(1) \( 2^{2 x}=2^{2}\left(2^{x}+8\right) \)

To solve the equation: \[ 2^{2x} = 2^{2}\left(2^{x} + 8\right) \] let's follow these steps: ### Step 1: Simplify the Equation First, recognize that \(2^{2x}\) can be rewritten as \((2^{x})^{2}\): \[ (2^{x})^{2} = 2^{2} \left(2^{x} + 8\right) \] ### Step 2: Substitute for Simplification Let’s make a substitution to simplify the equation. Let: \[ y = 2^{x} \] The equation becomes: \[ y^{2} = 4(y + 8) \] ### Step 3: Rearrange the Equation Bring all terms to one side to form a quadratic equation: \[ y^{2} - 4y - 32 = 0 \] ### Step 4: Solve the Quadratic Equation Use the quadratic formula to solve for \(y\): \[ y = \frac{4 \pm \sqrt{(-4)^2 - 4 \cdot 1 \cdot (-32)}}{2 \cdot 1} \] \[ y = \frac{4 \pm \sqrt{16 + 128}}{2} \] \[ y = \frac{4 \pm \sqrt{144}}{2} \] \[ y = \frac{4 \pm 12}{2} \] This gives two possible solutions: 1. \( y = \frac{4 + 12}{2} = \frac{16}{2} = 8 \) 2. \( y = \frac{4 - 12}{2} = \frac{-8}{2} = -4 \) ### Step 5: Consider the Validity of Solutions Since \( y = 2^{x} \) and any exponential expression with base 2 is always positive, \( y = -4 \) is not a valid solution. Therefore, we have: \[ y = 8 \] ### Step 6: Solve for \( x \) Recall that \( y = 2^{x} \): \[ 2^{x} = 8 \] Since \( 8 = 2^{3} \), we have: \[ 2^{x} = 2^{3} \implies x = 3 \] ### Conclusion The solution to the equation is: \[ \boxed{3} \]