Resolving power is the smallest separation at which two separate objects can be distinguished (resolved).
Resolution is the ability to distinguish between two points on an image i.e. the amount of detail.
The resolving power of a microscope is affected by the wavelength of light (400 - 600nm for visible light.
To improve resolving power, a shorter wavelength of light is needed. This is why sometimes microscopes are fitted with blue filters. Blue light has the shortest wavelength of visible light.
The elbow is a hinge joint consisting of three articulations which allow flexion and extension of the elbow, and also the supination and pronation of the forearm and the wrist at the elbow. The anatomy and the spacing of the bones in this joint allows only motion in one axis to flex and extend. The supporting ligaments and muscles also prevent hyperextension.
Explanation:
High-energy electrons are transported from the chlorophyll to other molecules by electron carriers beginning with pheophytin, P0 (a form of chlorophyll), then A1 phylloquinone etc.
The chloroplast is an organelle attached to the membrane found in plants. This comprises many plasma membrane invaginations called the thylakoid membrane. It contains chlorophyll pigments, called granum in rows, while the organelle's internal areas are called the lumen. Water fills the granum and the stroma is created.
Further Explanation:
<em>During the light reaction: </em>
- Photosystem II (PSII) contains pigments which consume light energy. This energy is exchanged between pigments until it enters the reaction core and is moved to P680; this transfers an electron to a higher level of energy where it then travels to a molecule of acceptors.
- For those removed from photosystem II, water supplies the chlorophyll in plant cell with substitute electrons. Additionally, water (H2O) divided into H+ and OH-by light during photolysis acts as a source of oxygen along with functioning as a reducer.
- The electron moves down the electron transport chain via several electron carriers
- The e- is delivered (to PS I) where it has a continuous loss of energy. Such energy drives the drainage of H+ from the stroma to the thykaloid, which results in a gradient creation. The H+ pass down their curve, passing into the stroma by ATP synthase.
- ATP synthase converts ADP and Pi to the ATP molecule, which stores energy.
- The electron enters Photosystem I where it heads to P700 pigments. It's. This consumes light energy, transfers the electron to a higher energy level, and moves it on to an acceptor electron. This leaves room for another electron which is then replaced by a photosystem II electron.
- In the ETC the NADP molecule is reduced to NADPH by supplying H+ ions. NADP and NADPH are vital to the Calvin cycle, in which monosaccharides or glucose-like sugars are produced after several molecules have been modified.
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Answer:
Carbohydrates
Simple sugars are known as monosaccharides. Carbohydrates also include long chains of connected sugar molecules. These long chains often consist of hundreds or thousands of monosaccharides bonded together to form polysaccharides.
Explanation:
Carbohydrates
Simple sugars are known as monosaccharides. Carbohydrates also include long chains of connected sugar molecules. These long chains often consist of hundreds or thousands of monosaccharides bonded together to form polysaccharides.
Answer: Decomposition Reaction.
In a <em>synthesis reaction</em>, two or more reactants combine to create one product. In a <em>decomposition reaction</em>, this product is broken down back into the two original reactants.
<em>Hope I helped!</em>