368124 In Young's double slit experiment 62 fringes are visible in the field of view with sodium light \(\left( {\lambda = 5893{\rm{ }}\mathop {{\rm{ }}A}\limits^{\;\;^\circ } } \right)\). If green light \(\left( {\lambda = 5461{\rm{ }}\mathop {{\rm{ }}A}\limits^{\;\;^\circ } } \right)\) is used then the number of visible fringes will be-

368125 In Young’s double slit experiment, the slits are \(2{\rm{ }}mm\) apart and are illuminated by photons of two wavelengths \({\lambda _1} = 12000\,\mathop A\limits^ \circ \) and \({\lambda _2} = 10000\,\mathop A\limits^ \circ \) . At what minimum distance from the common central bright fringe on the screen \(2{\rm{ }}m\) from the slit will a bright fringe from one interference pattern coincide with a bright fringe from the other?

368126 In Young’s double slit experiment, two wavelengths \({\lambda _1} = 780\) \(nm\) and \({\lambda _2} = 520\) \(nm\) are used to obtain interference fringes. If the \({n^{th}}\) bright band due to \({\lambda _1}\) coincides with \({(n + 1)^{th}}\) bright band due to \({\lambda _2}{\rm{ }}\) , then the value of \(n\) is

368127 If the 8th bright band due to light of wavelength \(\lambda_{1}\) coincides with 9th bright band from light of wavelength \(\lambda_{2}\) in Young's double slit experiment, then the possible wavelengths of visible light are

368124 In Young's double slit experiment 62 fringes are visible in the field of view with sodium light \(\left( {\lambda = 5893{\rm{ }}\mathop {{\rm{ }}A}\limits^{\;\;^\circ } } \right)\). If green light \(\left( {\lambda = 5461{\rm{ }}\mathop {{\rm{ }}A}\limits^{\;\;^\circ } } \right)\) is used then the number of visible fringes will be-

368125 In Young’s double slit experiment, the slits are \(2{\rm{ }}mm\) apart and are illuminated by photons of two wavelengths \({\lambda _1} = 12000\,\mathop A\limits^ \circ \) and \({\lambda _2} = 10000\,\mathop A\limits^ \circ \) . At what minimum distance from the common central bright fringe on the screen \(2{\rm{ }}m\) from the slit will a bright fringe from one interference pattern coincide with a bright fringe from the other?

368126 In Young’s double slit experiment, two wavelengths \({\lambda _1} = 780\) \(nm\) and \({\lambda _2} = 520\) \(nm\) are used to obtain interference fringes. If the \({n^{th}}\) bright band due to \({\lambda _1}\) coincides with \({(n + 1)^{th}}\) bright band due to \({\lambda _2}{\rm{ }}\) , then the value of \(n\) is

368127 If the 8th bright band due to light of wavelength \(\lambda_{1}\) coincides with 9th bright band from light of wavelength \(\lambda_{2}\) in Young's double slit experiment, then the possible wavelengths of visible light are

368124 In Young's double slit experiment 62 fringes are visible in the field of view with sodium light \(\left( {\lambda = 5893{\rm{ }}\mathop {{\rm{ }}A}\limits^{\;\;^\circ } } \right)\). If green light \(\left( {\lambda = 5461{\rm{ }}\mathop {{\rm{ }}A}\limits^{\;\;^\circ } } \right)\) is used then the number of visible fringes will be-

368125 In Young’s double slit experiment, the slits are \(2{\rm{ }}mm\) apart and are illuminated by photons of two wavelengths \({\lambda _1} = 12000\,\mathop A\limits^ \circ \) and \({\lambda _2} = 10000\,\mathop A\limits^ \circ \) . At what minimum distance from the common central bright fringe on the screen \(2{\rm{ }}m\) from the slit will a bright fringe from one interference pattern coincide with a bright fringe from the other?

368126 In Young’s double slit experiment, two wavelengths \({\lambda _1} = 780\) \(nm\) and \({\lambda _2} = 520\) \(nm\) are used to obtain interference fringes. If the \({n^{th}}\) bright band due to \({\lambda _1}\) coincides with \({(n + 1)^{th}}\) bright band due to \({\lambda _2}{\rm{ }}\) , then the value of \(n\) is

368127 If the 8th bright band due to light of wavelength \(\lambda_{1}\) coincides with 9th bright band from light of wavelength \(\lambda_{2}\) in Young's double slit experiment, then the possible wavelengths of visible light are

368124 In Young's double slit experiment 62 fringes are visible in the field of view with sodium light \(\left( {\lambda = 5893{\rm{ }}\mathop {{\rm{ }}A}\limits^{\;\;^\circ } } \right)\). If green light \(\left( {\lambda = 5461{\rm{ }}\mathop {{\rm{ }}A}\limits^{\;\;^\circ } } \right)\) is used then the number of visible fringes will be-

368125 In Young’s double slit experiment, the slits are \(2{\rm{ }}mm\) apart and are illuminated by photons of two wavelengths \({\lambda _1} = 12000\,\mathop A\limits^ \circ \) and \({\lambda _2} = 10000\,\mathop A\limits^ \circ \) . At what minimum distance from the common central bright fringe on the screen \(2{\rm{ }}m\) from the slit will a bright fringe from one interference pattern coincide with a bright fringe from the other?

368126 In Young’s double slit experiment, two wavelengths \({\lambda _1} = 780\) \(nm\) and \({\lambda _2} = 520\) \(nm\) are used to obtain interference fringes. If the \({n^{th}}\) bright band due to \({\lambda _1}\) coincides with \({(n + 1)^{th}}\) bright band due to \({\lambda _2}{\rm{ }}\) , then the value of \(n\) is

368127 If the 8th bright band due to light of wavelength \(\lambda_{1}\) coincides with 9th bright band from light of wavelength \(\lambda_{2}\) in Young's double slit experiment, then the possible wavelengths of visible light are