L3.1: Acids & Bases

avatar
Created by
Ayen B.

Cards (11)

  • Acids must have Hydrogen (H+) in their chemical formula. (i.e. HCl, HA)
    Bases must have a Hydroxide (OH-) in their chemical formula. (i.e. NaOH)
  • Arrhenius
    ● The earliest definition of acids and bases, which was suggested by Swedish Chemist Svante Arrhenius in the 1800s.
    ● This definition classifies these substances in terms of their behavior in water:
    Acids
    ■ are H+ or H3O+ producers.
    ■ has H in its formula that dissociates in H2O to yield H3O+
    Bases
    ■ are OH producers.
    ■ has OH in its formula that dissociates in H2O to yield OH-
    ● When acids and bases react, they undergo neutralization.
  • Strong Acid
    Strong acids dissociate completely into ions in water. Meaning, every molecule of the acid (HA) breaks apart into ions.
    ● There are no more HA molecules in a diluted solution of strong acid.
    ★ HA = Acid = Simple Definition
    ■ H = Hydrogen
    ■ A = Element/Molecule
  • Weak Acid
    Weak acids dissociate slightly into ions in water. Meaning, only a few HA molecules split into ions; most stay as HA.
    ● Most HA molecules are still associated in a diluted solution of weak acid.
    ● The equilibrium constant in terms of concentration (Kc), in weak acids, have very small values.
  • Acid Dissociation Constant (Ka)
    ● Measures the strength of an acid, and is indicated by Ka
    Acid Strength | [H30+] | % of HA dissociated | Ka value
    • Strong Acid | High | High | Large
    • Weak Acid | Low | Low | Small
  • Brønsted-Lowry
    ● A more general definition of acids and bases, compared to the earlier and older Arrhenius definition.
    ● The acid-base reaction of this definition, is a proton transfer process.
    ○ Reaction can occur between gasses, in aqueous/non-aqueous solutions, and in heterogeneous mixtures.
    ■ No longer being restricted to just H2O for reaction to occur.
  • Brønsted-Lowry
    ● This definition classifies substances in terms of
    their transfer of a hydrogen (H+) atom.
    ○ Acids
    ■ are proton donors.
    ■ any species that donates an H+ ion
    ■ must contain H+ in its formula.
    ● All Arrhenius acids are Brønsted-Lowry acids.
    ○ Bases
    ■ are proton acceptors.
    ■ any species that accepts an H+ ion.
    ■ must contain a lone electron pair to bond to H+
  • Arrhenius
    • Base must produce OH directly by itself in water. (Arrhenius base)
    • But NH3 doesn't have OH-, and it doesn't dissociate into OH− ; it reacts with water to form OH
    Brønsted-Lowry
    • NH3 accept proton from water (Brønsted base)
    • H2O donates proton to NH3 (Brønsted acid)
  • Conjugate Acid-Base Pairs
    ● Pairs that consist of two substances that differ by exactly one proton, which is the Hydrogen (H+) atom.
    ● Every acid has a conjugate base, and every base has a conjugate acid.
    Acidloss of H+ → Conjugate Base
    Basegain of H+ → Conjugate Acid
  • Conjugate Acid-Base Pairs
    ● The net direction of an acid-base reaction depends on the relative strengths of the acids and bases involved.
    ○ A reaction will favor the formation of the weaker acid and base.
    ○ This is noted because all Brønsted-Lowry acid-base reactions are equilibrium reactions, meaning they can go forward or reverse.
    ● The stronger the acid, the weaker the conjugate base and vice versa.
  • Conjugate Acid-Base Pairs
    ● The stronger the acid, the weaker the conjugate base and vice versa.
    ○ When an acid reacts with a base that is farther down the list, the reaction
    proceeds to the right (Kc > 1).
    ● An amphoteric compound contains both a hydrogen atom and a lone pair of e- meaning it can be either an acid or a base.
    ○ Prime example of such is water or H2O.