Input interpretation
![kinetic energy of particle | incident particle | e^- (electron) radiation absorber | xenon thickness | 20 cm](../image_source/8df750071c4a0ce4523f998e26239ec9.png)
kinetic energy of particle | incident particle | e^- (electron) radiation absorber | xenon thickness | 20 cm
Result
![0.26 MeV (megaelectronvolts)](../image_source/8bee37977153f3319f2265e9935131cb.png)
0.26 MeV (megaelectronvolts)
Comparison as energy for 0.26 MeV
![≈ 0.5 × mass-energy of an electron ( 1 m_e c^2 )](../image_source/ce91e0eb77e54b684c378f121db3d60d.png)
≈ 0.5 × mass-energy of an electron ( 1 m_e c^2 )
![≈ 2.1 × average energy of a gamma ray photon ( ≈ 2×10^-14 J )](../image_source/e8559631e1f2ad7e438bf36c29ec3442.png)
≈ 2.1 × average energy of a gamma ray photon ( ≈ 2×10^-14 J )
![≈ (2 to 2000) × energy of an X-ray photon ( 1×10^-17 to 2×10^-14 J )](../image_source/5e88c6f6bc35613d88b259e113ce37b5.png)
≈ (2 to 2000) × energy of an X-ray photon ( 1×10^-17 to 2×10^-14 J )
Properties
![shielding thickness | 20 cm CSDA range | 0.118 g/cm^2 stopping power | 1.47 MeV/(g/cm^2) collision stopping power | 1.43 MeV/(g/cm^2) radiative stopping power | 0.0384 MeV/(g/cm^2) radiation yield | 0.015 density effect parameter | 0](../image_source/86e312c7caa286feeb11a172dadc4c11.png)
shielding thickness | 20 cm CSDA range | 0.118 g/cm^2 stopping power | 1.47 MeV/(g/cm^2) collision stopping power | 1.43 MeV/(g/cm^2) radiative stopping power | 0.0384 MeV/(g/cm^2) radiation yield | 0.015 density effect parameter | 0
Range versus energy
![Range versus energy](../image_source/986d592f5e539ee9e1cdea1b06d4d701.png)
Range versus energy
Radiation yield versus energy
![Range versus energy Radiation yield versus energy](../image_source/7c1554db01a4c11a6335aa9b5670f6b0.png)
Range versus energy Radiation yield versus energy
Density effect parameter versus energy
![Range versus energy Density effect parameter versus energy](../image_source/abfac2f1faaeffaf2d1ab8e86f622564.png)
Range versus energy Density effect parameter versus energy
Stopping power versus energy
![Stopping power versus energy](../image_source/cd5230886a35d6c76af31a1a0a576b8e.png)
Stopping power versus energy
Absorber material properties
![atomic number (Z) | 54 atomic mass number (A) | 131.293 〈Z/A〉 | 0.41129 nuclear collision length (λ_T) | 100.8 g/cm^2 nuclear interaction length (λ_I) | 172.1 g/cm^2 radiation length (X_0) | 8.48 g/cm^2 minimum ionization (- dE/ dx |_ min) | 1.255 MeV/(g/cm^2) (at 20 °C and 1 atm) density | 5.9 g/L (at 0 °C) mean excitation energy | 482 eV Molière radius | 14.63 g/cm^2 pion collision length | 125 g/cm^2 pion interaction length | 199.6 g/cm^2 plasma energy | 1.37 eV](../image_source/e07c6310e81b19b2436d402c344c6dc8.png)
atomic number (Z) | 54 atomic mass number (A) | 131.293 〈Z/A〉 | 0.41129 nuclear collision length (λ_T) | 100.8 g/cm^2 nuclear interaction length (λ_I) | 172.1 g/cm^2 radiation length (X_0) | 8.48 g/cm^2 minimum ionization (- dE/ dx |_ min) | 1.255 MeV/(g/cm^2) (at 20 °C and 1 atm) density | 5.9 g/L (at 0 °C) mean excitation energy | 482 eV Molière radius | 14.63 g/cm^2 pion collision length | 125 g/cm^2 pion interaction length | 199.6 g/cm^2 plasma energy | 1.37 eV