Going to high power on a microscope decreases the area of the field of view. The field of view is inversely proportional to the magnification of the objective lens. ... The specimen appears larger with a higher magnification because a smaller area of the object is spread out to cover the field of view of your eye
By changing the light intensity the rate of photosynthesis will either increase or decrease because it is one of the factors that affects photosynthesis. If you increase the light intensity the rate increases but if you decrease the light intensity the rate decreases.
Higher light intensity increases the rate of photosynthesis and vice versa.more intense light means more energy in the light, so the chloroplasts get more energy from light, making photosynthesis go faster
I believe that it increases. -_-
The graph shows that productivity increases with increasing light intensity, reaching a peak before plateauing. Therefore, at the light intensity where productivity peaks, you would expect the highest productivity level before it starts to level off.
when you change from low power to high power the light intensity decreases. this is because the high power objective lens is smaller than the low power lens. therefore, the high power lens lets less light through
Increases
As the amplitude of a light wave increases, the intensity of light also increases. This means that the light becomes brighter and more powerful.
The light intensity increases by a factor of four when you half the distance to the source. This is known as the inverse square law, where light intensity is inversely proportional to the square of the distance from the source.
As you increase the magnification of the objective lens, the light intensity reaching the specimen decreases. This is due to the fact that the same amount of light is spread out over a larger area with higher magnification, resulting in lower intensity at the specimen.
As magnification increases, the light intensity typically decreases because the same amount of light is spread over a larger area. This reduction in light intensity can sometimes result in a dimmer image with more magnification.
As light intensity increases, the rate of photosynthesis in plants also increases. This results in the plant consuming more carbon dioxide and producing more oxygen as a byproduct. Therefore, the concentration of oxygen increases as the light intensity increases.
If the intensity of light increases, more photons will be incident on the metal surface, leading to a higher rate of electron emission through the photoelectric effect. This results in a higher current of emitted electrons.
The relationship between the intensity and energy of light is that the intensity of light is directly proportional to its energy. This means that as the intensity of light increases, so does its energy.
It directly increases along with the growth in intensity of the light
The condenser lens on a microscope increases or decreases the light intensity by focusing the light onto the specimen. Adjusting the diaphragm underneath the stage can also control the amount of light reaching the specimen, thus affecting the light intensity.
The output power of a light source is directly related to the intensity of light it emits. As the intensity of light increases, the output power of the light source also increases. This relationship is important in determining the effectiveness of a light source in various applications, such as in phototherapy or communication systems.
Amplitude of light waves directly affects the intensity of light. As the amplitude increases, more energy is carried by the light wave, resulting in higher intensity. Conversely, a decrease in amplitude leads to lower light intensity.