The final answer is: $\boxed{\frac{h}{\sqrt{2mK}}}$
The neutral pion $\pi^0$ decays into two photons: $\pi^0 \rightarrow \gamma + \gamma$. If the $\pi^0$ is at rest, what is the energy of each photon? The $\pi^0$ decays into two photons: $\pi^0 \rightarrow \gamma + \gamma$. The mass of the $\pi^0$ is $m_{\pi}c^2 = 135$ MeV. 2: Apply conservation of energy Since the $\pi^0$ is at rest, its total energy is $E_{\pi} = m_{\pi}c^2$. By conservation of energy, $E_{\pi} = E_{\gamma_1} + E_{\gamma_2}$. 3: Apply conservation of momentum The momentum of the $\pi^0$ is zero. By conservation of momentum, $\vec{p} {\gamma_1} + \vec{p} {\gamma_2} = 0$. 4: Solve for the photon energies Since the photons have equal and opposite momenta, they must have equal energies: $E_{\gamma_1} = E_{\gamma_2}$. Therefore, $E_{\gamma_1} = E_{\gamma_2} = \frac{1}{2}m_{\pi}c^2 = 67.5$ MeV.
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Verify that the mass defect of the deuteron $\Delta M_d$ is approximately 2.2 MeV. The mass defect $\Delta M_d$ of the deuteron is given by $\Delta M_d = M_p + M_n - M_d$, where $M_p$, $M_n$, and $M_d$ are the masses of the proton, neutron, and deuteron, respectively. Step 2: Find the masses of the particles The masses of the particles are approximately: $M_p = 938.27$ MeV, $M_n = 939.57$ MeV, and $M_d = 1875.61$ MeV. Step 3: Calculate the mass defect $\Delta M_d = M_p + M_n - M_d = 938.27 + 939.57 - 1875.61 = 2.23$ MeV. Step 4: Compare with the given value The calculated value of $\Delta M_d \approx 2.23$ MeV is approximately equal to 2.2 MeV.
The final answer is: $\boxed{2.2}$
The final answer is: $\boxed{\frac{h}{\sqrt{2mK}}}$
The neutral pion $\pi^0$ decays into two photons: $\pi^0 \rightarrow \gamma + \gamma$. If the $\pi^0$ is at rest, what is the energy of each photon? The $\pi^0$ decays into two photons: $\pi^0 \rightarrow \gamma + \gamma$. The mass of the $\pi^0$ is $m_{\pi}c^2 = 135$ MeV. 2: Apply conservation of energy Since the $\pi^0$ is at rest, its total energy is $E_{\pi} = m_{\pi}c^2$. By conservation of energy, $E_{\pi} = E_{\gamma_1} + E_{\gamma_2}$. 3: Apply conservation of momentum The momentum of the $\pi^0$ is zero. By conservation of momentum, $\vec{p} {\gamma_1} + \vec{p} {\gamma_2} = 0$. 4: Solve for the photon energies Since the photons have equal and opposite momenta, they must have equal energies: $E_{\gamma_1} = E_{\gamma_2}$. Therefore, $E_{\gamma_1} = E_{\gamma_2} = \frac{1}{2}m_{\pi}c^2 = 67.5$ MeV. The mass of the $\pi^0$ is $m_{\pi}c^2 = 135$ MeV
If you need help with something else or any modifications to the current problems let me know! 3: Apply conservation of momentum The momentum of
Let me know if you want me to generate more problems! $M_n = 939.57$ MeV
Verify that the mass defect of the deuteron $\Delta M_d$ is approximately 2.2 MeV. The mass defect $\Delta M_d$ of the deuteron is given by $\Delta M_d = M_p + M_n - M_d$, where $M_p$, $M_n$, and $M_d$ are the masses of the proton, neutron, and deuteron, respectively. Step 2: Find the masses of the particles The masses of the particles are approximately: $M_p = 938.27$ MeV, $M_n = 939.57$ MeV, and $M_d = 1875.61$ MeV. Step 3: Calculate the mass defect $\Delta M_d = M_p + M_n - M_d = 938.27 + 939.57 - 1875.61 = 2.23$ MeV. Step 4: Compare with the given value The calculated value of $\Delta M_d \approx 2.23$ MeV is approximately equal to 2.2 MeV.
The final answer is: $\boxed{2.2}$