Acid Base Intro notes 2015

Acids: start with “H”, make H+ ions in solution with water

Examples: HCl, H2SO4, HF, H3PO4

Nomenclature: hydrochloric acid, sulfuric acid, hydrofluoric acid, phosphoric acid

Taste sour, have a pH less than 7

Bases: end with “OH” make OH- ions in solution with water

Examples: LiOH, NaOH, KOH, Al(OH)3

Nomenclature: lithium hydroxide, sodium hydroxide, potassium hydroxide, aluminum hydroxide

Taste bitter, feel slippery (dissolve fats) have a pH greater than 7

Ammonia (NH3) is a type of base called a Lowry/Bronsted base: (get used to drawing “conjugate pairs”)

NH3 + H2O ßà NH4+ + OH-

There are 3 standard definitions of an ACID:

Arrhenius: start with “H” and produce H+ ions in water

Lowry-Bronsted: are a proton (aka Hydrogen cation) donor

Lewis: electron pair acceptor

There are 3 standard definitions of a Base:

Arrhenius: end with “OH” and produce OH- (hydroxide) ions in water

Lowry-Bronsted: are a proton acceptors

Lewis: electron pair donor

The concentration of H+ is so critical in the rate of chemical reactions (and the equilibrium of the human body) that we have a special scale for measuring tiny concentrations of the H+ ion called the pH scale.

pH means power of the hydrogen ion concentration

Mathematically pH is a function defined as: pH = - log [H+]

(pH is the negative of the log of the hydrogen ion concentration)

Exponent Review: Logarithm (log) Review:

1x10-1 = .1 -log(.1) = 1

1x10-7 = .0000001 -log(0.0000001) = 7

1x10-14 = .00000000000001 -log(0.00000000000001) = 14

(Practice pH, pOH and H+ concentration on worksheet)

Acids and Bases react together and NEUTRALIZE to produce salt and water

Acid + Base à salt + water (not just table salt, any salt)

Acids: Dissolve metals, (producing H2 gas)

react with carbonates to produce bubbles,

low (1-7) pH,

Must have hydrogen (often have oxygen as well),

turns Litmus paper RED,

taste SOUR

When they ionize they produce H+ ions which combine with water to make the H3O+ (hydronium ion)

Bases: High pH (7-14),

good for cleaning (like ammonia),

turn litmus paper BLUE,

taste bitter

feel slippery

Bases ionize to produce OH- (hydroxide ions)

Indicators: are a class of chemicals that undergo a visible color change in chemical environments that have a greater abundance of H+ or OH- ions.

Some important indicators:

Bromthymol Blue: Blue in basic conditions yellow in acids

Phenolphthalein violet in basic conditions clear in neutral or acid

Anthrocyanin: Cabbage juice indicator is _____blue/lavender__ in water (neutral)

(aka Cabbage Juice Cabbage juice indicator is ____reddish pink______in acids

Indicator) Cabbage juice indicator is _____green______in bases

Universal indicator (a mixture of four separate indicators that include, bromthymol blue, phenolphthalein, and methyl red

ROY G BIV (know the colors this reminds us of)

ROY G BIV The colors of visible light (in a rainbow)

lowest energy or longest wavelength(l) to highest energy or shortest wavelength(l)

Some acids are poly-protic (means they can give up more than one hydrogen ion)

HNO3 is monoprotic

H2SO4 is diprotic

H3PO4 is triprotic

Strong acids completely ionize (change from molecules to ions)

Would their Ka be greater than or less than 1?

Strong Bases completely dissociate (dissolve from their formula unit to their ions)

Would their Kb be greater than or less than 1?

Weak Acids and Bases will try to remain together and will covert from their equilibrium positions as stress is

placed upon them (water is just as weak an acid as it is a weak base)

Acids are formed from reaction of non-metal oxides and water

Ex: SO2 + H2O à H2SO4 (not balanced)

Or CO2 + H2O à H2CO3 (demo with BTB)

Bases are formed from metal oxides and water

Ex: CaO + H2O à Ca(OH)2

Or MgO + H2O à Mg(OH)2 (demo; with universal indicator)

Neutralization occurs when the same number of Moles of acid reacts with an equivalent number of moles of base to stoichiometerically form a salt and water.

The equation to remember is: mLacid Macid = mLbase Mbase

(volume times concentration = volume times concentration)

Volume measured in milliliters and concentration measured in Molality (moles per liter)

A salt may hydrolyze (react with water) to form an acidic or alkali solution, depending upon its “parent” acid and base.

A parent acid and a parent base neutralize to for a salt that may be “acidic” like it’s parent acid ; basic (or alkali) like it’s parent base or neutral, equally acidic and alkali (more common)

Memorize these strong acids: HCl, HBr, HI,H2SO4, HNO3, HClO3(Chloric acid)HClO4(Perchloric acid)

and HC2H3O2 or CH3COOH as acetic (or ethanoic acid aka vinegar) a very common weak acid

Memorize these strong bases: LiOH, NaOH, KOH, RbOH, CsOH, FrOH, Ca(OH)2, Sr(OH)2, Ba(OH)2, Ra(OH)2 the alkali metals and the soluble alkaline earth metals.

And the base NH3 (ammonia) an important weaker base helps you understand Lowry-Bronsted conjugate pairs.

NH3 + H2O ßà NH4+ and OH-

(NH3 and OH- are the bases; H2O and NH4+ are the acids)

Recap of titration calculations:

Complete neutralization occurs when there is just as much acid as there is base

For mono protic acids and mono hydroxyl bases

Volume of acid times the concentration of the acid will equal the volume of the base times the concentration of the base

Or more simply: mLacid Macid = mLbase Mbase

(milliliters of acid times the molarity of the acid equals the milliliters of base times the Molarity of the base)

How many ml of .25 M HCl would be needed to neutralize 30.0 ml of .15 M NaOH?