice Problems Calculate the pH of each solution
[OH-] = 4.3 x 10-5M [OH-] = 4.3 x 10-11M [H+] = 5.0 x 10-5M [H+] = 8.3 x 10-10M A. pH = 9.63 B. pH = 3.65 A. pH = 4.30 B. pH = 9.08

More Practice Problems
Find the pH and the pOH of each solution. [H+] = 1 x 10-4M [H+] = M What are the pH and pOH values of the following solutions, based on their hydrogen-ion concentrations? [H+] = 1 x 10-12M [H+] = 0.045M Use either pH Calculations worksheet #1 or #2 here

Complete Topic 8 Acids, Bases, and Salts note packet page 146, practice problems # 26-29.

Relative H+ Concentrations of Solutions
The lower the pH, the more H+ ions are in a soln. As [H+] in a soln. increases, pH of the soln. decreases. Ex. A soln. with a pH of 3 has more H+ ions then a soln. of pH 4 Difference in H+ of two soln. = 10 (difference in pH) That Means:

Relative H+ Concentrations of Soln.
Complete Topic 8 Acids, Bases, and Salts note packet page 146, practice problems #

Strong Vs Weak Acids Determined by degree in which the acid dissociates in water. Strong Acid – completely ionized in aqueous soln. High concentration of H3O+ Ex. Weak Acid – partially ionized in aqueous soln. Low concentration of H3O+ HCl(g) + H2O(l) → H3O+(aq) + Cl–(aq) CH3COOH(aq) + H2O(l) H3O+(aq) + CH3COO–(aq)

Acid Dissociation Constant;
Ka Acid dissociation constant (Ka) is the ratio of the concentration of the dissociated form of an acid to the concentration of the undissociated form. Ka reflects the fraction of an acid that is ionized Ka = [products] [reactants] Weak acids have small Ka values. Strong acids have large Ka values. Dissociation/ ionization is more complete Example: Nitrous acid (HNO2) has a Ka of 4.4 × 10−4 : strong Ethanoic acid (CH3COOH) has a Ka of 1.8 × 10−5 : weak dissociation constants are sometimes called ionization constants.

Acid Dissociation Constant;
Ka Example CH3COOH(aq) + H2O(l) H3O+(aq) + CH3COO–(aq) Keq= [H3O+] × [CH3COO–] [CH3COOH] × [H2O]

Calculating Dissociation Constants
You can find the Ka of an acid in water by substituting the equilibrium concentrations of the acid, [HA], the anion from the dissociation of the acid, [A−], and the hydrogen ion, [H+], into the equation below. Ka = [H+][A−] [HA]

Calculating Dissociation Constants
In a M solution of ethanoic acid, [H+] = 1.34 × 10−3M. Calculate the Ka of this acid. Refer to the table for the ionization equation for ethanoic acid. Start by determining the equilibrium concentration of the ions. [H+] = [CH3COO−] = 1.34 × 10−3M ( – )M = M Concentration [CH3COOH] [H+] [CH3COO−] Initial 0.1000 Change −1.34 × 10−3 1.34 × 10−3 Equilibrium 0.0987

Strong Vs Weak Bases Determined by degree in which the metal ions and hydroxide ions dissociate in water. Strong Base – completely ionized in aqueous soln. Ex. Weak Acid – partially ionized in aqueous soln. NaOH(aq) + H2O(l) → OH-(aq) + Na+(aq) NH3(aq) + H2O(l) NH4+(aq) + OH–(aq) Base Acid Conjugate Acid Conjugate Base

Neutralization A rx between an acid and a base to produce water and a salt. Generally a double replacement reaction

Titration A lab process used for determining the concen. Of an unknown soln. by reacting it with a soln. of known concen. Involves an acid and a base When moles of H+ and OH- are equal, neutralization has occurred, and the endpoint of the titrations is reached. Indicators are used to identify the endpoint. Change in indicator color = endpoint reached.

Salts Ionic compounds composed of a positive ion (other than H+) and a negative ion (other than OH-) Salt is one of the products of an acid-base neutralization rx Salts are electrolytes (conduct electricity when dissolved in H2O) Soluble salts are better electrolytes than insoluble salts Table F can be used to determine soluble and insoluble salts

Electrolytes Substances that can conduct electricity when dissolved in H2O Dissolve in H2O to produce a soln. with “+” and “–” ions. Conduct electricity b/c of mobile ions in the soln. Acids (Table K), bases (Table L), and salts are electrolytes

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