Acids and Bases Dr. Ron Rusay Summer 2004 © Copyright 2004 R.J. Rusay
Introduction to Aqueous Acids Acids: taste sour and cause certain dyes to change color.
Introduction to Aqueous Bases Bases: taste bitter, feel soapy and cause certain dyes to turn color.
Electrolytes Aqueous solutions can be categorized into 3 types: non-electrolytes, strong electrolytes or weak electrolytes based on their ability to conduct electricity. A solution must have ions to conduct. Pure Water does not conduct. Aqueous solutions can be tested for conductivity which will determine the degree of ionization of the solutes. It is possible to have full or partial ionization. © Copyright R.J. Rusay
Solution Test Apparatus for Electrolytes
Conductivity
Electrolytes / Ionization
Electrolytes Almost all ionic compounds and a few molecular compounds are strong electrolytes. Several molecular compounds are weak conductors, most are non-conductors. Conductivity is directly related to the amount of ionization, i.e. ions in solution. Table salt, sodium chloride, is completely ionized: NaCl (s) + H 2 O (l) ---> NaCl (aq) ---> 0.10molNa + (aq) + Cl - (aq) © Copyright R.J. Rusay 0.00mol 0.10mol 0.10mol
Strong vs. Weak Electrolytes
Models of Acids and Bases Arrhenius Concept: Acids produce H + in solution, bases produce OH ion. Brønsted-Lowry: Acids are H + donors, bases are proton acceptors. HCl + H 2 O Cl + H 3 O + acid base acid base
Lewis Acids and Bases Lewis Acid: electron pair acceptor Lewis Base: electron pair donor
Conjugate Acid/Base Pairs HA(aq) + H 2 O(l) H 3 O + (aq) + A (aq) conj conj conj conj acid 1 base 1 acid 2 base 2 conjugate base: everything that remains of the acid molecule after a proton is lost. conjugate acid: formed when the proton is transferred to the base.
Acid Strength 100% of the acid is ionized. For example nitric acid, HNO 3. Other common strong acids are sulfuric and hydrochloric. 100% of the acid is ionized. For example nitric acid, HNO 3, produces 100% H + (aq). Other common strong acids are sulfuric and hydrochloric. Stong acids produce very weak conjugate bases, eg. (NO 3 ) Strong Acids:
Structure and Acid Strength Bond polarity & bond strength affects acidity. In binary compounds: Bond Polarity (The higher the bond polarity, the stronger the bond, the weaker the acid) eg. HF Bond Strength (The lower the bond strength, the higher the resulting H + ionization and the stronger the acid. ) eg. HCl
Oxides Acidic Oxides (Acid Anhydrides): O X bond is strong and covalent. SO 2, NO 2, CrO 3 Basic Oxides (Basic Anhydrides): O X bond is ionic. K 2 O, CaO
Dissociation of Strong and Weak Acids
Acid Strength (continued) A weak acid is not 100% ionized. For example acetic acid, CH 3 COOH,. Most acids, particularly organic acids, are weak acids. A weak acid is not 100% ionized. For example acetic acid, CH 3 COOH, produces <100% H + (aq). Most acids, particularly organic acids, are weak acids. Weak acids produce a much stronger conjugate base than water, eg. The acetate ion: (CH 3 COO ) Weak Acids :
Multiprotic Acids Monoprotic acids have 1 acidic H, diprotic have 2, eg. Sulfuric acid H 2 SO 4 etc. In a strong multiprotic acid, like H 2 SO 4, only the first H is strong; transferring the second H is usually weak H 2 SO 4 + H 2 O H 3 O +1 + HSO 4 -1 HSO H 2 O H 3 O +1 + SO 4 -2
Aqueous Bases Any compound that accepts a proton is a base. The common bases are group IA & IIA metal hydroxide compounds. “Strong” and “weak” are used in the same sense for bases as for acids. Strong = complete dissociation (100% hydroxide ion is supplied to the solution) An example of a weak base is ammonia. NH 3 (g) + H 2 O (l) NH 3 (aq) NH 4 + (aq) + OH - (aq) © Copyright R.J. Rusay
Bases (continued) Weak bases have very little dissociation (or reaction with water), eg. methyl amine like ammonia has <100% hydroxide ion in aqueous solution. H 3 CNH 2 (aq) + H 2 O(l) H 3 CNH 3 + (aq) + OH (aq) Organic bases are weak bases; for example, dopamine (neurotransmitter), cadaverine (product of cellular decomposition), morphine (narcotic pain killer) and cocaine are weak bases.
