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Carbon is important to life because it can form complex molecules. This is because because of its ability to form many bonds. Carbon typically has four single bonds, two double bonds, one triple and one single bond, or one double and two single bonds. Due to this extensive boding, carbon can form large molecules that are necessary for the existence of living things.
Carbon can form complex molecules because of its ability to form many bonds. Carbon in a neutral species has four single bonds, two double bonds, one triple and one single bond, or one double and two single bonds. Due to this extensive boding, carbon can form large molecules and even chains tens of thousands of atoms long (polymers).
1. 6 carbon dioxide molecules combine with six 5-carbon molecules forming twelve 3-carbon molecules.2. The 12 3-carbon molecules are converted into high-energy forms.3. 2 of the 12 3-carbon molecules are removed and the plant uses them to produce sugars, lipids, amino acids, and other compounds.4. The 10 3-carbon molecules What_are_the_four_steps_in_the_Calvin_cycleback into six 5-carbon molecules, which combine with 6 more carbon dioxide molecules.The process starts over.
Carbon atoms combine by sharing electrons in covalent bonds. In glucose, carbon atoms form a ring structure with hydrogen and oxygen atoms attached to each carbon. In fatty acids, carbon atoms form a long chain with a carboxyl group at one end and a methyl group at the other end. These combinations allow for the formation of complex organic molecules with specific properties and functions.
Crucial to the carbon-based life on the Earth are several types of biologically-essential molecules. The basic types of molecules are carbohydrates, lipids, proteins and nucleic acids. The chemistry of these carbon-based molecules is included in the field of organic chemistry with the specific life-related processes forming the field of biochemistry.
The forming of carbon molecules in plants is photosynthesis.
It forms very strong bonds.
Carbon dioxide molecules are very important for photosynthesis
It forms very strong bonds.
Carbon is important to life because it can form complex molecules. This is because because of its ability to form many bonds. Carbon typically has four single bonds, two double bonds, one triple and one single bond, or one double and two single bonds. Due to this extensive boding, carbon can form large molecules that are necessary for the existence of living things.
Carbon can form complex molecules because of its ability to form many bonds. Carbon in a neutral species has four single bonds, two double bonds, one triple and one single bond, or one double and two single bonds. Due to this extensive boding, carbon can form large molecules and even chains tens of thousands of atoms long (polymers).
1. 6 carbon dioxide molecules combine with six 5-carbon molecules forming twelve 3-carbon molecules.2. The 12 3-carbon molecules are converted into high-energy forms.3. 2 of the 12 3-carbon molecules are removed and the plant uses them to produce sugars, lipids, amino acids, and other compounds.4. The 10 3-carbon molecules What_are_the_four_steps_in_the_Calvin_cycleback into six 5-carbon molecules, which combine with 6 more carbon dioxide molecules.The process starts over.
There are plenty of important molecules not made from carbon! Check out synthetic chemistry from some examples. Carbon is the most important element in organic chemistry.
CO2 is a chemist's way of writing carbon dioxide. The "6" means there are six molecules of carbon dioxide.In biology we often see 6CO2 on the left side of an equation for photosynthesis, where six carbon dioxide molecules combine with six molecules of water to form glucose and six molecules of oxygen. We also see 6CO2 on the right-hand side of an equation for aerobic respiration, in which a molecule of glucose reacts with six molecules of oxygen, forming six molecules each of carbon dioxide and water.
Carbon atoms combine by sharing electrons in covalent bonds. In glucose, carbon atoms form a ring structure with hydrogen and oxygen atoms attached to each carbon. In fatty acids, carbon atoms form a long chain with a carboxyl group at one end and a methyl group at the other end. These combinations allow for the formation of complex organic molecules with specific properties and functions.
Carbon and hydrogen
valence of 4 bonds and can form a single or double convalent bond