If a red light is shown on the leaves, then the rate of photosynthesis will decrease. The experiment conducted shows that red light is not efficient for photosynthesis. When the discs were placed in front of the red light, the discs floated on a much slower pace than the discs in the white light. The hypothesis was correct; the discs floated much slower in the red light. This is probably because the red light appears much dimmer than the white light. Since the leaf needs light for photosynthesis, the light that is dimmer will work less efficiently. In this lab, the data was accurate because the hypothesis was correct. The hypothesis was able to prove that the red light was unable to effectively produce photosynthesis. Only one of the discs
Introduction: Photosynthesis can be defined as a solar powered process that removes atmospheric carbon dioxide and transforms it into oxygen and carbohydrates (Harris-Haller 2014). Photosynthesis can be considered to be the most important biochemical process on Earth because it helps plants to grow its roots, leaves, and fruits, and plants serve as autotrophs which are crucial to the food chain on earth. Several factors determine the process of photosynthesis. Light is one these factors and is the main subject of this experiment. The intensity of light is a property of light that is important for photosynthesis to occur. Brighter light causes more light to touch the surface of the plant which increases the rate of photosynthesis (Speer 1997). This is why there is a tendency of higher rates of photosynthesis in climates with a lot of sunlight than areas that primarily do not get as much sunlight. Light wavelength is also a property of
-Measuring the pH of a solution (such as in the lab we had) could also help determine the rate of photosynthesis. You would need a much more specific pH meter, but generally, if pH goes down, the level of CO2 is higher, meaning more cellular respiration. Higher pH means there’s less CO2, so more photosynthesis.
The rate of photosynthesis is affected by environmental factors like light intensity, light wavelength, and temperature. This experiment will test the
Follow the steps detailed in the first experiment to test the effects of an increase in light intensity on photosynthetic rates in corn (a C4 plant).
The data shows that photosynthesis really does need water and light. No disks floated in the dark because there was no light. In the light experiment there was only 6 disks to begin with. The data proves the hypothesis correct, it was predicted that no disks were going to float.
What is the relationship between the increase in light intensity and the photosynthetic rate in leaves from a corn plant? How does this relationship compare with what you observed for tomato plants?
We then removed the air in the leaf discs, (which would help the leaf float) by vacuuming it with a syringe. After that, we placed five leaf discs in each beaker, and timed the amount of time it took for each leaf disc to hit the surface of the liquid mixture with the different colored lids/lights. By placing an air-free leaf at the bottom of each beaker, then waiting to record the time when the leaf hits the top (photosynthesis will have produced oxygen bubbles to make it float), this procedure will show us how quick photosynthesis takes place using different color lights. The bar graph shows that there is a correlation between the color of the light and the time it takes for the leaves to float up. The blue light took an average of 8.2 minutes to rise; the green light, 14.4 minutes; the white light, 13 minutes; and the no light had not floated up by the time class ended. As one can see, the blue time was faster than the white time by about 63%, and the green time was slower than the white time by about 11%. The color of the lights had an impact on the rate of
As the rate of both photosynthesis and cellular respiration are being measured under two different conditions, one being different colors of light and the other being temperature. As the measurements will be concentrations over time. The chemical formula that will be implicated will
The photosynthetic rates of Camomba Caroliniana, were effected by the color of light it was exposed to during the experiment. As seen in Table 1, Camomba Caroliniana that was exposed to green light had an average photosynthetic rate of 0.13 mL O2 produced/g/hour, which was lower than the photosynthetic rate of Camomba Caroliniana that was exposed to white light (0.19 mL O2 produced/g/hour). The data from table 1 can also be used to determined the reliability of the experiment, the standard errors for green and white light are relatively small, 0.02 and 0.01, respectively. This means that there is less variation in the experiment, but the experiment involving white light is slightly more reliable because its standard error is smaller. The 95%
For this experiment we wanted to see if access to light would affect the rate of CO2 production in spinach leaves. To figure out this phenomenon we performed 5 experiments to test access to light using wash-in-walk fabric. For the first experiment we used no fabric and in the following experiment we placed one layer of wash-in-walk fabric between the light source and the spinach. After ever run, we added another layer of wash-in-walk fabric between the light source and spinach until we used 4 pieces of fabric. The control experiment, which was the run without fabric, gave us the greatest average CO2 depletion rate, with an average of -1.361 ppm/m, with a range from -1.589 to -1.133 ppm/m which is represent in Figure 2. Using one layer of fabric
There are three main factors that affect the rate of photosynthesis; temperature, carbon dioxide concentration and light intensity. Specifically, in order for a plant to photosynthesise at a sufficient rate, there must be enough light as a plant is unable to do this process if there is an inadequate amount. The more photons of light that hit the leaves results in a greater amount of chlorophyll molecules that are ionised and more ATP is produced. Therefore, by increasing the amount of light the plant is receiving there will be a greater amount of energy resulting in a faster rate of photosynthesis. However, if there is an insufficient amount of supply from other factors, then when there is too much light it can affect the rate of photosynthesis.
The real spinach leaves with also tested with light that showed a negative slope for CO2 release. The experiment had a positive control and a negative control. The CO2 deceased and, also increased. The experiment photosynthesis was used with color of light, the colors that was tested were green, yellow, blue, and
Plants, through the use of chlorophyll (green pigment in plants) that traps light can generate ‘food’ by combining carbon dioxide in the air and water. As with many chemical process energy is need to make and break molecules during the chemical process. The greater the light levels the more energy is available to carry out process of photosynthesis. Some photosynthesis requires carbon dioxide, the more carbon dioxide that is available that is available the greater the rate of photosynthesis. According to Sadava et al (2011) increasing light intensity would tend
The purpose of this LeafLab report was to help better my understanding the process of photosynthesis. It helped me comprehend the rate of photosynthesis in several different plants and how it can change from factors that happen naturally on earth. The factors that affect and change the rate of photosynthesis include light intensity, light quality, CO2, concentration, and of course temperature. I was able to examine, differentiate, and compare photosynthesis in different types of plants; such as C3 and C4 plants. I was able to simulate and take measurements of the rate of carbon dioxide in the leaves of plants, and investigate light and dark respiration, the efficiency of photochemical. I became aware of the dependencies of carbon dioxide and how “energy” is not just a feeling of excitement. The lab was exciting; exciting to receive an end result. I was very motivated and determined to find answers and collect the information, however, the actual lab was very difficult for me to compute and a bit confusing, even with the documents provided. I felt lost a lot of
Different colors of light affect the development of plants in different ways. The rate of photosynthesis of each plant will differ depending on the color of the light that is emitted on it. Once the carbon dioxide is produced it will react with the water in the aquatic system, thus producing carbonic acid. We measured the carbonic acid levels with the help of phenolphthalein and sodium hydroxide to conclude that the brighter the color of the light is, the faster the plant will photosynthesize, and thus the lower the carbonic concentration of the aqueous solution.