Natural Indicators
Reactions of Acids & Bases A use for natural indicators: “Neutralization Reactions” Titrations Examples
Water as an Acid and a Base Amphoteric substances can act as either an acid or a base Water acting as an acid:Water acting as an acid: NH 3 + H 2 O NH OH -1 NH 3 + H 2 O NH OH -1 Water acting as a base:Water acting as a base: HCl + H 2 O H 3 O +1 + Cl -1 HCl + H 2 O H 3 O +1 + Cl -1 Water reacting with itself as both:Water reacting with itself as both: H 2 O + H 2 O H 3 O +1 + OH -1
Water as an Acid and a Base Water is amphoteric. It can behave either as an acid or a base. H 2 O (l) + H 2 O (l) H 3 O + (aq) + OH (aq) conj conj conj conj acid 1 base 1 acid 2 base 2 acid 1 base 1 acid 2 base 2 The equilibrium expression for pure water is: K w = [H 3 O + (aq) ] [OH (aq) ]
Water: Self-ionization
Autoionization of Water Water is an extremely weak electrolyte therefore are only a few ions present: K w = [H 3 O +1 ] [OH -1 ] = 1 x 10 25°C NOTE: the concentration of H 3 O +1 and OH -1 are equalNOTE: the concentration of H 3 O +1 and OH -1 are equal [H 3 O +1 ] = [OH -1 ] = °C[H 3 O +1 ] = [OH -1 ] = °C K w is called the ion product constant for water: as [H 3 O +1 ] increases, [OH - ] decreases and vice versa.K w is called the ion product constant for water: as [H 3 O +1 ] increases, [OH - ] decreases and vice versa.
Acidic and Basic Solutions Acidic solutions have: a larger [H +1 ] than [OH -1 ] Basic solutions have: a larger [OH -1 ] than [H +1 ] Neutral solutions have [H +1 ] = [OH -1 ] = 1 x M [H +1 ] = 1 x [OH -1 ] [OH -1 ] = 1 x [H +1 ]
The pH Scale pH log[H + ] log[H 3 O + ] pH in water ranges from 0 to 14. K w = 1.00 10 14 = [H + ] [OH ] pK w = = pH + pOH As pH rises, pOH falls (sum = 14.00).
pH & pOH pH = -log[H 3 O +1 ]pOH = -log[OH -1 ] pH water = -log[10 -7 ] = 7 = pOH waterpH water = -log[10 -7 ] = 7 = pOH water [H +1 ] = 10 -pH [OH -1 ] = 10 -pOH pH 7 is basic, pH = 7 is neutral The lower the pH, the more acidic the solution; The higher the pH, the more basic the solution 1 pH unit corresponds to a factor of 10 pOH = 14 - pH
There are no theoretical limits on the values of pH or pOH. (e.g. pH of 2.0 M HCl is , the pH at Iron Mountain, California is ~ -2 to -3)
What’s in these household products? Acids or bases? Strong or weak? Should you be concerned about safety?
The pH of Some Familiar Aqueous Solutions [H 3 O + ] [OH - ] [OH - ] = KWKW [H 3 O + ] neutral solution acidic solution basic solution [H 3 O + ]> [OH - ] [H 3 O + ]< [OH - ] [H 3 O + ] = [OH - ] What’s your diet? Your urine will tell!
