X-Rays and Gamma Rays

Given: λ = 0.10 nm = 1.0×10^-10 m

Formula:

1. ν = c/λ = (3.0×10⁸)/(1.0×10^-10) = 3.0×10¹⁸ Hz
2. Check units and write the final result clearly.

Given: h = 6.63×10^-34 J s

Formula:

1. E = hν = 6.63×10^-34 × 5.0×10¹⁸ = 3.315×10^-15 J
2. Check units and write the final result clearly.

Given: Use E(eV)=1240/λ(nm)

Formula:

1. E = 1240/0.124 = 10000 eV = 10 keV
2. Check units and write the final result clearly.

Given: λ_min(nm)=1.24/V(kV)

Formula:

1. λ_min = 1.24/50 = 0.0248 nm
2. Check units and write the final result clearly.

Given: V(kV)=1.24/λ_min(nm)

Formula:

1. V = 1.24/0.031 = 40 kV
2. Check units and write the final result clearly.

Given: 1 MeV = 1.6×10^-13 J

Formula:

1. ν = E/h = (1.6×10^-13)/(6.63×10^-34) = 2.41×10²⁰ Hz
2. Check units and write the final result clearly.

Given: E(eV)=2.0×10⁶ eV

Formula:

1. λ(nm)=1240/E(eV)=1240/(2.0×10⁶)=6.2×10^-4 nm
2. Check units and write the final result clearly.

Given: E = 20000 eV

Formula:

1. λ(nm)=1240/20000=0.062 nm
2. Check units and write the final result clearly.

Given: E(eV)=1240/λ(nm)

Formula:

1. E = 1240/0.05 = 24800 eV = 24.8 keV
2. Check units and write the final result clearly.

Given: V(kV)=1.24/λ(nm)

Formula:

1. V = 1.24/0.01 = 124 kV
2. Check units and write the final result clearly.

Given: λ = c/ν

Formula:

1. λ = (3×10⁸)/(3×10²¹) = 1×10^-13 m
2. Check units and write the final result clearly.

Given: 1 pm = 10^-3 nm

Formula:

1. E(eV)=1240/0.001=1.24×10⁶ eV = 1.24 MeV
2. Check units and write the final result clearly.

Given: E = 8000×1.6×10^-19 J

Formula:

1. ν = E/h = (1.28×10^-15)/(6.63×10^-34) = 1.93×10¹⁸ Hz
2. Check units and write the final result clearly.

Given: λ_min(nm)=1.24/V(kV)

Formula:

1. λ_min = 1.24/100 = 0.0124 nm
2. Check units and write the final result clearly.

Given: E(eV)=1240/λ(nm)

Formula:

1. E = 1240/0.2 = 6200 eV = 6.2 keV
2. Check units and write the final result clearly.

Given: ν = c/λ

Formula:

1. ν = (3×10⁸)/(5×10^-13) = 6×10²⁰ Hz
2. Check units and write the final result clearly.

Given: E=hν

Formula:

1. E = 6.63×10^-34 × 6×10²⁰ = 3.98×10^-13 J
2. Check units and write the final result clearly.

Given: λ_min=hc/eV

Formula:

1. Since λ_min is inversely proportional to V, doubling V halves λ_min.
2. Check units and write the final result clearly.

Given: λ=c/ν

Formula:

1. λ=(3×10⁸)/(1.5×10¹⁸)=2×10^-10 m = 0.20 nm
2. Check units and write the final result clearly.

Given: E=40000 eV

Formula:

1. λ(nm)=1240/40000=0.031 nm
2. Check units and write the final result clearly.

X-rays are high-frequency electromagnetic radiations with short wavelength and high penetrating power.

They are used in medical imaging and crystal structure analysis.

They are used in cancer radiotherapy and sterilisation of medical instruments.

They are ionising radiations and can damage cells and DNA.

Gamma rays are produced during radioactive decay or nuclear transitions.

It is the shortest wavelength in the continuous X-ray spectrum for a given tube voltage.

Correct Option: X-rays

Explanation: X-ray wavelengths are comparable with interatomic spacing, so they produce diffraction.

Correct Option: Accelerating voltage

Explanation: λ_min=hc/eV, so it depends on tube voltage.

Correct Option: Nuclear transitions

Explanation: Gamma photons are emitted when nuclei move from excited to lower energy states.

Correct Option: Gamma rays

Explanation: Gamma rays are at the highest-energy end of the electromagnetic spectrum.

Correct Option: A heavy metal target

Explanation: Sudden deceleration in a tungsten target produces X-rays.

Correct Option: Frequency

Explanation: E=hν.

Correct Option: DNA

Explanation: DNA damage can lead to mutation and cancer risk.

