Problem 4: Consider a diffraction grating through which monochromatic light (of unknown wavelength) has a first-ord...
please answer all questions ints) A monochromatic light is passing a diffraction grating. The maximum diffraction order of the maxima observed 3. (15 poi on a screen behind the the screen? diffraction grating is 5. What is the maximum angle at which the first order maxima can be observed on 4. (15 points) (Unpolarized light of an intensity lo passes through three successive Polaroid sheets each of whose axis makes a same angle θ with the preceding ints) A monochromatic...
2. Light of wavelength 545 nm passes through a diffraction grating with 1.35 x103 slits/cm The diffraction pattern is observed on a screen 1.70 cm from the grating. a) Determine the separation distance between the adjacent maxima on the screen. b) A second monochromatic light illuminates the diffraction grating simultancously. The second-order maximum of the second light falls midway between the central maximum and the first-order maximum for the first light on the screen. Determine the wavelength of the second...
Monochromatic light shines on a diffraction grating with 8,600 lines uniformly distributed over 1.8 cm. The grating is illuminated using a laser of 630 nm wavelength. A diffraction pattern is formed on a screen located at 1.7 m away from the grating. (a) What is the angle of the first-order maximum of the 630-nm light incident upon the grating? (b) What is the separation on the screen between the first and the second order maxima? (c) What is the highest...
(15 points) A monochromatic light is passing a diffraction grating. The maximum diffraction order of the maxima observed on a screen behind the diffraction grating is 5. What is the maximum angle at which the first order maxima can be observed on the screen? 3. (15 points) A monochromatic light is passing a diffraction grating. The maximum diffraction order of the maxima observed on a screen behind the diffraction grating is 5. What is the maximum angle at which the...
Problem 3: Suppose light has its second-order maximum at 36.5 when falling ona diffraction grating that has 5000 lines per centimeter. 02-36.5° Calculate the wavelength of the light in nanometers. Numeric A numeric value is expected and not an expression.
Problem 9: A red laser (λ = 608 nm) is incident on a diffraction grating that has n = 1100 lines per cm. Randomized Variables λ = 608 nm n = 1100 lines/cm  Part (a) What is the angle, in radians, that the first order maximum makes, θ1? Numeric : A numeric value is expected and not an expression. θ1 = __________________________________________ Part (b) What is the angle of the fourth order maximum, θ4, in radians? Numeric : A...
In a diffraction experiment, light of 600.nm wavelength produces a first-order maximum 0.350 mm from the central maximum on a distant screen. A second monochromatic source produces a third-order maximum 0.870 mm from the central maximum when it passes through the same diffraction grating. What is the wavelength of the light from the second source?
A diffraction grating with an unknown number of lines per mm, is illuminated by light at a wavelength l = 633 mm, and the first order diffraction pattern is seen at an angle β= 45.OO. Light of a second wavelength is shone on to the grating, whose second order diffraction pattern is seen at l = 62.00. What is the wavelength of the second beam?
A 4.4-cm-wide diffraction grating has 2400 slits. It is illuminated by light of wavelength 530 nm . What is the angle (in degrees) of the first diffraction order? What is the angle (in degrees) of the second diffraction order?
A diffraction grating has 5500 lines/cm . When a beam of monochromatic light goes through it, the second pair of bright spots occurs at ±26.0 cm from the central spot on a screen 43.0 cm past the grating. A. What is the wavelength of this light? B. How far from the central spot does the next pair of bright spots occur on the screen?