Q.59 An X-ray tube operates at 30 kV. If one electron converts 10% of its energy into a photon at first collision, then the wavelength of the photon (correct to two decimal places) is _______ Å.
[h = 4.14 × 10⁻¹⁵ eV·s, c = 3 × 10⁸ m s⁻¹ and e = 1.6 × 10⁻¹⁹ C]

Problem Analysis

Electrons in the X-ray tube gain kinetic energy from acceleration through 30 kV, calculated as E = eV = (1.6×10^-19 C) × (30×10³ V) = 4.8×10^-15 J, or directly 30,000 eV since energy in eV equals accelerating voltage in volts . At first collision, 10% converts to photon energy: E_γ = 0.1 × 30,000 = 3,000 eV .

Wavelength Calculation

Photon energy relates to wavelength by E_γ = hc/λ, so λ = hc/E_γ. Using h = 4.14×10^-15 eV·s, c = 3×10⁸ m/s, hc = 1.242×10^-6 eV·pm . Thus, λ = 1.242×10^-6/3,000 = 4.14×10^-10 m = 4.14 Å (1 Å = 10^-10 m) .

Step-by-Step Derivation

• Compute electron energy: 30 keV.
• Photon energy: 0.1 × 30 keV = 3 keV.
• hc product: 4.14×10^-15 × 3×10⁸ = 1.242×10^-6 eV·pm.
• λ in meters: 4.14×10^-10 m.
• Convert: 4.14 Å, correct to two decimal places.

No options provided; this is a numerical fill-in for CSIR NET-style exams .

Core Concept: Bremsstrahlung in X-Ray Production

In an X-ray tube, electrons accelerate through 30 kV, gaining 30 keV kinetic energy (E = eV). Partial energy loss (here 10%) during target collision produces photons via bremsstrahlung, unlike minimum wavelength cases using full energy [web:6][web:9]. Photon energy E_γ = 0.1 × 30,000 = 3,000 eV.

Parameters Table

Common Mistakes and Exam Tips

Avoid confusing with minimum wavelength λ_min = hc/eV (would be 0.414 Å for full 30 kV) [web:4][web:5]. Use eV units consistently; given h is in eV·s simplifies to voltage directly. For CSIR NET, verify units (m to Å) and precision.

Applications in Modern Physics

This X-ray tube wavelength 30 kV 10% energy scenario models diagnostic X-rays and material analysis, linking quantum mechanics to practical tech. Practice variations like 70% conversion (as in 40 kV problems) builds mastery.