### Given Equations
We start with the following system of equations:
1. **\(\alpha^2 = \pi \cdot r_p \cdot R_\infty \cdot \frac{R_H}{R_\infty - R_H}\)**
- This equation relates \(\alpha^2\) to the variables \(r_p\), \(R_\infty\), and \(R_H\).
2. **\(r_p = \frac{2}{\pi R_H} \cdot \left( \frac{v_u}{c} \right)^2\)**
- This equation expresses \(r_p\) in terms of \(R_H\), \(v_u\), and \(c\).
The goal is to solve for \(\alpha\) in terms of \(R_\infty\), \(R_H\), \(v_u\), and \(c\) by eliminating \(r_p\).
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### Solution Process
To find \(\alpha\), we substitute the expression for \(r_p\) from the second equation into the first equation and simplify step-by-step.
#### Step 1: Substitution
- Substitute \(r_p = \frac{2}{\pi R_H} \cdot \left( \frac{v_u}{c} \right)^2\) into the first equation:
\(\alpha^2 = \pi \cdot \left( \frac{2}{\pi R_H} \cdot \left( \frac{v_u}{c} \right)^2 \right) \cdot R_\infty \cdot \frac{R_H}{R_\infty - R_H}\)
#### Step 2: Simplification
- **Cancel the \(\pi\) terms:**
The \(\pi\) in the numerator and denominator cancels out:
\(\alpha^2 = \frac{2}{R_H} \cdot \left( \frac{v_u}{c} \right)^2 \cdot R_\infty \cdot \frac{R_H}{R_\infty - R_H}\)
- **Simplify the \(R_H\) terms:**
The \(R_H\) in the numerator and denominator simplifies:
\(\frac{2}{R_H} \cdot \frac{R_H}{R_\infty - R_H} = \frac{2}{R_\infty - R_H}\)
Thus:
\(\alpha^2 = \frac{2}{R_\infty - R_H} \cdot \left( \frac{v_u}{c} \right)^2 \cdot R_\infty\)
- **Rearrange:**
Rewrite the expression for clarity:
\(\alpha^2 = \frac{2 R_\infty}{R_\infty - R_H} \cdot \left( \frac{v_u}{c} \right)^2\)
#### Step 3: Solve for \(\alpha\)
- Take the square root of both sides:
\(\alpha = \sqrt{ \frac{2 R_\infty}{R_\infty - R_H} \cdot \left( \frac{v_u}{c} \right)^2 }\)
- **Apply the square root property:**
Since \(\sqrt{a \cdot b} = \sqrt{a} \cdot \sqrt{b}\) (for positive \(a\) and \(b\)):
\(\alpha = \sqrt{ \frac{2 R_\infty}{R_\infty - R_H} } \cdot \sqrt{ \left( \frac{v_u}{c} \right)^2 }\)
- **Simplify:**
The square root of the squared term simplifies:
\(\alpha = \sqrt{ \frac{2 R_\infty}{R_\infty - R_H} } \cdot \frac{v_u}{c}\)
- **Alternative form:**
Rearrange for conciseness:
\(\alpha = \frac{v_u}{c} \cdot \sqrt{ \frac{2 R_\infty}{R_\infty - R_H} }\)
This form is clear and expresses \(\alpha\) in terms of the required variables.
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### Final Answer
The solution for \(\alpha\) is:
\(\alpha = \frac{v_u}{c} \sqrt{\frac{2 R_\infty}{R_\infty - R_H}}\)
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### Notes
- The expression assumes \(R_\infty - R_H > 0\) to ensure the denominator is positive and the square root is defined.
- All variables (\(R_\infty\), \(R_H\), \(v_u\), \(c\)) are treated as positive quantities for simplicity, consistent with typical mathematical or physical contexts.
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