Problem One
You will use both m * c * deltaT and H = m * heat of fusion.
Givens
m = 12.4 grams
c = 0.1291
t1 = 26oC
t2 = 1204
heat of fusion (H_f) = 63.5 J/grams.
Equation
H = m * c * deltaT + m * H_f
Solution
H = 12.4 * 0.1291 * (1063 - 26) + 12.4 * 63.5
H = 1660.1 + 787.4
H = 2447.5 or 2447.47 is the exact answer. I have to leave the rounding to you. I have no idea where to round it although I suspect 2450 would be right for 3 sig digs.
Problem Two
Formula and Givens
t1 = 14.5
t2 = 50.0
E = 5680
c = 4.186
m = ??
E = m c * deltaT
Solution
5680 = m * 4.186 * (50 - 14.5)
5680 = m * 4.186 * (35.5)
5680 = m * 148.603 * m
m = 5680 / 148.603
m = 38.22 grams That isn't very much. Be very sure you are working in joules. You'd leave that many grams in the kettle after drying it thoroughly.
m = 38.2 to 3 sig digs.
Answer:
2480 J; 38.2 g
Explanation
Question 1
There are two heat flows in this problem
q = Heat to raise gold to its melting point + heat to melt the gold
q = q₁ + q₂
q = mcΔT + mΔH
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Heat to heat the gold (q₁)
ΔT = T_f – T_i Insert the values
ΔT = 1064 – 26 Do the subtraction
ΔT= 1038 °C Insert values into the formula for q₁
q₁ = 12.4 × 0.1291 × 1038 Do the multiplication
q₁ = 1662 J
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Heat to melt the gold (q₂)
q₂ = 12.4 × 63.5 Do the multiplication
q₂ = 787.4 J
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Total heat required (q)
q = 1662 + 787.4 Do the addition
q = 2450 J (to three significant figures)
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Question 2
q = mCΔT
ΔT = T_f – T_i Insert the values
ΔT = 50.0 – 14.5 Do the subtraction
ΔT= 35.5 °C Insert values into the formula for q
5680 = m × 4.186 × 35.5 Do the multiplication
5680 = m × 148.6 Divide both sides by 148.6
5680/148.6 = m Do the division and switch
m = 38.2 g
