Solids, Liquids and Gases Solids (s): Molecules are held in place by intermolecular interactions. Liquids (l): Molecules are held next to one another by intermolecular interactions, however, these interactions are not strong enough to prevent the molecules from flowing past one another. Gases (s): The intermolecular interactions are too weak to hold the molecules next to one another, so the molecules wander off on their own.

Diffusion Diffusion is the spontaneous spreading out of a substance, and is due to the natural movement of its particles. Cotton wool soaked with hydrochloric acid Ammonium chloride Cotton wool soaked with ammonia solution Diffusion of ammonia and hydrogen chloride gases Ink being diffused in water

The mass of atoms are very small Therefore scientists cannot count individual atoms or molecules directly Instead a scientist count there particles by weighing a certain number of them Same as a bank cashier, by knowing the weight of one coin they can calculate the number of coins by dividing the total mass by the mass of one coin.

A. What is the Mole? VERY A large amount!!!! A counting number (like a dozen) Avogadro’s number (NA) 1 mol = 6.02  1023 items A large amount!!!! VERY

The Mole The mole is simply a chemist’s measurement for the amount of a substance. It is a very large number (6 x 1023) as it ‘counts’ very small ‘objects’ such as atoms and molecules which have a very small masses. This rather strange number was not selected deliberately – instead, it is the number of atoms in a sample of any element that has a mass in grams that is numerically equal to the elements atomic mass. It allows chemists to work with masses in the lab which are feasible.

The Mole Definition A mole of any substance is defined as the amount of the substance that contains as many particles as 12 g of carbon – 12.

B. Molar Mass Mass of 1 mole of an element or compound. Atomic mass tells the... That 6.01 *1023 atoms will weigh this amount 6.01 *1023 atoms of carbons will weigh 12 grams grams per mole (g/mol) 1 mole of carbon is 12 grams per litre Round to 2 decimal places

B. Molar Mass Examples carbon aluminum zinc 12.01 g/mol 26.98 g/mol

B. Molar Mass Examples water sodium chloride 2(1.01) + 16.00 = 18.02 g/mol H2O NaCl 22.99 + 35.45 = 58.44 g/mol

B. Molar Mass Examples sodium bicarbonate sucrose NaHCO3 22.99 + 1.01 + 12.01 + 3(16.00) = 84.01 g/mol C12H22O11 12(12.01) + 22(1.01) + 11(16.00) = 342.34 g/mol

If a magnesium atom is twice as heavy as an atom of carbon Then 100 moles of magnesium Are twice as heavy as 100 moles Of carbon Therefore if we have a piece of Magnesium that is twice as heavy As a piece of carbon they have an Equal number of atoms

Atom of hydrogen weighs Mr=1 Atom of carbon weighs Mr=12 Atom of hydrogen weighs Mr=1 One gram of hydrogen atoms and twelve grams of Carbon atoms both have the same number of atoms

108grams Atom of silver weighs Ar=108 Atom of carbon weighs Ar=12 If we have 12g of carbon how do we calulate the mass of silver if it has the same number of atoms 108grams

All these masses contain the same number of atoms 12g 24g 27g 40g 56g 63.5 108g carbon magnesium aluminium calcium iron copper silver All these masses contain the same number of atoms Avogadro`s number = 6 X 1023 Symbol L It is the number of atoms of carbon in 12g of the carbon-12 isotope

The amount of a substance which contains 6 X 1023 particles is called a mole of that substance Symbol mol

One mole of carbon weighs 12grams 48g of Mg (one mole weighs 24 g) One mole of carbon contains 6 X 1023 atoms Is 2 moles of Mg

Converting moles to grams Mass of one mole of an element= relative atomic mass in grams Element Relative atomic mass H 1 C 12 N 14 Mg 24 Cu 63.5 Fe 56 I 127

The mass of one mole of an element Relative Atomic Mass in grams =

The relative molecular mass of a compound is the sum of the relative atomic masses of all the atoms in the compound H2O = 2(1) + (16) = 18 (relative molecular mass of H2O) CuSO4.H2O =(63.5) + (32) +4(16) +5 (18)=249.5

