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∙ 7y agoAs you move away from the center of the interference pattern, the path length difference between the two interfering waves decreases, resulting in fewer and narrower interference fringes. This occurs because the phase difference between the waves changes gradually with distance from the center, causing the fringes to become closer and thinner.
As you move away from the center of an interference pattern, the path length difference between the two interfering waves decreases, resulting in closer and thinner fringes. The variations in the intensity or brightness of the fringes decrease because the waves are becoming more in-phase as you move towards the center of the pattern.
No, concave lenses cause light rays to diverge outward when passing through them. This is due to the lens being thinner at the center than at the edges, causing light rays to spread out.
Yes, the size of an object can appear to change as the observer moves closer to or farther away from the object due to perspective. When an observer moves closer to an object, it may appear larger, and when moving farther away, it may appear smaller.
Convex lenses would help Marcia see clearly objects that are far away. Convex lenses are thicker in the center and thinner at the edges, helping to focus light rays further back onto her retina, correcting her farsightedness.
Target Field's straight away center field points in the northwest direction.
As you move away from the center of an interference pattern, the path length difference between the two interfering waves decreases, resulting in closer and thinner fringes. The variations in the intensity or brightness of the fringes decrease because the waves are becoming more in-phase as you move towards the center of the pattern.
It's thinner
No, concave lenses cause light rays to diverge outward when passing through them. This is due to the lens being thinner at the center than at the edges, causing light rays to spread out.
The density of the atmosphere decreases with altitude because there is less air pushing down from above. At sea level, the weight of the atmosphere above compresses the air, making it more dense than at higher altitudes where there is less pressure from the air above.
No because the epicenter is right on top of the center of the quake.
No, the foot is distal to the thigh. "Proximal" refers to a position closer to the center of the body, while "distal" refers to a position farther away from the center.
When an object enters a black hole, it starts being stretched. As it moves closer and closer to the center of the black hole, the gravitational pull on the part of the object that is closer to the center becomes more powerful than the gravitation pull on the part of the object that is farther away from the center. The objects keeps on getting stretched until it reaches the center of the black hole. We don't yet know what happens at that point.
It is closer to 350, being 150 away. It is 221 away.
With a higher altitude, there is a lower air pressure. This is caused by gravity pulling the gas molecules of our atmosphere closer to its surface. when the molecules are farther away from the Earth's surface the gravitational pull is weaker thus making the atmosphere thinner higher up and thicker closer to the surface.
Sediment closer to a mid-ocean ridge is typically younger, thinner, and composed of more volcanic material compared to sediment farther away. This is because the ridge is a site of active seafloor spreading where new oceanic crust is formed, leading to a higher rate of sedimentation near the ridge.
Sediment closer to a mid-ocean ridge tends to be younger, coarser, and more abundant due to the higher rate of volcanic and tectonic activity in those areas. In contrast, sediment farther away from the ridge is older, finer, and less abundant as it has had more time to accumulate and undergo erosion.
840,000 is closer as 281 away 830,000 is further 9,719 away