re: HSC Chemistry Marathon Archive
Flexibility of a polymer is determined by the side chains of its monomers. PS is made up of a monomer styrene whcich has a bulky benzene side chain. The bulky benezene side chain greatly reduces the flexibility, making PS inflexible and increasing rigidity. The total molecular weight of PS, results in stronger dispersion frces which accounts for its hardness rigidity and toughness
lol i need to revise module 1
Question: (module 1)
Things needed for a particular galvanic cell: magnesium solid, magnesium sulfate solution, carbon (graphite rods), iron(II) sulfate, iron(III) sulfate, filter paper, 2 beakers, voltmeter
a) Identify the anode and cathode (2 marks)
b) Explain what a salt bridge does. Identify a suitable substance for a salt bridge and justify your choice (3 Marks)
c) A student suggests to replace the graphite electrode rods for lead. Explain why this is unsuitable. (2 marks)
d) This galvanic cell was placed in someplace safe and secure for a very long time (3 months). There were MANY qualitative and quantitative changes. Predict 4 possible changes and explain them (8 marks)
a) The anode is the magnesium piece of metal and the cathode is the carbon (graphite) rod.
b) A salt bridge is required to complete the circuit in a galvanic cell and to maintain electrical neutrality in the electrolyte solution of each half cell allowing for a continuous flow of current through the galvanic circuit. Aqueous KNO3 would be a suitable solution in which to immerse the salt bridge (made from filter paper) as it will not form precipitates in the electrolyte solutions and therefore allow for electrical neutrality by transferring positive K+ ions to the FeSO4/Fe2(SO4)3 solution to negate the buildup of positive charge due to a decrease in the concentration of positive Fe^(2+)/Fe^(3+) ions and transferring NO3- ions to the MgSO4 solution to negate the buildup of positive charge due to an increase in the concentration of positive Mg^(2+) ions.
c) Not sure.
d) Oxidation half-equation: Mg(s)->Mg^(2+)(aq)+2e
Reduction half-equation(s): Fe(2+)(aq)+2e->Fe(s), Fe^(3+)(aq)+3e->Fe(s)
Observed changes after three months:
- Decolourisation of the FeSO4/Fe2(SO4)3 solution due to the discharge (reduction) of Fe(3+)/Fe(2+) ions from solution
- Decrease in the mass and size of the magnesium electrode (anode) due to the oxidation of magnesium as shown by the oxidation half-equation above.
- Deposit of a brown metal on the carbon rod due to the formation and subsequent corrosion of iron in the presence of water and oxygen.
- Sedimentation of iron hydroxide (insoluble) at the bottom of the container originating from the corrosion of the iron formed in the reduction half-equation.
Corrosion of iron
Oxidation half-equation: Fe(s)->Fe^(2+)(aq)+2e
Reduction half-equation: O2(g)+2H2O(l)+4e->4OH-(aq)
Formation of insoluble Fe(OH)2: Fe^(2+)(aq)+2OH-(aq)->Fe(OH)2(s)
