368137 In Young's double slit experiment, the wavelength of red light is \(7800\) \( \mathop A^{~~\circ} \) and that of blue light is \(5200\) \( \mathop A^{~~\circ} \). The value of \({n}\) for which \({n^{\text {th }}}\) bright band due to red light coincides with \({(n+1)^{\text {th }}}\) bright band due to blue light, is
368138 In Young’s double slit experiment, slits are separated by \(2\,mm\) and the screen is placed at a distance of \(1.2\,m\) from the slits. Light consisting of two wavelengths \(6500A^\circ \) and \(5200A^\circ \) are used to obtain interference fringes. Then the separation between the fourth bright fringes of two different patterns produced by the two wavelengths is
368139 The Young's double slit experiment is performed with blue and green light of wavelengths \(4360\,\mathop {{\rm{ }}A}\limits^{\;\;^\circ } \) and \(5460\,\mathop {{\rm{ }}A}\limits^{\;\;^\circ } \) respectively. If \(x\) is the distance of 4th maxima from the central one, then
368137 In Young's double slit experiment, the wavelength of red light is \(7800\) \( \mathop A^{~~\circ} \) and that of blue light is \(5200\) \( \mathop A^{~~\circ} \). The value of \({n}\) for which \({n^{\text {th }}}\) bright band due to red light coincides with \({(n+1)^{\text {th }}}\) bright band due to blue light, is
368138 In Young’s double slit experiment, slits are separated by \(2\,mm\) and the screen is placed at a distance of \(1.2\,m\) from the slits. Light consisting of two wavelengths \(6500A^\circ \) and \(5200A^\circ \) are used to obtain interference fringes. Then the separation between the fourth bright fringes of two different patterns produced by the two wavelengths is
368139 The Young's double slit experiment is performed with blue and green light of wavelengths \(4360\,\mathop {{\rm{ }}A}\limits^{\;\;^\circ } \) and \(5460\,\mathop {{\rm{ }}A}\limits^{\;\;^\circ } \) respectively. If \(x\) is the distance of 4th maxima from the central one, then
368137 In Young's double slit experiment, the wavelength of red light is \(7800\) \( \mathop A^{~~\circ} \) and that of blue light is \(5200\) \( \mathop A^{~~\circ} \). The value of \({n}\) for which \({n^{\text {th }}}\) bright band due to red light coincides with \({(n+1)^{\text {th }}}\) bright band due to blue light, is
368138 In Young’s double slit experiment, slits are separated by \(2\,mm\) and the screen is placed at a distance of \(1.2\,m\) from the slits. Light consisting of two wavelengths \(6500A^\circ \) and \(5200A^\circ \) are used to obtain interference fringes. Then the separation between the fourth bright fringes of two different patterns produced by the two wavelengths is
368139 The Young's double slit experiment is performed with blue and green light of wavelengths \(4360\,\mathop {{\rm{ }}A}\limits^{\;\;^\circ } \) and \(5460\,\mathop {{\rm{ }}A}\limits^{\;\;^\circ } \) respectively. If \(x\) is the distance of 4th maxima from the central one, then
368137 In Young's double slit experiment, the wavelength of red light is \(7800\) \( \mathop A^{~~\circ} \) and that of blue light is \(5200\) \( \mathop A^{~~\circ} \). The value of \({n}\) for which \({n^{\text {th }}}\) bright band due to red light coincides with \({(n+1)^{\text {th }}}\) bright band due to blue light, is
368138 In Young’s double slit experiment, slits are separated by \(2\,mm\) and the screen is placed at a distance of \(1.2\,m\) from the slits. Light consisting of two wavelengths \(6500A^\circ \) and \(5200A^\circ \) are used to obtain interference fringes. Then the separation between the fourth bright fringes of two different patterns produced by the two wavelengths is
368139 The Young's double slit experiment is performed with blue and green light of wavelengths \(4360\,\mathop {{\rm{ }}A}\limits^{\;\;^\circ } \) and \(5460\,\mathop {{\rm{ }}A}\limits^{\;\;^\circ } \) respectively. If \(x\) is the distance of 4th maxima from the central one, then