357875 The de Broglie wavelength of an electron moving with a velocity of \(2 \times 10^{8} {~m} {~s}^{-1}\) is equal to that of a photon. Find the ratio of the kinetic energy of the photon to that of the electron.

357876 An electron is 2000 times lighter than a proton. Both are moving such that their matter waves have same wavelength. The ratio of their kinetic energies in approximation is:

357877 An electron of mass \(m\) with an initial velocity \(\overrightarrow v = {v_0}\hat i\left( {{v_0} > 0} \right)\) enters an electric field \(\vec E = - {E_0}\hat i\left( {{E_0} = } \right.\) constant \(\left.>0\right)\) at \(\mathrm{t}=0\). If \(\lambda_{0}\) is its de-Broglie wavelength initially, then its de-Broglie wavelength at time \(t\) is

357878 A proton, an electron and an alpha particle have the same energies. Their de-Broglie wavelengths will be compared as

357875 The de Broglie wavelength of an electron moving with a velocity of \(2 \times 10^{8} {~m} {~s}^{-1}\) is equal to that of a photon. Find the ratio of the kinetic energy of the photon to that of the electron.

357876 An electron is 2000 times lighter than a proton. Both are moving such that their matter waves have same wavelength. The ratio of their kinetic energies in approximation is:

357877 An electron of mass \(m\) with an initial velocity \(\overrightarrow v = {v_0}\hat i\left( {{v_0} > 0} \right)\) enters an electric field \(\vec E = - {E_0}\hat i\left( {{E_0} = } \right.\) constant \(\left.>0\right)\) at \(\mathrm{t}=0\). If \(\lambda_{0}\) is its de-Broglie wavelength initially, then its de-Broglie wavelength at time \(t\) is

357878 A proton, an electron and an alpha particle have the same energies. Their de-Broglie wavelengths will be compared as

357875 The de Broglie wavelength of an electron moving with a velocity of \(2 \times 10^{8} {~m} {~s}^{-1}\) is equal to that of a photon. Find the ratio of the kinetic energy of the photon to that of the electron.

357876 An electron is 2000 times lighter than a proton. Both are moving such that their matter waves have same wavelength. The ratio of their kinetic energies in approximation is:

357877 An electron of mass \(m\) with an initial velocity \(\overrightarrow v = {v_0}\hat i\left( {{v_0} > 0} \right)\) enters an electric field \(\vec E = - {E_0}\hat i\left( {{E_0} = } \right.\) constant \(\left.>0\right)\) at \(\mathrm{t}=0\). If \(\lambda_{0}\) is its de-Broglie wavelength initially, then its de-Broglie wavelength at time \(t\) is

357878 A proton, an electron and an alpha particle have the same energies. Their de-Broglie wavelengths will be compared as

357875 The de Broglie wavelength of an electron moving with a velocity of \(2 \times 10^{8} {~m} {~s}^{-1}\) is equal to that of a photon. Find the ratio of the kinetic energy of the photon to that of the electron.

357876 An electron is 2000 times lighter than a proton. Both are moving such that their matter waves have same wavelength. The ratio of their kinetic energies in approximation is:

357877 An electron of mass \(m\) with an initial velocity \(\overrightarrow v = {v_0}\hat i\left( {{v_0} > 0} \right)\) enters an electric field \(\vec E = - {E_0}\hat i\left( {{E_0} = } \right.\) constant \(\left.>0\right)\) at \(\mathrm{t}=0\). If \(\lambda_{0}\) is its de-Broglie wavelength initially, then its de-Broglie wavelength at time \(t\) is

357878 A proton, an electron and an alpha particle have the same energies. Their de-Broglie wavelengths will be compared as