Worked Instances: Q = n(e – )F and you can Q = It


Worked Instances: Q = n(e – )F and you can Q = It

Question 1. Just what size from copper would-be transferred regarding an effective copper(II) sulphate provider having fun with a current off 0.fifty A beneficial over ten seconds?

Extract the data from the question: electrolyte: copper(II) sulphate solution, CuSOcuatro current: I = 0.50 A time: t = 10 seconds F = 96,500 C mol -1 (data sheet)

Determine the amount of electricity: Q = We x t I = 0.fifty An effective t = 10 seconds Q = 0.fifty ? ten = 5.0 C

Estimate the latest moles regarding electrons: n(age – ) = Q ? F Q = 5.0 C F = our teen network gratis proefversie 96,five hundred C mol -step one letter(elizabeth – ) = 5.0 ? 96,500 = 5.18 ? 10 -5 mol

Assess moles away from copper utilising the balanced prevention 1 / 2 of effect picture: Cu 2+ + 2e – > Cu(s) step one mole out of copper try placed of 2 moles electrons (mole proportion) moles(Cu) = ?n(age – ) = ? ? 5.18 ? 10 -5 = dos.59 ? ten -5 mol

bulk = moles ? molar bulk moles (Cu) = dos.59 ? ten -5 mol molar mass (Cu) = grams mol -1 (out of Periodic Desk) size (Cu) = (2.59 ? 10 -5 ) ? = 1.65 ? ten -step three g = 1.65 mg

Use your calculated value of m(Cu(s)) and the Faraday constant F to calculate quantity of charge (Q(b)) required and compare that to the value of Q(a) = It given in the question. Q(a) = It = 0.50 ? 10 = 5 C

Use your computed value of amount of time in seconds, the Faraday constant F as well as the most recent offered from the matter so you’re able to calculate the fresh mass out-of Ag you can put and you can evaluate that toward worth given in the matter

Q(b) = n(e – )F n(e – ) = 2 ? n(Cu) = 2 ? [m(Cu) ? Mr(Cu)] = 2 ? [(1.65 ? 10 -3 ) ? ] = 2 ? 2.6 ? 10 -5 = 5.2 ? 10 -5 mol Q = 5.2 ? 10 -5 ? 96,500 = 5

Question 2. Calculate the time needed to put 56 g away from gold from a silver nitrate service having fun with a recent away from cuatro.5 A.

Estimate the fresh new moles out of silver transferred: moles (Ag) = bulk (Ag) ? molar bulk (Ag) mass Ag placed = 56 grams molar size = 107

Extract the data from the question: mass silver = m(Ag(s)) = 56 g current = I = 4.5 A F = 96,500 C mol -1 (from data sheet)

Calculate the new moles from electrons necessary for brand new impulse: Build this new prevention effect formula: Ag + + age – > Ag(s) Regarding the picture 1 mole out of Ag is deposited by the 1 mole out of electrons (mole proportion) therefore 0.519 moles regarding Ag(s) are deposited because of the 0.519 moles off electrons n(elizabeth – ) = 0.519 mol

Assess the amount of energy necessary: Q = n(elizabeth – ) ? F n(age – ) = 0.519 mol F = 96,five hundred C mol -step 1 Q = 0.519 ? 96,500 = 50,083.5 C

Q = It = 4.5 ? 11, = 50083.5 C Q = n(e – )F so, n(e – ) = Q ? F = 50083.5 ? 96,500 = 0.519 mol n(Ag) = n(e – ) = 0.519 mol m(Ag) = n(Ag) ? Mr(Ag) = 0.519 ? 107.9 = 56 g Since this value for the mass of silver is the same as that given in the question, we are reasonably confident that the time in seconds we have calculated is correct.

1. More formally we declare that to own certain level of electricity the quantity of substance produced is proportional so you’re able to their equivalent weight.

Use your calculated value of m(Ag(s)) and the Faraday constant F to calculate quantity of charge (Q) required and compare that to the value given in the question. n(e – ) = n(Ag) = mass ? molar mass = 0.894 ? 107.9 = 8.29 ? 10 -3 mol Q = n(e – )F = 8.29 ? 10 -3 mol ? 96,500 = 800 C Since this value of Q agrees with that given in the question, we are reasonably confident that our calculated mass of silver is correct.

Worked Instances: Q = n(e – )F and you can Q = It

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