Building contractors often install double-glazed windows to prevent thermal energy (heat) from entering or exiting a building. In addition to being effective insulators, such windows present interesting optical effects.

In the figure, a double-glazed window consists of two identical panes of glass ( g=1.50 ), each g=42.0 mm thick, separated by an air gap of a=33.6 mm . If light incident on the glass makes an angle of =40.00∘ with respect to the glass, find the shift in path Δ as the light enters the room. Use a=1.00 for the index of refraction of air.

Two parallel, horizontal rectangular regions representing glass panes, separated by an open rectangular region representing the air gap between the glass. The thickness of each glass pane is y subscript g. The thickness of the air gap is y subscript a. A light ray is incident upon the upper glass pane, and makes an angle phi with respect to the glass surface. The ray bends downward toward the normal at the air-glass boundary. The ray passes through the glass and strikes the bottom glass-air boundary, where it bends away from the normal and enters the air gap. The beam continues to the second glass sheet, where it once again bends toward the normal at the air-glass boundary. The ray passes through the second sheet and again bends away from the normal at the glass-air boundary. The ray that emerges from the second sheet propagates parallel to a straight line extending the trajectory of the ray incident on the first glass sheet, and is a perpendicular distance delta x away from it.
Δ=
mm

Let's analyze this exercise we can calculate the lateral displacement formed by the displacement of the glass plate plus the displacement in the part of air between the glasses.

x_total = d₁ - d₂ + d₃

The sign of displacement in the air is because it reduces lateral displacement.

Let's use the law of refraction to find the angle refracted in the glass, which will determine the displacement

n₁ sin θ₁ = n₂ sin θ₂

where subscript 1 is for the indicating part and subscript 2 for the refracted part (glass)

sin θ₂ = n₁ /n₂ sin θ₁

sin θ₂ = 1 /n_g sin θ₁

for the specific case

sin θ₂ = 1 /1.5 sin 40

θ₂ = sin⁻¹ (0.4285)

θ₂ = 25.37º

so the lateral displacement when exiting the plate is

tan θ₂ = d₁ / y_g

d₁ = y_g tan 25.37

d₁ = 4.20 so 25.37

d₁ = 1.99 cm

when the ray leaves glass and enters the air, it will recover its initial direction, therefore the angle is θ = 40º, the displacement for this part is

tan θ = d₂ / y_a

d₂ = y_a sin θ

suppose that the width is equal to the thickness of the glass y_a = 4.20 cm

d₂ = 4.20 tan 40

d₂ = 3.52 cm

At this time it enters the second glass plate, we see that it is identical to the analysis of the first plate. So the displacement is

d₃ = y_g tan 25.37

d₃ = 4.2 tan 2537

d₃ = 1.99 cm

consequently the total displacement is

general fromula

x_total = 2 y_g tan 25.37 - y_a tan 40

The offset for the given values is

x_total = 1.99 - 3.52 + 1.99

x_total = 0.46 cm

poojatomarb76 poojatomarb76 · Answer 2 · 2022-04-09T12:07:02+02:00

The perpendicular distance delta x away from it will be 0.46 cm.

What is the law of refraction?

The incident ray refracted ray, and normal to the interface of two media at the moment of incidence all lie on the same plane,

According to refraction laws. A constant is the ratio of the sine of the angle of incidence to the sine of the angle of refraction. Snell's law of refraction is another name for this.

Let's look at this activity in more detail. We can compute the lateral displacement created by the displacement of the glass plate plus the displacement of the air between the glasses.

[tex]\rm x_{total} = d_1 - d_2 + d_3[/tex]

Because it lowers lateral displacement, displacement in the air is an indication. To compute the displacement, we'll utilize the law of refraction to determine the angle refracted in the glass.

[tex]\rm n_1 sin \theta_1 = n_2 sin \theta_2[/tex]

[tex]sin \theta_2 = \frac{n_1}{n_2} sin \theta_1[/tex]

[tex]\rm sin \theta_2 = \frac{1}{15} sin 40^0 \\\\ \theta_2 = sin^{-1}(0.4285) \\\\\ sin \theta_2 =25.37 ^0[/tex]

As a result, while departing the plate, the lateral displacement is;

[tex]tan \theta_2 = \frac{d_1}{y_g} \\\\\ d_1 = y_g tan 25.37^0 \\\\\ d_1 = 4.20 cos 25.37^0 \\\\ d_1= 1.99 cm[/tex]

The ray will revert to its original orientation when it exits the glass and enters the air, therefore the angle is = 40° and the displacement for this section is

[tex]\rm tan = \frac{d_s}{y_a} \\\\\ d_s = y_a sin \theta \\\\[/tex]

Assume that the breadth of the glass is equal to its thickness, y a = 4.20 cm.

[tex]\rm d_2 = 4.20 tan 40^0\\\\ d_2 = 3.52 cm[/tex]

When it reaches the second glass plate, we notice that the analysis is identical to the first plate's. As a result, the displacement

[tex]\rm d_3 = y_g tan 25.37^0\\\\ d_3 = 4.2 tan 2537 \\\\\ d_3 = 1.99 cm[/tex]

Consequently, the total displacement will be;

[tex]\rm x_{total} = 2 y_g tan 25.37^0 - y_a tan 40^0[/tex]

[tex]x_{total} = 1.99 - 3.52 + 1.99\\\\ x_{tota}l = 0.46 \ cm[/tex]

Hence the perpendicular distance delta x away from it will be 0.46 cm.

To learn more about the law of refraction refer to the link;

https://brainly.com/question/13879937