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What else can I help you with?
If the temperature of the air is said to be at absolute zero one might conclude?
the molecules contain a minimum amount of energy.
How might the distribution of leaf pigments differ in a leaf that is dark green in color vs one which is lighter green?
A darker green plant means that it has more chlorophyll to photosynthesise. A brighter leaf colour on the other hand shows that, that plant does not require so much chlorophyll to photosynthesise.
Green structures found in many cells of plant leaves and stems?
Chloroplasts are the green structures in plant cells that contain chlorophyll, a pigment responsible for capturing light energy to carry out photosynthesis. This process converts sunlight into chemical energy, producing glucose as a result.
Why did your freshly grated horseradish turn green?
Freshly grated horseradish can turn green due to the oxidation process that occurs when its enzymes are exposed to air. This reaction can produce chlorophyll and other pigments, resulting in a greenish tint. Additionally, if the horseradish was grown in soil rich in certain minerals, it might contain pigments that contribute to the color change. Despite the color, the flavor and pungency of the horseradish remain intact.
What is the meaning of chlorophy 3?
It seems like there might be a typo in your question. If you meant "chlorophyll," it is a green pigment found in plants that is essential for photosynthesis, the process by which plants convert sunlight into energy. Chlorophyll absorbs light energy, which is used to convert carbon dioxide and water into glucose and oxygen.
Green organelles in plant cells contain what to make food?
cellulose. I think. Of course, you might want to ask uncle Google
If a snake has limb buds what might a scientist conclude?
scientist might concluded that the snakes budding
Removing chlorophyll pigment from leaves might be done by?
chromatography
What might the scientist conclude about biome in this area?
The scientist might conclude that the biome in this area is determined by factors such as temperature, precipitation, soil type, and elevation. They may also conclude that the flora and fauna in the area have specific adaptations to thrive in these environmental conditions. Additionally, they might observe the interactions between different species and their impact on the ecosystem.
Why grass gets brown after winter?
The green color in grass (green plants in general) is caused by chlorophyll. Chlorophyll is one pigment in plants' leaves that absorbs light (all but the green, obviously, since the green is reflected why it appears green to us). There's also other cellular organs which absorb light, like beta-carotine. All of them have different absorption spectrae, why they reflect different regions of the spectrum of visible light, which is why they might appear orange or yellow to us; those don't absorb orange / yellow frequences. So when the light changes in the course of the year, the activity of the particles is shifted, chlorophyll is less active than others may be, so the leave appears to be the color of those cells, rather than the color of the chlorophyll which is getting comparatively less. (sorry if there's grammar faults, I'm not native)
Why does chlorophyll make plant leaves appear green?
Chlorophyll is a complex biomolecule containing magnesium. The molecule contains special ring shaped structures that capture preferred wavelengths of light. Green is not "captured" so it is reflected back to our eye. I do know that plants may contain modified chlorophyll and other pigments to take advantage of the type of light available to them. One example are sea plants where only certain wavelengths of light may reach specific depths and the plants have evolved to capture this light for energy. "We can also look at this from another angle. Why does chlorophyll reflect ("throw away") green light, which is the most abundant color in sunlight, and utilize instead the weaker reds and blue? Scientists theorize that it may have been because competing organisms were absorbing much of the green wavelengths billions of years ago, so algae (the earliest plants) reflected the green away and instead absorbed the red and blue hues that remained. Early in Earth's history, the oceans were dominated by archaea, bacteria-like organisms that are often purple in color, due to a pigment used to create energy from the sun in a process analogous to photosynthesis (but completely differently at the chemical level). As algae came along, they would have found a beneficial niche by utilizing the unused red and blue wavelengths (and reflecting the green). If you compare the absorption spectra of chlorophyll (plants) and retinal (the pigment in archaea), they are mirrors of each other, which supports this theory. Why archaea never evolved into complex organisms like algae did into plants and trees is not known (to me, at least), but another roll of the evolutionary dice might have led to large, purple archaea-trees that could outcompete plants (since plants use only the weaker red/blue wavelengths). Today, archaea ancestors remain as microorganisms that tend to inhabit extreme environments (geysers, salt ponds, etc.) where their purple (and red) colors can still be seen. For more info, see: "Extreme Microbes", S. DasSarma" by Paul Bridges
What might you conclude if you notice sections sections of warped and wrinkled rock layers on the side of a mountain?
You may conclude that the mountain you are observing is a fold mountain.
