Moles and Formulas
Avogadro's constant is 6.02 x 1023 and is the number of atoms in one mole of any element.
Number of particles (N) = number of moles (n) x Avogadro's constant (L)
Empirical formula gives the ratio of the atoms of different elements in a compound (molecular formula represented as simplest ratio)
1. g or % of elements / their Ar = moles
2. Moles / smallest number of moles = simplest ratio
Molecular formula shows actual number of atoms of each element present in molecule.
1. Number given / total Ar = ratio
2. Multiply empirical formula by ratio
Reactions and equations
Ionic equations are used because ionic compounds are completely dissociated in solution.
Ag+(aq) + NO3-(aq) + Na+(aq) + Cl-(aq) à AgCl(s) + Na+(aq) + NO3-(aq)
Na+(aq) and NO3-(aq) are spectator ions (do not take part), so we make the ionic equation which is…
Ag+(aq) + Cl-(aq) --> AgCl(s)
Solutions
Concentration (mol dm-3) = number of moles (mol) / volume (dm3)
Divide volume by 1000 if in cm3
Standard solutions are solutions of known concentration. They are used to find concentrations of other solutions which can be done by volumetric analysis such as titrations.
Calculations from equations
Limiting reactants and yield
Often experimental yield < theoretical yield, because...
-reaction is incomplete
-side reactions with unwanted substances produced
-complete separation of product from reaction mixture is impossible
-product lost during transfer of chemicals during preparation
Efficiency of procedure given by percentage yield.
% yield = (experimental yield / theoretical yield) x 100
States
Gases
For a gas:
Number of moles (n) = volume (V) / molar volume (Vmol)
At constant temperature - P ∝ 1/V (or PV = constant)
At constant volume - P ∝ T (or P/T = constant)
At constant pressure - V ∝ T (or V/T = constant)
These variables are all related by the Ideal Gas Equation:
PV = nRT (this is used if you are given or trying to find moles)
Refer to IBDP Chemistry, An ideal gas exactly obeys these laws. Real gases have some attractive forces between particles and these particles do occupy some space so they do not exactly obey. If they did they would never condense into liquids. Gases behave most 'ideally' at high temperatures and low pressures.
When mass of a particular gas is fixed (nR is constant) and we want to convert pressure, temperature and volume under one set of conditions (1) to another (2) we use the Combined Gas Law:
P1 V1 = P2 V2
T1 T2
Same units for P and V on each side and T is absolute temperature in K.
This is the end of this topic.