Example #1 Determine the given information and the information you need to find Given [H +1 ] = 10.0 MFind [OH -1 ] Solve the Equation for the Unknown Amount Determine the [H +1 ] and [OH -1 ] in a 10.0 M H +1 solution
Convert all the information to Scientific Notation and Plug the given information into the equation. Given [H +1 ] = 10.0 M= 1.00 x 10 1 M K w = 1.0 x Example #1 (continued) Determine the [H +1 ] and [OH -1 ] in a 10.0 M H +1 solution
Example #2 Find the concentration of [H +1 ] Calculate the pH of a solution with a [OH -1 ] = 1.0 x M
Enter the [H +1 ] concentration into your calculator and press the log key log(1.0 x ) = -8.0 Change the sign to get the pH pH = -(-8.0) = 8.0 Example #2 continued Calculate the pH of a solution with a [OH -1 ] = 1.0 x M
Enter the [H +1 ] or [OH -1 ]concentration into your calculator and press the log key log(1.0 x ) = -3.0 Change the sign to get the pH or pH pOH = -(-3) = 3.0 Subtract the calculated pH or pOH from to get the other value pH = – 3.0 = 11.0 Calculate the pH and pOH of a solution with a [OH -1 ] = 1.0 x M Example #3
If you want to calculate [OH -1 ] use pOH, if you want [H +1 ] use pH. It may be necessary to convert one to the other using 14 = [H +1 ] + [OH -1 ] pOH = – 7.41 = 6.59 Enter the pH or pOH concentration into your calculator Change the sign of the pH or pOH -pOH = -(6.59) Press the button(s) on you calculator to take the inverse log or 10 x [OH -1 ] = = 2.6 x Example #4 Calculate the [OH -1 ] of a solution with a pH of 7.41
Calculating the pH of a Strong, Monoprotic Acid A strong acid will dissociate 100% HA H +1 + A -1 Therefore the molarity of H +1 ions will be the same as the molarity of the acid Once the H +1 molarity is determined, the pH can be determined pH = -log[H +1 ]
Example #5 Determine the [H +1 ] from the acid concentration HNO 3 H +1 + NO M HNO 3 = 0.10 M H +1 Enter the [H +1 ] concentration into your calculator and press the log key log(0.10) = Change the sign to get the pH pH = -(-1.00) = 1.00 Calculate the pH of a 0.10 M HNO 3 solution
The pH Scale What is the pH of 6M hydrochloric acid?
Neutralization Reactions How would indicator be used?
Aqueous Reactions: Neutralization Net Ionic Equations HCl (aq) + NaOH (aq) ---> NaCl (aq) + H 2 O (l) ___________________________________________________ HCl (aq) ---> H + (aq) + Cl - (aq) NaOH (aq) ---> Na + (aq) + OH - (aq) NaCl (aq) ---> Na + (aq) + Cl - (aq) ________________________________________________ Na + (aq) + OH - (aq) + H + (aq) + Cl - (aq) ---> Na + (aq) + Cl - (aq) + H 2 O (l) _______________________________________________________ © Copyright R.J. Rusay H + (aq) + OH - (aq) ---> H 2 O (l)
Acid-Base Titration Acids have pH 7, and 7 is neutralAcids have pH 7, and 7 is neutral Without a pH meter how can the progress of reaction be monitored?Without a pH meter how can the progress of reaction be monitored?
Acid-Base Titration pH & Water
Stomach Chemistry
Buffered Solutions Buffered Solutions resist change in pH when an acid or base is added to it. Used when need to maintain a certain pH in the system, eg. Blood. A buffer solution contains a weak acid and its conjugate base Buffers work by reacting with added H +1 or OH -1 ions so they do not accumulate and change the pH. Buffers will only work as long as there is sufficient weak acid and conjugate base molecules present.
Buffers