Please help with this 4 part question Light with wavelength = 700.0000nm is incident on a...
Red light has a longer wavelength than blue light. Both red light and blue light are sent through a "double slit" with small slit spacing. The relative position of the first order constructive interference fringe for red light is (larger/smaller/same) as the position for blue light. As the slit is increased in size--what happens to the first order constructive fringe position for red light (increases/decreases/same)?, and for blue light increases/decreases/same)? Same, Same, Same Larger, decreases, decreases Smaller, decreases, decreases Smaller,...
Red light has a longer wavelength than blue light. Both red light and blue light are sent through a "double slit" with small slit spacing. The relative position of the first order constructive interference fringe for red light is (larger/smaller/same) as the position for blue light. As the slit is increased in size--what happens to the first order constructive fringe position for red light (increases/decreases/same)?, and for blue light (increases/decreases/same)? Larger, increass, decreases Same, increases, increases Larger, Same, Same Larger,...
Red light has a longer wavelength than blue light. Both red light and blue light are sent through a "double slit" with small slit spacing. The relative position of the first order constructive interference fringe for red light is (larger/smaller/same) as the position for blue light. As the slit is increased in size--what happens to the first order constructive fringe position for red light (increases/decreases/same)?, and for blue light (increases/decreases/same)? Same, increases, increases Larger, Same, Same Same, Same, Same Smaller,...
Question 18 (8 points) An object is placed 50.0cm in front of a lens. The image forms on the same side of the lens and is larger than the object. The image is (upright or inverted), the lens is (converging/diverging), image distance is (positive/negative), the image is (real, virtual) upright, converging, negative, real inverted, converging, positive, virtual upright, converging, negative, virtual upright, converging, positive, virtual upright, converging, positive, real O inverted, converging, positive, real inverted, diverging, positive, real inverted, diverging,...
An object is placed 50.0cm in front of a lens. The image forms on the same side of the lens and is larger than the object. The image is (upright or inverted), the lens is (converging/diverging), image distance is (positive/negative), the image is (real, virtual) O inverted, diverging, positive, real upright, converging, positive, virtual inverted, converging, positive, virtual upright, converging, positive, real upright, converging, negative, virtual upright, converging, negative, real inverted, converging, positive, real O inverted, diverging, negative, real
An object is placed 50.0cm in front of a lens. The image forms on the same side of the lens and is larger than the object. The image is (upright or inverted), the lens is (converging/diverging), image distance is (positive/negative), the image is (real, virtual) O upright, converging, positive, virtual O inverted, converging, positive, real inverted, diverging, negative, real O upright, converging, negative, virtual O inverted, diverging, positive, real O inverted, converging, positive, virtual O upright, converging, positive, real O...
A charge, q=91.0000 microCoulombs on a particle with mass m=1.00000 milli- grams, moves through a pipe from the origin to a point at coordinate x=1.40000m and y=1.8000m. All space is filled with a uniform electric field E=1,900.00000N/C and pointing parallel to the x axis. What is the change in electric potential as the mass moves from initial to final positions (in VOLTS) An object is placed 50.0cm in front of a lens. The image forms on the same side of...
Light with wavelength 500nm is incident upon a surface at an angle of 40.0 degrees, refracts and enters a second medium. The light that enters the second medium travels faster than in the first medium. Compared to properties in the first medium the refracted angle will be (smaller, larger, same), and the index will be (smaller, larger, same), and the frequency will be (smaller, larger, same) and the wavelength will be (smaller larger, same) Angle-smaller, index-larger, frequency-same, wavelength-smaller. Angle-larger, index-smaller,...
Light with wavelength 500nm is incident upon a surface at an angle of 40.0 degrees, refracts and enters a second medium. The light that enters the second medium travels faster than in the first medium. Compared to properties in the first medium the refracted angle will be (smaller, larger, same), and the index will be (smaller, larger, same), and the frequency will be (smaller, larger, same) and the wavelength will be (smaller larger, same) Angle-larger, index-smaller, frequency-same, wavelength-larger. Angle-larger, index-smaller,...
Light with wavelength 500nm is incident upon a surface at an angle of 40.0 degrees, refracts and enters a second medium. The light that enters the second medium travels faster than in the first medium. Compared to properties in the first medium the refracted angle will be (smaller, larger, same), and the index will be (smaller, larger, same), and the frequency will be (smaller, larger, same) and the wavelength will be (smaller larger, same) Angle-same, index-smaller, frequency-same, wavelength-smaller. Angle-larger, index-larger,...