Can you please answer all questions completely. Refraction, Wave speed and Snell's Law i. A pond...
Example 22.2 Angle of Refraction for Glass Goal Apply Snell's law to a slab of glass. Incident Normal rav Problem A light ray of wavelength 589 nm (produced by a sodium lamp) traveling through air is incident on smooth, flat slab of crown glass at an angle of θ1-35° to the normal, as sketched in Figure 22.11. Find the angle of refraction, θ2. Strategy Substitute quantities into Snell's law and solve for the unknown angle of refraction, θ2. iI Glass...
2. Use Snell's law (n, sin = n, sine,) to explain why , is greater than 0 in Fig. 2. Total Internal Reflection When light passes from a medium of large refractive index into one of small refractive index --- for example, from water to air --- the refracted ray bends away from the surface normal, as shown in Fig. 2. As the angle of incidence increases, the angle of refraction also increases. When the angle of incidence reaches a...
Please answer all questions: 1. What is the speed of light in a medium with a refractive index n=1.31? 2. Consider an interface between air and water (n=1.33). A laser beam is incident from air at an angle of 69.0^oo relative to the interface. At what angle relative to the interface will the ray emerge on the water side?
The index of refraction for fresh water is n water - 1.333. The speed of light in a vacuum is c = 3.00 times 10^8 m/s. What is the speed of light in fresh water? Write the result in terms of 108 m/s. For example if the result is 1.234*108 m/s, just enter 1.234. (keep 3 decimal places) Enter a number x108 m/s Submit (5 attempts remaining) Refraction creates Optical illusion NORMAL line (perpendicular) 2. to water The above figure...
Partner: Date Name 11 Snell's Law Introduction When light passes from one material to another it is always bent away from its original path. This process is known as refraction and the change in direction depends on the change in optical density (or refractive index) of the two materials. A larger change in refractive index results in a larger change in angle between incoming and outgoing light beams. A light beam bends closer to the normal in the material with...
please do table 2. the top page is for website info. only. Part B Lab Go to PhET website. Click on Simulation/Physics. Under Physics, choose Light & Radiation. Under Light & Radiation, Bending Light is the 6th simulation (Location might change. A to Z search.). Click to run the Bending Light/More Tools. Complete Data Table with Bending Light/More Tools Simulation: Basic Operation for More Tools Simulation: Place check marks on Ray, Normal, and Angles. Keep the default setting Material 1...
Part B Lab Go to PhET website. Click on Simulation Physics. Under Physics, choose Light & Radiation. Under Light & Radiation, Bending Light is the 6th simulation (Location might change. A to Z search.) Click to run the Bending Light/More Tools. Complete Data Table with Bending Light/More Tools Simulation: Basic Operation for More Tools Simulation: Place check marks on Ray, Normal, and Angles. Keep the default setting Material 1 (above surface) index of refraction as air = 1.000 and Material...
please do all the questions will full working answers *Question 186: Refraction/Snell's Law The index of refraction of water is 1.33. What is the angle of refraction of a beam of light hitting the water surface at an angle of 30 degrees with the normal and entering the water? Select one: a. 53.1 degrees b. 67.9 degrees c. 22.1 degrees d. 40.6 degrees e. 10.2 degrees *Question 197: Critical Angle A diamond (refractive index 2.46) is placed in water (refractive...
need help. please answer #1 and 2 1. You are looking, from directly above, at a goldfish at the bottom of a 54.0-cm fish tank filled with water. How far away does the fish look to you? The index of refraction of water is 1.34. 2. A beam of light is incident, from air, on a flat surface of glass (n=1.50). The refracted ray inside the glass is found to make an angel of 26.7° with the direction of the...
please answer asap and use Nair=1 Nwater=1.333 and c=3x10^8 m/s 4) Fig. 4 A light ray in water of wavelength 529nm is incident on flat, rectangular piece of transparent plastic (n 1.49) that is floating on a pool of water (n= 1.333). The ray from the water strikes the bottom of the plastic at an angle of 40.0° from the normal line. What happens to the ray when it hits the top edge of the plastic? (give all numeric quantities)...