367721 A single slit of width \(0.20\,mm\) is illustrated with light of wavelength \(500\,nm\). The observing screen is placed \(80\,cm\) from the slit. The width of the central bright fringe will be:

367722 In Fraunhofer diffraction pattern, slit width is \(0.2mm{\rm{ }}\) and screen is at \(2m\) away from the lens. If wavelength of light used is \(5000\mathop A\limits^o \) , then the distance between the first minimum on either side of the central maximum is ( \(\theta \) is small and measured in radiant)

367723 A beam of light of wavelength \(600\,nm\) from a distant source falls on a single slit \(1\,mm\) wide and the resulting diffraction pattern is observed on a screen \(2\,m\) away. The distance between the first dark fringes on either side of the central bright fringe is

367724 In Fraunhofer diffraction the centre of diffraction image is:

367725 Visible light of wavelength \(6000 \times {10^{ - 8}}\,cm\) falls normally on a single slit and produces a diffraction pattern. It is found that the second diffraction minimum is at \(60^{\circ}\) from the central maximum. If the first minimum is produced at \(\theta_{1}\), then \(\theta_{1}\) is close to -

367721 A single slit of width \(0.20\,mm\) is illustrated with light of wavelength \(500\,nm\). The observing screen is placed \(80\,cm\) from the slit. The width of the central bright fringe will be:

367722 In Fraunhofer diffraction pattern, slit width is \(0.2mm{\rm{ }}\) and screen is at \(2m\) away from the lens. If wavelength of light used is \(5000\mathop A\limits^o \) , then the distance between the first minimum on either side of the central maximum is ( \(\theta \) is small and measured in radiant)

367723 A beam of light of wavelength \(600\,nm\) from a distant source falls on a single slit \(1\,mm\) wide and the resulting diffraction pattern is observed on a screen \(2\,m\) away. The distance between the first dark fringes on either side of the central bright fringe is

367724 In Fraunhofer diffraction the centre of diffraction image is:

367725 Visible light of wavelength \(6000 \times {10^{ - 8}}\,cm\) falls normally on a single slit and produces a diffraction pattern. It is found that the second diffraction minimum is at \(60^{\circ}\) from the central maximum. If the first minimum is produced at \(\theta_{1}\), then \(\theta_{1}\) is close to -

367721 A single slit of width \(0.20\,mm\) is illustrated with light of wavelength \(500\,nm\). The observing screen is placed \(80\,cm\) from the slit. The width of the central bright fringe will be:

367722 In Fraunhofer diffraction pattern, slit width is \(0.2mm{\rm{ }}\) and screen is at \(2m\) away from the lens. If wavelength of light used is \(5000\mathop A\limits^o \) , then the distance between the first minimum on either side of the central maximum is ( \(\theta \) is small and measured in radiant)

367723 A beam of light of wavelength \(600\,nm\) from a distant source falls on a single slit \(1\,mm\) wide and the resulting diffraction pattern is observed on a screen \(2\,m\) away. The distance between the first dark fringes on either side of the central bright fringe is

367724 In Fraunhofer diffraction the centre of diffraction image is:

367725 Visible light of wavelength \(6000 \times {10^{ - 8}}\,cm\) falls normally on a single slit and produces a diffraction pattern. It is found that the second diffraction minimum is at \(60^{\circ}\) from the central maximum. If the first minimum is produced at \(\theta_{1}\), then \(\theta_{1}\) is close to -

367721 A single slit of width \(0.20\,mm\) is illustrated with light of wavelength \(500\,nm\). The observing screen is placed \(80\,cm\) from the slit. The width of the central bright fringe will be:

367722 In Fraunhofer diffraction pattern, slit width is \(0.2mm{\rm{ }}\) and screen is at \(2m\) away from the lens. If wavelength of light used is \(5000\mathop A\limits^o \) , then the distance between the first minimum on either side of the central maximum is ( \(\theta \) is small and measured in radiant)

367723 A beam of light of wavelength \(600\,nm\) from a distant source falls on a single slit \(1\,mm\) wide and the resulting diffraction pattern is observed on a screen \(2\,m\) away. The distance between the first dark fringes on either side of the central bright fringe is

367724 In Fraunhofer diffraction the centre of diffraction image is:

367725 Visible light of wavelength \(6000 \times {10^{ - 8}}\,cm\) falls normally on a single slit and produces a diffraction pattern. It is found that the second diffraction minimum is at \(60^{\circ}\) from the central maximum. If the first minimum is produced at \(\theta_{1}\), then \(\theta_{1}\) is close to -

367721 A single slit of width \(0.20\,mm\) is illustrated with light of wavelength \(500\,nm\). The observing screen is placed \(80\,cm\) from the slit. The width of the central bright fringe will be:

367722 In Fraunhofer diffraction pattern, slit width is \(0.2mm{\rm{ }}\) and screen is at \(2m\) away from the lens. If wavelength of light used is \(5000\mathop A\limits^o \) , then the distance between the first minimum on either side of the central maximum is ( \(\theta \) is small and measured in radiant)

367723 A beam of light of wavelength \(600\,nm\) from a distant source falls on a single slit \(1\,mm\) wide and the resulting diffraction pattern is observed on a screen \(2\,m\) away. The distance between the first dark fringes on either side of the central bright fringe is

367724 In Fraunhofer diffraction the centre of diffraction image is:

367725 Visible light of wavelength \(6000 \times {10^{ - 8}}\,cm\) falls normally on a single slit and produces a diffraction pattern. It is found that the second diffraction minimum is at \(60^{\circ}\) from the central maximum. If the first minimum is produced at \(\theta_{1}\), then \(\theta_{1}\) is close to -