Correct Option: X-rays

Explanation: CT imaging uses many X-ray projections to form cross-sectional images.

Correct Option: 3×10⁸ m s^-1

Explanation: All electromagnetic waves travel with speed c in vacuum.

Correct Option: Increases

Explanation: E=hc/λ.

Correct Option: Kill microorganisms

Explanation: Ionising radiation destroys biological molecules in microbes.

Correct Option: X-rays

Explanation: X-rays reveal density differences inside luggage.

Correct Option: Minimum wavelength

Explanation: No photon can have wavelength shorter than λ_min for a given tube voltage.

Correct Option: Neutral electromagnetic waves

Explanation: Photons have no electric charge.

Correct Option: Tungsten

Explanation: Tungsten has high melting point and high atomic number.

Correct Option: Very short

Explanation: They lie beyond X-rays at the high-frequency end.

Correct Option: Energy absorption and re-emission

Explanation: Materials absorb X-ray energy and emit visible light.

Correct Option: Energy

Explanation: Electron volt measures energy.

Correct Option: Remove electrons from atoms

Explanation: Ionisation creates charged particles.

Correct Option: Minimise time, maximise distance and use shielding

Explanation: These reduce absorbed dose.

An electron accelerated through voltage V gains kinetic energy eV. If all this energy becomes one photon, eV=hc/λ_min. Therefore λ_min=hc/eV.

Incident electrons may lose different fractions of kinetic energy during deceleration at the target. Since photon energy varies, a continuous range of wavelengths is produced.

Inner-shell vacancies are filled by electrons from higher shells. The energy difference depends on nuclear charge and atomic structure, so wavelengths are characteristic of the target element.

Cut-off wavelength decreases because λ_min=hc/eV. Intensity can increase if electron current or power delivered to target increases.

If energies are same, their frequency and wavelength are same. The name difference mainly describes origin: extra-nuclear for X-rays and nuclear for gamma rays.

Their wavelengths are of the order of atomic spacing, so constructive and destructive interference can occur from crystal planes.

They may be absorbed, scattered or transmitted. Absorption depends on density, thickness, atomic number and photon energy.

Most kinetic energy of electrons becomes heat at the target; only a small fraction becomes X-rays.

X-rays are electromagnetic waves and neutral; cathode rays are streams of electrons and are deflected by electric and magnetic fields.

Higher voltage gives electrons greater kinetic energy, allowing photons of higher energy and shorter wavelength.

Yes. The distinction is mainly origin, not only wavelength. X-rays are usually extra-nuclear; gamma rays are nuclear.

The rest mass energy of electron and positron converts into high-energy photons, commonly two gamma photons for momentum conservation.

Hardness means penetrating ability. Hard X-rays have shorter wavelength and higher photon energy.

Inner-shell energy levels depend on atomic number, so transitions produce element-specific photon energies.

No photon can have energy greater than the maximum kinetic energy eV of the incident electron.

They have very short wavelength and high photon energy, so they can pass through soft tissues and many materials.

Gamma rays usually have higher frequency and originate from nuclear transitions, giving them very high photon energies.

Lead has high density and high atomic number, so it absorbs and attenuates ionising radiation effectively.

Characteristic X-rays have definite wavelengths from atomic transitions, while continuous X-rays form a spectrum due to electron deceleration.

Different tissues absorb X-rays by different amounts, creating contrast on a detector or film.

They have very short wavelength and high photon energy, so they can pass through soft tissues and many materials.

Gamma rays usually have higher frequency and originate from nuclear transitions, giving them very high photon energies.

Lead has high density and high atomic number, so it absorbs and attenuates ionising radiation effectively.

Characteristic X-rays have definite wavelengths from atomic transitions, while continuous X-rays form a spectrum due to electron deceleration.

Different tissues absorb X-rays by different amounts, creating contrast on a detector or film.

They have very short wavelength and high photon energy, so they can pass through soft tissues and many materials.

Gamma rays usually have higher frequency and originate from nuclear transitions, giving them very high photon energies.

Lead has high density and high atomic number, so it absorbs and attenuates ionising radiation effectively.

Characteristic X-rays have definite wavelengths from atomic transitions, while continuous X-rays form a spectrum due to electron deceleration.

Different tissues absorb X-rays by different amounts, creating contrast on a detector or film.

They have very short wavelength and high photon energy, so they can pass through soft tissues and many materials.

Gamma rays usually have higher frequency and originate from nuclear transitions, giving them very high photon energies.

Lead has high density and high atomic number, so it absorbs and attenuates ionising radiation effectively.

Characteristic X-rays have definite wavelengths from atomic transitions, while continuous X-rays form a spectrum due to electron deceleration.

Different tissues absorb X-rays by different amounts, creating contrast on a detector or film.