http://www.vcaa.vic.edu.au/Documents/exams/chemistry/2011chem1-w.pdf
Section 1
Question 8 - Still not sure as to why they chose D over C
Question 9 - I don't quite get the VCAA answers
Question 11 - I understand that the equivalence point is influenced by n(H+) available from each acid and since c x v gives the same answer for both, the equivalence would be the same. However, I was just thinking that a strong acid would mean that it would donate its proton easily? and so would require less NaOH? but I might be completely wrong
Question 12 - Not sure how?
Question 18 - How does mass relate to the energy (frequency) required for vibration?
Question 19 - Why not UV- Vis?
Section B
Question 1 c and d - I think I lack the theoretical knowledge required for these question. Could someone explain how they would answer it? What their thought process is?
Thanks Guys 
8 is admittedly really dodgy.
But you have to take the hint from the question. It's more soluble in water => charged. The amide wouldn't be nearly as soluble as the ionic salt.
For 9, in future, please post the VCAA answers; makes it easier for the poor guy who has to go look it up
OK...this question is funny. The reaction is canola oil plus ethanol gives ethyl stereate and glyercol, with a potassium hydroxide catalyst. The top layer is ethyl stereate, so the bottom layer is everything else; ethanol, glyercol and potassium hydroxide. Hence D is correct. However, depending on the stoichiometry, ethanol may not be present in the bottom layer, so A was accepted. Be mindful though that no reactions ever go to completion, so A is unrealistic.
11 Let's think of it this way
Let A be the acid, and B- be the base.
We have three equilibria here.
HA<=>H+ + A-
B- + H2O <=> OH- + HB
H+ + OH- <=> H2O
Now, B is hydroxide, so we don't need to consider the second equilibrium.
Hydroxide ions will react with effectively ANY H+ ions present (due to the large disparity between the concentrations; [OH-] is around 0.10 M), so the third equilibrium will be driven to the right. Thus, so will the first equilibrium. The net result is that the OH- reacts with HA almost completely. HA's acid strength doesn't matter, as long as HA is a stronger acid than water.
It's true that a strong acid will dissociate more readily. OH- is such a strong base, though, that it can react with essentially any acid.
Think of it this way. For the equilibrium HA<=> H+ + A- and the equilibrium H+ + OH- <=> H2O
Let the equilibrium constants be Ka and 1/Kw
The combined reaction, HA + OH- <=> A- + H2O, has an equilibrium constant of Ka*1/Kw=Ka/Kw
Now...Kw is tiny. 1/Kw is 10^14. Multiplying that by any Ka in the data table and we'll still have a K constant that is quite large.
Thus, same amount of OH- reacts with the acid.
12
Thymol blue is yellow => pH>2.8 (base form)
methyl red is yellow => pH>6.3 (base form)
Phenolphthalein is colourless => pH<8.3 (acid form)
Which pH value satisfies these constraints?
18
This is a very bad question IMO. Larger mass, even with same bond strength => smaller vibration. Think about it. If you have a spring, if the load is heavier, it'll oscillate less.
Although technically, C is correct too because a larger atomic radius means a larger bond length, which means a weaker bond.
19
UV Vis does NOT identify. For starters, the different hydrocarbons may all have similar absorption wavelengths for all we know. Does that help with UV Vis? Not really.
Also, all UV Vis does is determine the absorbance of a particular frequency. It is only useful when we know what we're testing and we have other standards of the known compound to compare absorbances. UV Vis cannot tell us what a compound is. We need to separate it first, with gas chromatography perhaps, and then use something like NMR or mass spec to work out what we have. Hence D.
1. c
Hydrolysed saturated triglyceride => glycerol and three saturated fatty acids.
Glycerol is E. The saturated fatty acid is D.
d
Biodiesel mainly consists of methyl esters. Just remember that.
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