A current of 0.15A is passed through an aqueous solution of K2PtCl4. How long will it take to deposit 1.00g Pt? (M=195.1)

We will first find the charge required to deposit 1g of Pt, and then find the time taken to pass this charge with the given current.

n(Pt) = 1.00 g / M(Pt)
where n(Pt) is the number of moles of Pt, and M(Pt) = 195.1 g/mol is the molar mass of Pt.

n(Pt) = 1.00 / 195.1
n(Pt) ≈ 0.00513 mol

Since K2PtCl4 dissociates into K2PtCl2 and two Cl atoms, we can find out that 2 mole of electrons are needed for each mole of Pt.

n(e-) = n(Pt) * 2
where n(e-) is the number of moles of electrons.
n(e-) = 0.00513 * 2
n(e-) ≈ 0.0103 mol

Now, we can find the total charge required for this process using the Faraday's constant (F).

F = 96485 C/mol is Faraday's constant.

Q = n(e-) * F
Q = 0.0103 * 96485
Q ≈ 993 C (rounded)

Now that we have the required charge (Q) for depositing 1g of Pt, we can find the time (t) it takes with the given current (I).

I = 0.15 A

t = Q / I
t = 993 / 0.15
t ≈ 6620 s (rounded)

So it would take about 6620 seconds to deposit 1g of Pt with a 0.15 A current.