Let \( z_1 \) and \( z_2 \) be two complex numbers such that \( z_1 + z_2 = 5 \) and \( z_1^3 + z_2^3 = 20 + 15i \). Then \( \left| z_1^4 + z_2^4 \right| \) equals
- \( 30 \sqrt{3} \)
- \( 75 \)
- \( 15 \sqrt{15} \)
- \( 25 \sqrt{3} \)
The Correct Option is B
Approach Solution - 1
To solve this problem, we need to determine the magnitude of \( |z_1^4 + z_2^4| \) given the conditions \( z_1 + z_2 = 5 \) and \( z_1^3 + z_2^3 = 20 + 15i \).
First, recall the identity for the sum of cubes:
\(z_1^3 + z_2^3 = (z_1 + z_2)(z_1^2 - z_1z_2 + z_2^2)\)
Substituting \(z_1 + z_2 = 5\), we get:
\(20 + 15i = 5(z_1^2 - z_1z_2 + z_2^2)\)
Therefore,
\(z_1^2 - z_1z_2 + z_2^2 = 4 + 3i\)
Also, from the identity \((z_1 + z_2)^2 = z_1^2 + 2z_1z_2 + z_2^2\), we have:
\(25 = z_1^2 + 2z_1z_2 + z_2^2\)
Let's subtract these results:
\(25 - (4 + 3i) = z_1^2 + 2z_1z_2 + z_2^2 - (z_1^2 - z_1z_2 + z_2^2)\)
This simplifies to:
\(21 - 3i = 3z_1z_2\)
Thus,
\(z_1z_2 = 7 - i\)
Now, let's use the identity for the sum of fourth powers:
\(z_1^4 + z_2^4 = (z_1^2 + z_2^2)^2 - 2(z_1z_2)^2\)
We already know:
\(z_1^2 + z_2^2 = 4 + 3i + z_1z_2 = 4 + 3i + (7 - i) = 11 + 2i\)
Now compute \((z_1^2 + z_2^2)^2\):
\((11 + 2i)^2 = 121 + 44i + 4i^2 = 121 + 44i -4 = 117 + 44i\)
Next, compute \(2(z_1z_2)^2\):
\((z_1z_2)^2 = (7 - i)^2 = 49 - 14i + i^2 = 49 - 14i - 1 = 48 - 14i\)
Therefore,
\(2(z_1z_2)^2 = 2(48 - 14i) = 96 - 28i\)
Substitute back,
\(z_1^4 + z_2^4 = (117 + 44i) - (96 - 28i) = 21 + 72i\)
We need the magnitude:
\(\left|z_1^4 + z_2^4\right| = \sqrt{21^2 + 72^2} = \sqrt{441 + 5184} = \sqrt{5625} = 75\)
Thus, the answer is \( 75 \).
Approach Solution -2
Given:
\[ z_1 + z_2 = 5 \quad \text{and} \quad z_1^3 + z_2^3 = 20 + 15i \]
Let \( S = z_1 + z_2 \) and \( P = z_1 z_2 \). We know that:
\[ S = 5 \]
Using the identity for the sum of cubes:
\[ z_1^3 + z_2^3 = (z_1 + z_2)\left(z_1^2 - z_1 z_2 + z_2^2\right) \]
Since \( z_1^2 + z_2^2 = S^2 - 2P \), we can write:
\[ z_1^3 + z_2^3 = S(S^2 - 3P) = 20 + 15i \]
Substitute \( S = 5 \):
\[ 5(25 - 3P) = 20 + 15i \]
Solving for \( P \), we get:
\[ 125 - 15P = 20 + 15i \] \[ 15P = 105 - 15i \] \[ P = 7 - i \]
Now we need to find \( z_1^4 + z_2^4 \). Using the identity:
\[ z_1^4 + z_2^4 = (z_1^2 + z_2^2)^2 - 2(z_1 z_2)^2 \]
Since \( z_1^2 + z_2^2 = S^2 - 2P \), we have:
\[ z_1^2 + z_2^2 = 5^2 - 2(7 - i) = 25 - 14 + 2i = 11 + 2i \]
Now, square \( z_1^2 + z_2^2 \):
\[ (z_1^2 + z_2^2)^2 = (11 + 2i)^2 = 121 + 44i + 4i^2 = 121 + 44i - 4 = 117 + 44i \]
Next, calculate \( (z_1 z_2)^2 \):
\[ (z_1 z_2)^2 = (7 - i)^2 = 49 - 14i + i^2 = 49 - 14i - 1 = 48 - 14i \]
Thus,
\[ z_1^4 + z_2^4 = (117 + 44i) - 2(48 - 14i) \] \[ = 117 + 44i - 96 + 28i \] \[ = 21 + 72i \]
Finally, we find \( |z_1^4 + z_2^4| \):
\[ |z_1^4 + z_2^4| = \sqrt{21^2 + 72^2} = \sqrt{441 + 5184} = \sqrt{5625} = 75 \]
The answer is: 75
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