A laser beam is incident on two slits with separation d = 0.032 mm. A screen is placed L = 3.8 m from the slits. The wavelength of the laser light is λ = 5250 Å. θ1 and θ2 are the angles to the first and second bright fringes above the center of the screen Part (a) Express sin(θ1) in terms of d and λ. sin(θ1) =? Part (b) Express sin(θ2) in terms of d and λ. sin(θ2) = ? Part (c) Express the distance between the two bright fringes on the screen, y, in terms of θ1, θ2 and L. y =? Part (d) Solve for the numerical value of y in meters. y =?

A laser beam is incident on two slits with separation d = 0.032 mm. A screen is placed L = 3.8 m from the slits. The wavelength of the laser light is λ = 5250 Å. θ1 and θ2 are the angles to the first and second bright fringes above the center of the screen Part (a) Express sin(θ1) in terms of d and λ. sin(θ1) =? Part (b) Express sin(θ2) in terms of d and λ. sin(θ2) = ? Part (c) Express the distance between the two bright fringes on the screen, y, in terms of θ1, θ2 and L. y =? Part (d) Solve for the numerical value of y in meters. y =?

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Question

A laser beam is incident on two slits with separation d = 0.032 mm. A screen is placed L = 3.8 m from the slits. The wavelength of the laser light is λ = 5250 Å. θ₁ and θ₂ are the angles to the first and second bright fringes above the center of the screen

Part (a) Express sin(θ₁) in terms of d and λ.

sin(θ₁) =?

Part (b) Express sin(θ₂) in terms of d and λ.

sin(θ₂) = ?

Part (c) Express the distance between the two bright fringes on the screen, y, in terms of θ₁, θ₂ and L.

y =?

Part (d) Solve for the numerical value of y in meters.

y =?