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Acids and Bases in all Different Places. I. Properties of Acids. A. Molecular substances which ionize when added to water to form hydronium (H 3 O +1 ) ions all acids are electrolytes B . React with active metals to form H 2(g ) 1. _ Mg (s) + _ HCl (aq)
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I. Properties of Acids • A. Molecular substances which ionize when added to water to form hydronium (H3O+1) ions all acids are electrolytes • B. React with active metals to form H2(g) • 1. _ Mg(s) + _ HCl(aq) • 2. _ Zn(s) + _ HCl(aq) • 3. _ Cu(s) + _ HCl(aq)
I. Properties of Acids • C. Acids affect the colors of indicators • Universal Indicator • Phenolphthalein • D. Acids neutralizebases • E. Dilute acids taste sour think citric acid and ascorbic acid (Vitamin C) • **SAFETY TIP: Acids release tremendous amounts of heat when you dilute them • (esp. H2SO4) ALWAYS ADD ACID TO WATER
II. Naming Acids • treated as an ionic compound with H+1 (hydrogen ion) as cation • negative ion can be nonmetal (binary acid) or polyatomic anion (ternary acid) • A) Binary acids – acids that contain a negative ion ending in “-ide” • 1) Formula Name • use prefix: hydro- • use root of anion’s name • use suffix: -ic • a) HCl b) HBr c) HF • hydrochloric acid hydrobromicacid hydrofluoric acid
II. Naming Acids • 2) Name Formula • follow above rules in reverse • be sure to balance charges • a) hydroiodic acid b) hydrosulfuric acid • HI H2S
II. Naming Acids • B) Ternary acids • DO NOT BEGIN WITH “hydro-“!!!!!!! • use name of polyatomic ion and switch its ending: • NOTE: sulfur stays “sulfur-” + ending, phosphorus stays “phosphor-” + ending
II. Naming Acids • 1) Formula Name • a) H2CO3 • CO3 carbonATE carbonic acid • b) H2SO4 • SO4 sulfATE sulfuric acid • 2) Name Formula • a) acetic acid • acetIC acetATE HC2H3O2 • b) phosphoric acid • phosphorIC phosphATE H3PO4 • c) nitric acid • nitrIC nitrATE HNO3
** some acids are stronger than others: Rank the following acids from weakest to strongest: sulfuric acid, carbonic acid, hydrochloric acid, hydrofluoric acid, acetic acid H2CO3 , HC2H3O2 , HF, H2SO4 , HCl
III. Bases - ionic substance which dissociates to form hydroxide (OH-1) ions in water * examples: lye (NaOH) , lime (Ca(OH)2) , milk of magnesia (Mg(OH)2) • Naming Review. Name (or give the formula for) the following bases: • 1. NaOH • sodium hydroxide • 2. Mg(OH)2 • magnesium hydroxide • 3. aluminum hydroxide • Al(OH)3 • 4. ammonium hydroxide • NH4OH
IV. Properties of Bases - often referred to as caustic or alkaline substances • A. Bases are electrolytes - dissociate in water to form OH-. • B. Bases affect the colors of indicators. • Universal IndicatorPURPLE • PhenolphthaleinMAGENTA • C. Bases neutralize acids. • D. Water solutions are bitter and slippery. • E. Emulsify fats and oilsthis is why they are useful in soap
V. Salt – any ionic compound that does not contain hydroxide (OH-1) • * all are good electrolytes
formed by a neutralization reactionAcid + Base Salt + Water • 1) _____ HCl(aq) + _____ NaOH(aq) • 2) _____ H2SO4(aq) + ____ KOH(aq) • 3) ____ HBr(aq) + _____ Ca(OH)2(aq) • 4) _____ HC2H3O2(aq) + _____ NaOH(aq)
Acid, Base, Salt, or Neither: • 1. NaCl 2. KCl 3. KOH 4. SO2 5. NH4C2H3O2 • Salt salt baseneithersalt • 1. KBr 2. H2SO4 3. HgCl2 4. Al(OH)3 5. HCl • Salt acid salt base acid • 6. KOH 7. CaO 8. K3PO4 9. CO2 10. NH4OH • Base saltsalt neither base
VI. pH – a mathematical way of measuring how acidic a solution is
It’s a logarithmic scale; that means each step is worth 10 • lemon juice is 10 times more acidic than vinegar • battery acid is 10 times more acidic than lemon juice • How many times more acidic is battery acid than vinegar?
Red Orange Green Blue Purple pH: 3 5 7 9 11 Color scale for Universal Indicator:
Which of the solutions above is the most acidic? • Battery acid • 2) Which of the solutions above is the most basic? • Lye • 3) Look at the solutions that your teacher is testing with universal indicator. • Label each as acidic, basic, or neutral • Estimate the pH based on the color • Rank the substances from most acidic to least acidic
VII. Buffer - a solution which is able to resist major changes in pH • example: HC2H3O2(aq) H+1(aq) + C2H3O2-1(aq) • common-ion effect - by adding a salt with the negative ion (NaC2H3O2, KC2H3O2), we increase the concentration of that ion, therefore: • add H+1: • the acid will react with the acetate ion to produce molecular acetic acid, thus “neutralizing” it and keeping the pH the same • add OH-1: • the base will react with the molecular acetic acid to produceacetate ions, thus “neutralizing” it and keeping the pH the same
BLOODY BUFFERS!! • biological example: carbonic acid/bicarbonate in blood Hold your Breath!!! • There is a balance between the ions which acts as a buffer, keeping the pH of the blood right around 7.4. The hemoglobin molecule in red blood cells can only withstand pH extremes of 7.2-7.6
VIII. Acid-Base Indicators - chemicals specifically designed to show specific colors in acids and different colors in bases
IX. Acid-Base Neutralization H+1 + OH-1 H2O • if you have 35 molecules of acid, 35 molecules of base will neutralize it • equivalence point - when an equivalent amount of OH-1 ions has been added to H+1 ions it’s “neutralized”
X. Acid-Base Titration - lab procedure used to determine the concentration of an unknown acid or base solution. • standard solution – solution whose concentration is known • unknown solution – solution whose concentration you are trying to determine • MaVa = MbVb
Titration Problems • 1) If you begin a titration with 20.0 mL of unknown HCl and titrate it to the equivalence point using 35.6 mL of 0.600 M standard NaOH, what is the concentration of HCl? • Ma(20.0 mL) = (0.600M)(35.6 mL) Ma= 1.07 M • 2) If you titrate 65.0 mL of an unknown NH3 solution to the equivalence point with 31.2 mL of a 1.50 M HCl solution, what is the concentration of the ammonia? • (1.50M)(31.2mL) = Mb(65.0mL) Mb= 0.720 M
Titration Problems • 1) Ma = ??? Va = 50.0 mL Mb= 1.50 M Vb = 71.3 mL • Ma(50.0mL) = (1.50M)(71.3mL)Ma= 2.14 M • 2) What is the concentration of an unknown NaOH solution if you titrate 100.0 mL of it to the equivalence point with 43.5 mL of 6.0 M HCl? • (6.0M)(43.5mL) = Mb(100.0mL) Mb= 2.6 M
Titration Problems • 3) What is the concentration of a vinegar (HC2H3O2) solution if you titrate exactly 20 drops of it to the equivalence point with 26 drops of 0.600M NaOH? • Ma(2θdr) = (0.600M)(26dr) Ma = 0.78 M