25.1-pH-and-the-Acid-Dissociation-Constant.pptx

25.1-pH-and-the-Acid-Dissociation-Constant.pptx

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  pH and theAcid Dissociation Constant Learning Outcomes: CHAPTER 4 - Acids and bases – Lesson 3 1. understand and use the terms strong acid and weak acid. 2. apply the knowledge of pH to calculate ion concentrations. 3. define mathematically the terms pH, Ka and Kw and use them in calculations (Kb and the equation Kw = Ka × Kb will not be tested) LESSON OBJECTIVE: Investigate pH, Kw, Ka and how to utilise them in calculations.
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  QUICK QUIZ 3) 4)
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  Recap Question For the reactionbelow label the acid, base, conjugate acid, conjugate base and identify the conjugate pairs: NH3(aq) + H2O(l) NH ⇌ 4 + (aq) + OH- (aq) Acid Conjugate Base Conjugate Acid Base - Brønsted-Lowry theory of acids and bases: acids are proton donors and bases are proton acceptors. - Conjugate pairs: an acid and base on each side of an equilibrium equation that are related to each other by the difference of a proton - Equilibrium expression (Kc): A relationship that links the equilibrium concentrations of reactants/products to the stoichiometry that can be used to calculate an equilibrium constant
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  - Water isamphoteric, it is able to act as either an acid or a base: H2O(l) + H2O(l) H ⇌ 3O+ (aq) + OH- (aq) - This is often simplified as: H2O(l) H ⇌ + (aq) + OH- (aq) - What would a Kc expression for this reaction look like? - Extent of ionisation is incredibly low, therefore [H+ ] and [OH- ] is too - Thus can simplify further, assume concentration of water is constant Ionic Product of Water (Kw) is the equilibrium constant for the ionisation of water Kw = [H+ ][OH- ] - Kw = 1.00 × 10-14 mol2 .dm-6 at 298K - Pure water is neutral: - [H+ ] = [OH- ] - Kw = [H+ ]2 - [H+ ] = 1.00 × 10-7 mol.dm-3 Ionic Product of Water, Kw Kc = __________________ [H+ (aq)][OH- (aq)] [H2O(l)]
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  pH Scale - Whatmakes a solution acidic? The amount of H+ in solution - pH is a measurement of the acidity of an aqueous solution: pH = -log[H+ ] - The pH scale shows how acidic/basic a solution is on a scale from 1 to 14 - Invented by Danish chemist Søren Sørensen - Uses a logarithmic scale to account for a very large range of hydrogen ion concentrations - Negative sign results in (mostly) all positive values - Pure water is neutral, calculate the pH of pure water ([H+ ] = 1.00 × 10-7 mol.dm-3 ) neutral 7 basic 0 14 acidic [H+ ] > [OH- ] [H+ ] < [OH- ] Can rearrange equation to get [H+ ] from pH: [H+ ] = 10-pH Question 1) Calculate the pH of a solution with [H+ ] = 1.6 × 10-4 mol.dm-3 2) Determine the [H+ ] in a solution with pH = 10.5 pH = 3.80 [H+ ] = 3.16 × 10-11 mol.dm-3
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  Acid-Base Strength andpH Strong Acids: - Strong monoprotic acids completely ionise in water: HCl(aq) H → + (aq) + Cl- (aq) - Assume conc of strong acid is equal to conc of H+ and use that value in pH equation - Can ignore the negligent amount of H+ produced from ionisation of water - Note: more steps required for polyprotic acids (e.g. H2SO4, H3PO4) Strong Bases: - Strong bases also completely ionise in water: NaOH(aq) Na → + (aq) + OH- (aq) - Rearrange Kw expression: [H+ ] = Kw /[OH-] (Kw=1.00×10-14 mol2 .dm-6 at 298K) - Can then use pH equation Question 1) Determine the pH of a solution if [HCl] = 2.00×10-3 mol.dm-3 2) Determine the pH of a solution if [NaOH] = 0.0500 mol.dm-3 pH = 2.70 pH = 12.7
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  Ka =_________ [H+ ][A- ] [HA] The AcidDissociation Constant, Ka Weak Acids - Monoprotic weak acids do not fully dissociate: HA(aq) H ⇌ + (aq) + A- (aq) - Can apply equilibrium law to obtain an acid dissociation constant, the equilibrium constant for a weak acid: The value of Ka will imply the degree of ionisation - For monoprotic acids [H+ ] = [A- ] thus: Ka = ______ [H+ ]2 [HA] Question A weak acid has a Ka value of 6.3 × 10–6 mol.dm-3 , determine the pH of a 0.15 mol.dm-3 solution of this weak acid. pH = 3.0 [HA] = Total concentration – [H]
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  pKa Very Weak Acids -Ka values can be very small in which case we can give a pKa value, a value of Ka expressed as a logarithm: pKa = -logKa Question A 0.100 mol.dm-3 solution of ethanoic acid has a [H+ ] of 1.32 × 10-3 mol.dm-3 , calculate the Ka and pKa for this weak acid. Ka = 1.74 × 10-5 mol.dm-3 pKa = 4.76
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  pH and theAcid Dissociation Constant Learning Outcomes: (taken from the Cambridge International AS and A Level Chemistry curriculum) 25.1 Acids and bases 1. understand and use the terms conjugate acid and conjugate base 2. define conjugate acid-base pairs, identifying such pairs in reactions 3. define mathematically the terms pH, Ka pKa and Kw and use them in calculations (Kb and the equation Kw = Ka × Kb will not be tested) LESSON OBJECTIVE: Investigate pH, Kw, Ka, pKa and how to utilise them in calculations.
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  Work through eachtask, one column at a time. Start at the bottom and work your way up. Explain how the ionic product of water, Kw, can be simplified to Kw = [H+ ]2 and why [H+ ] equals 1.00 × 10-7 mol.dm-3 at 298K. Calculate the following: 1) The pH of a solution with a hydrogen ion concentration of 2.7×10-2 mol.dm-3 2) The concentration of hydrogen ions present in a solution with a pH equal to 9.3 A 0.010 mol.dm-3 solution of a weak acid had a pH of 2.75, calculate its corresponding Ka and pKa values. Summarise the equation used to calculate Kw from [H+ ] and [OH- ] and state its value at 298K. Summarise what information the pH of a solution can provide and why it is necessary to use a logarithmic scale to represent it. Explain the concept of the acid dissociation constant, Ka and how it can be used to calculate a pKa value. Rationalise when it is appropriate to use a pKa value. Define the ionic product of water, Kw. Copy the equation to calculate pH from [H+ ] and then rearrange it to make [H+ ] the subject. Summarise how to determine the pH for a strong acid and a strong base. START AT THE BOTTOM WORK TOWARDS THE TOP