Converting Grams to moles 12g of carbon = 1 mole 1g of carbon = 1/12 moles 36g of carbon= 36/12=3 moles

How many moles of sulfuric acid (H2SO4) are there in 12 How many moles of sulfuric acid (H2SO4) are there in 12.25 g of sulfuric acid Relative mol mass =2(1) + (32) + 4(16) = 98 Total mass/mass of one mole 12.25/98=0.125 mole

Converting moles to number of atoms or molecules How many atoms of sodium are present in 0.25 moles of a metal 1 mole of Na contained 6x1023 atoms 0.25 x 6x1023 atoms= 1.5 x1023 atoms

Molar Volume One mole of any gas should occupy the same volume as one mole of any other gas at the same conditions of temperature and pressure. Gases are often compared at STP, standard temperature and pressure. Standard pressure = 101325 Pa Standard temperature = 273 K Molar Volume = 22.4 L = 22,400 cm3 = 2.24 x 10–2 m3

Relative Molecular Mass The relative molecular mass is the average mass of a molecule relative to one twelfth the mass of the carbon 12 atom. The relative molecular mass has no units as it is the ratio of two masses.

Molar Mass The molar mass of a substance is the mass in grams of one mole of the substance. The molar mass has the same numerical value as its relative molecular mass, but its units are grams (g). 1 mol of carbon, 12 g

More Mole Calculations Volume of X (if a gas at STP) in litres at STP Number of particles of X ÷ 22.4 ÷ 6 x 1023 x 22.4 x 6 x 1023 Moles of X Notice that there is no direct link from particles to grams, you must first convert to moles. Likewise going from volume to mass. x molar mass ÷ molar mass Mass of X in g

Chemical Formulas

Empirical Formula The empirical formula of a compound is the formula that gives that simplest whole number ratio in which the atoms of the elements in the compound are present. The empirical formula of glucose, C6H12O6 (ratio of atoms is 6:12:6) is CH2O, as this is the lowest ratio (1:2:1) of the atoms C, H and O.

Molecular Formula The molecular formula of a compound is the formula that gives the actual number of atoms of each element present in a molecule of the compound.

Percentage Composition by Mass If the empirical formula of a compound is known, the percentage by mass of each element present can be calculated. It can be useful to calculate the percentage of a certain element in a compound, for example the percentage of nitrogen in fertilisers.

Structural Formulas The structural formula of a compound shows the arrangement of the atoms within a molecule of the compound. Some Examples: You will come across many more structural formulas in the organic section of the course. Methane, CH4 Ethene, C2H4 Ethanol, C2H5OH

Chemical Equations

Chemical Equations A chemical equation is a way of representing a chemical change. It shows reactants and products. To balance an equation means to change the numbers of each molecule involved, so that the same number of atoms of each element appear on the reactants side and on the products side. Chemical equations balance on an atomic level, not molecular. You cannot change the formula of a substance, i.e. if the equation has NH3 you cannot change this you can only put a number in front of it, 2NH3, increasing the number of N’s and the number of H’s. Never change the subscripts (small numbers). It is possible to write balanced equations for lots of reactions but that does not mean that the reaction actually takes place.

Formation of Water (Oxygen does not exist as single atoms) (This reaction does not take place)

Balancing an Equation

Balance the following

Balancing Redox Equations In working out what is oxidised and what is reduced in a reaction, it is important to remember that oxidation numbers are not a charge. Write the oxidation numbers below each atom to which it applies, as shown in the examples. Oxidation is an increase in oxidation number. Reduction is a decrease in oxidation number.

Assign oxidation numbers to all the atoms in the equation. Write down half equations of what is oxidised and reduced. Attach subscripts to atoms oxidised and reduced and balance the half equations. Balance the half equations. Attach species that were attached to the oxidised and reduced atoms. Include all the original species and complete the balancing by inspection.

Calculations using Chemical Equations A balanced equation for a chemical reaction gives the relative amounts of each reactant and each product involved in the reaction. If the amount of one substance is known, based on the molar ratios in the equation, the amounts (masses, particles or volume)of other substances can be calculated. Make sure to always work in moles.