The three kinds of carbon backbones are straight chain,branched chain,and the ring.
Most plants have special structures on their leaves called stomates. Carbon dioxide is drawn into the leaf tissue through these pore-like structures.
Carbon is common in both diamond and charcoal.
Homologous structures
Perhaps the yellow candle contains hydrocarbons with a smaller carbon backbone. The smaller the carbon backbone, the faster the molecule (and hotter) will burn. Methane, Ethane, Propane, Butane.... Octane, Ethane (used in creation of ethanol) burn hotter than octane, but are all used for fuel. The larger (longer) the carbon backbone, the less volitile the hydrocarbon. See Web Links See the Web Links for "Wikipedia: List or inorganic compounds" to the bottom for the answer. Any chemical compound without a carbon is an inorganic compound. In general, a compound that contains a carbon atom is an "organic" compound. There are exceptions: oxides of carbon like carbon dioxide and carbon monoxide; salts of carbon, like cyanide, cyanate, and thiocyante. See http://en.wikipedia.org/wiki/Inorganic_compounds_by_element for a detailed listing inorganic compounds by element. A few examples of common inorganic compounds: Carbon Dioxide, CO2 Hydrogen Chloride, HCl (when dissolved in water becomes Hydrochloric acid, aka stomach acid) Sulphuric acid, H2SO4
Nitrogen, Oxygen,Hydrogen, and Carbon Di-oxide are the common Gases in the Atmosphere.
No, carbon is the element that forms the backbone of most polymers. Oxygen may be present in polymer structures as well, but it is the carbon atoms that primarily link together to form the long chains characteristic of polymers.
Carbon is known as the backbone of life because it is the key element in organic compounds, which form the basis of all living organisms on Earth. Carbon atoms can form stable bonds with other elements, allowing for the complex structures necessary for life to exist.
Glycerol backbone, with fatty acids attached to C1 and C2 and a phosphate attached at the last carbon. Attached to it is a base or an alcohol.
Carbon is the element that provides the backbone for all organic molecules due to its ability to form stable covalent bonds with other carbon atoms and a variety of other elements. This unique bonding capacity allows for the diversity of structures and functions seen in organic compounds.
The answer is carbon!
Carbon. Organic molecules are usually made up of carbon chains or rings, with hydrogen atoms bonded to most bond sites. The molecules are distinguished by the length of the chain, the number of double or triple carbon-carbon bonds, and the other elements or ligands that might be bonded to the carbon chain or ring.
carbon atoms forms the backbone of glucose molecule
These are known as hydrocarbons, which are molecules composed solely of carbon and hydrogen atoms. The arrangement of carbon atoms can result in straight chains, branched chains, or even cyclic structures. They form the backbone of organic chemistry and are the basis of many important compounds like alkanes, alkenes, and alkynes.
well, Amoebas do not have a backbone. which makes them a invertabrate.
The backbone sugar of RNA is ribose, which is a five carbon carbohydrate. When the oxygen atom from carbon number 2 is lost, it gives deoxy ribose, which is the backbone sugar for DNA.
The atoms attached to the carbon backbone that determine a molecule's function within the cell can vary depending on the specific molecule. Common atoms attached to carbon in biological molecules include hydrogen, oxygen, nitrogen, and phosphorus. The functional groups attached to the carbon backbone, such as hydroxyl, amino, carboxyl, and phosphate groups, play a crucial role in determining the molecule's function within the cell.
All four macromolecules (carbohydrates, lipids, proteins, nucleic acids) have carbon atoms as a common element. Carbon atoms are the backbone of organic molecules because of their ability to form versatile and stable bonds with a variety of other elements.