283149 A graph is plotted between the fringe-width(z) and the distance (D) between the slit and eyepiece, keeping other adjustment same. The correct graph is

283150 A double slit experiment is immersed in water of refractive index 1.33. The slits separation is 1 \(\mathrm{mm}\), distance between slit and screen is \(1.33 \mathrm{~m}\). The slits are illuminated by a light of wavelength \(6300 \AA\). The fringe width is

283151 In Young's double slit experiment, the \(6^{\text {th }}\) maximum with wavelength ' \(\lambda_1\) ' is at a distance ' \(d_1\) ' from the central maximum and the \(4^{\text {th }}\) maximum with wavelength \(\lambda_2\) is at distance \(d_2\). Then \(\frac{d_1}{d_2}\) is.

283152 The Young's double-slit experiment is performed with the light of blue colour \(\left(\lambda_b=4350 \AA\right)\) and then with green colour \(\left(\lambda_{\mathrm{g}}=5450 \AA\right)\). Without changing experimental setup, if the distance of the sixth fringe from the centre is determined for both the colours as \(\mathbf{X}_{\text {blue }}\) and \(\mathbf{X}_{\text {green }}\), then \(\mathbf{X}_{\text {blue }}\) : \(\mathbf{X}_{\text {green }}\) is nearly

283149 A graph is plotted between the fringe-width(z) and the distance (D) between the slit and eyepiece, keeping other adjustment same. The correct graph is

283150 A double slit experiment is immersed in water of refractive index 1.33. The slits separation is 1 \(\mathrm{mm}\), distance between slit and screen is \(1.33 \mathrm{~m}\). The slits are illuminated by a light of wavelength \(6300 \AA\). The fringe width is

283151 In Young's double slit experiment, the \(6^{\text {th }}\) maximum with wavelength ' \(\lambda_1\) ' is at a distance ' \(d_1\) ' from the central maximum and the \(4^{\text {th }}\) maximum with wavelength \(\lambda_2\) is at distance \(d_2\). Then \(\frac{d_1}{d_2}\) is.

283152 The Young's double-slit experiment is performed with the light of blue colour \(\left(\lambda_b=4350 \AA\right)\) and then with green colour \(\left(\lambda_{\mathrm{g}}=5450 \AA\right)\). Without changing experimental setup, if the distance of the sixth fringe from the centre is determined for both the colours as \(\mathbf{X}_{\text {blue }}\) and \(\mathbf{X}_{\text {green }}\), then \(\mathbf{X}_{\text {blue }}\) : \(\mathbf{X}_{\text {green }}\) is nearly

283149 A graph is plotted between the fringe-width(z) and the distance (D) between the slit and eyepiece, keeping other adjustment same. The correct graph is

283150 A double slit experiment is immersed in water of refractive index 1.33. The slits separation is 1 \(\mathrm{mm}\), distance between slit and screen is \(1.33 \mathrm{~m}\). The slits are illuminated by a light of wavelength \(6300 \AA\). The fringe width is

283151 In Young's double slit experiment, the \(6^{\text {th }}\) maximum with wavelength ' \(\lambda_1\) ' is at a distance ' \(d_1\) ' from the central maximum and the \(4^{\text {th }}\) maximum with wavelength \(\lambda_2\) is at distance \(d_2\). Then \(\frac{d_1}{d_2}\) is.

283152 The Young's double-slit experiment is performed with the light of blue colour \(\left(\lambda_b=4350 \AA\right)\) and then with green colour \(\left(\lambda_{\mathrm{g}}=5450 \AA\right)\). Without changing experimental setup, if the distance of the sixth fringe from the centre is determined for both the colours as \(\mathbf{X}_{\text {blue }}\) and \(\mathbf{X}_{\text {green }}\), then \(\mathbf{X}_{\text {blue }}\) : \(\mathbf{X}_{\text {green }}\) is nearly

283149 A graph is plotted between the fringe-width(z) and the distance (D) between the slit and eyepiece, keeping other adjustment same. The correct graph is

283150 A double slit experiment is immersed in water of refractive index 1.33. The slits separation is 1 \(\mathrm{mm}\), distance between slit and screen is \(1.33 \mathrm{~m}\). The slits are illuminated by a light of wavelength \(6300 \AA\). The fringe width is

283151 In Young's double slit experiment, the \(6^{\text {th }}\) maximum with wavelength ' \(\lambda_1\) ' is at a distance ' \(d_1\) ' from the central maximum and the \(4^{\text {th }}\) maximum with wavelength \(\lambda_2\) is at distance \(d_2\). Then \(\frac{d_1}{d_2}\) is.

283152 The Young's double-slit experiment is performed with the light of blue colour \(\left(\lambda_b=4350 \AA\right)\) and then with green colour \(\left(\lambda_{\mathrm{g}}=5450 \AA\right)\). Without changing experimental setup, if the distance of the sixth fringe from the centre is determined for both the colours as \(\mathbf{X}_{\text {blue }}\) and \(\mathbf{X}_{\text {green }}\), then \(\mathbf{X}_{\text {blue }}\) : \(\mathbf{X}_{\text {green }}\) is nearly