In a certain body of water, the attenuation coefficient of blue light is 0.02, and the...

A lake has a light attenuation constant of -0.0798/m (we want to figure out the depth...

A lake has a light attenuation constant of -0.0798/m (we want to figure out the depth at which 60% of the light is attenuated (where 40% of the initial intensity still remains). a) What is this depth in meters? b) How does this depth compare to what you would expect to find in the Chesapeake Bay? c) Would the attenuation coefficient absolute value (remember absolute value ignores positive or negative) go up or down if it were measured in the...

Why does the ocean look blue-green in color, but not a glass of water? A. Because...

Why does the ocean look blue-green in color, but not a glass of water? A. Because all water reflects blue and green light B. Because all water absorbs all red-light C. Water absorbs red-light when there is a large depth of it (~30 meter) D. Water reflects green light if it is shallow

Blue light falling on a double-slit produces interference fringes on a screen. What will happen to...

Blue light falling on a double-slit produces interference fringes on a screen. What will happen to the fringes (closer together, farther apart, remain the same, or no more fringes) if The blue light is replaced by red light? The blue light is replaced by incoherent light? The separation between the slits is decreased? The distance to the screen is decreased? The entire experiment is immersed in water?

A certain kind of glass has an index of refraction of 1.660 for blue light of...

A certain kind of glass has an index of refraction of 1.660 for blue light of wavelength 440 nm and an index of 1.630 for red light of wavelength 690 nm. If a beam containing these two colors is incident at an angle of 30.0° on a piece of this glass, what is the angle between the two beams inside the glass?

A certain kind of glass has an index of refraction of 1.660 for blue light of...

A certain kind of glass has an index of refraction of 1.660 for blue light of wavelength 440 nm and an index of 1.630 for red light of wavelength 690 nm. If a beam containing these two colors is incident at an angle of 30.0° on a piece of this glass, what is the angle between the two beams inside the glass?

Can someone please check 7. A certain kind of glass has nblue= 1.650 for blue light...

Can someone please check 7. A certain kind of glass has nblue= 1.650 for blue light and nred= 1.610 for red light. If a beam of white light (containing all colors) is incident at an angle of 30.0°, what is the angle between the red and blue light inside the glass? a. 0.22° b. 0.45° c. 1.90° d. 1.81° I got B 8. An object is held at a distance of 12 cm from a convex mirror creating an upright...

The dust in an interstellar cloud blocks blue light in the following way: For every 1.00...

The dust in an interstellar cloud blocks blue light in the following way: For every 1.00 pc light travels through the cloud, only 90.1% of the light goes through the cloud. Thus, after 2.00 pc, 90.1% of the remaining 90.1% or 81.2% (0.901 × 0.901 = 0.812) remains. a. You might initially expect that after 15 pc, the total of these 9.9% reductions would have removed all of the blue light. How much blue light actually remains? % b. The...

1. A rectangular piece of acrylic is placed in a tank of water. Blue light (7.5x10​14​Hz)...

1. A rectangular piece of acrylic is placed in a tank of water. Blue light (7.5x10​14​Hz) travels from water to acrylic and then back into water. Calculate its speed and wavelength in each medium. Draw the light in its path from water to acrylic to water, showing the angles of reflection and refraction at each interface if : a. it enters the acrylic making an angle of 60° with the water-acrylic interface (i.e. the angle is measured between the light...

1. A rectangular piece of acrylic is placed in a tank of water. Blue light (7.5x10​14​Hz)...

1. A rectangular piece of acrylic is placed in a tank of water. Blue light (7.5x10​14​Hz) travels from water to acrylic and then back into water. Calculate its speed and wavelength in each medium. Draw the light in its path from water to acrylic to water, showing the angles of reflection and refraction at each interface if : a. it enters the acrylic making an angle of 60° with the water-acrylic interface (i.e. the angle is measured between the light...

A point source of light is 89.6 cm below the surface of a body of water....

A point source of light is 89.6 cm below the surface of a body of water. Find the diameter of the circle at the surface through which light emerges from the water. Water has an index of refraction of 1.33.