photosynthesis turns carbon dioxide into longer 6 carbon chains (glucose) which may then be further elongated into starches for storage.
Yes. The "benzo" portion of the name keys you into this being an organic compound. Organic compounds are carbon-containing compounds. In this case, sodium benzotriazolyl has at least one aromatic ring, definitely making it an organic compound.
food making and plants breathe carbon dioxide
Mainly because carbon is unusual in being able to form strong and stable bonds to itself. This means you can form chains of carbon atoms, a phenomenon called catenation. So for any type of carbon compound you can have a whole series, with one carbon, two carbons, three carbons etc., in theory for ever. So you can have methane, ethane, propane etc. chloromethane, chloroethane, chloropropane etc methanol, ethanol, propan-1-ol...... Then, for all but the simplest members of each series, the position of the different atoms matters as well, and you get different compounds called isomers. There are millions of possibilities.
The term "organic" in chemistry at a time when certain complicated carbon compounds could not be made in the lab, but only by living things. Some scientists even believed that living things could only make these "organic" compounds because they possessed some special "spiritual essence" unique to living things that would not be accessible to nonliving things.Eventually scientists discovered enzymes and other ways of making these complicated carbon compounds in the lab, so the mystery went away but the name "organic chemistry" remained.In modern Chemistry, Organic Chemistry is the study of carbon compounds. Methane is considered the simplest organic compound. However, carbon dioxide and the various carbonates are not "organic" compounds.
In making fertilizers, explosives and organic compounds
Carbon is fundamental to all organic compounds. Organic compounds contain one or more C-H or C-C bonds. All organic compounds contain carbon, but not all carbon-containing compounds are organic, such as carbon dioxide.Carbon is the foundation for making organic compounds. Every organic contains carbon. Hydrogen is also present in every organic compound.
Higher than what? Some organic compounds (e.g. propane, butane) have very very low boiling points making them gases at room temperature. Certain inorganic compounds (e.g. tungsten carbide) have boiling points so high that before those compounds boiled all organic compounds would not only have boiled but would have decomposed into their elements or very simple inorganic carbon compounds (e.g. carbon monoxide, carbon dioxide).
Nitrogen, photosynthesis's, carbon dioxide
Yes. The "benzo" portion of the name keys you into this being an organic compound. Organic compounds are carbon-containing compounds. In this case, sodium benzotriazolyl has at least one aromatic ring, definitely making it an organic compound.
By making sure that no harmful gases are passed into the air like Sulphur Dioxide, Oxides of Nitrogen, Carbon Monoxide, Hydrogen Chloride and Volatile Organic Compounds.
In living organisms, carbon fixation (incorporation of atmospheric inorganic carbon dioxide into organic compounds) is carried out by certain microbes and most plants and the other organisms feed on plants to acquire their organic compounds. The process of carbon fixation is called photosynthesis and it's driven by sun light and catalyzed by enzymes. In organic chemistry labs, chemists have found ways to either create organic molecules from inorganic ones or add carbon onto preexisting organic molecules, though these processes require very strigent reaction conditions that are different from those in living organisms, mostly because we cannot make use of enzymes the same way as living organisms do. The earliest experiments involved reacting carbon dioxide and ammonia by adding an electrical current, making urea as the product. Current organic chemstry techniques have countless ways to manipulate organic compounds and it will be futile to try to list even a fraction of the techniques. Follow the link below for a Wikipedia page that has links to a large number of possible organic chemistry reactions.
In living organisms, carbon fixation (incorporation of atmospheric inorganic carbon dioxide into organic compounds) is carried out by certain microbes and most plants and the other organisms feed on plants to acquire their organic compounds. The process of carbon fixation is called photosynthesis and it's driven by sun light and catalyzed by enzymes. In organic chemistry labs, chemists have found ways to either create organic molecules from inorganic ones or add carbon onto preexisting organic molecules, though these processes require very strigent reaction conditions that are different from those in living organisms, mostly because we cannot make use of enzymes the same way as living organisms do. The earliest experiments involved reacting carbon dioxide and ammonia by adding an electrical current, making urea as the product. Current organic chemstry techniques have countless ways to manipulate organic compounds and it will be futile to try to list even a fraction of the techniques. Follow the link below for a Wikipedia page that has links to a large number of possible organic chemistry reactions.
The carbon in plants come from the carbon found in carbon dioxide (CO2). As plants undergo photosynthesis they draw in water through their roots and carbon dioxide from the air through specialized structures called stomates. So the inorganic carbon in carbon dioxide becomes organic carbon making up the oils, carbohydrates and proteins found in plants.
food making and plants breathe carbon dioxide
It is usefull because of it's abundance and for the fact it can have 4 covalent bonds making it a very stable element in molecules and polymers.
Mainly because carbon is unusual in being able to form strong and stable bonds to itself. This means you can form chains of carbon atoms, a phenomenon called catenation. So for any type of carbon compound you can have a whole series, with one carbon, two carbons, three carbons etc., in theory for ever. So you can have methane, ethane, propane etc. chloromethane, chloroethane, chloropropane etc methanol, ethanol, propan-1-ol...... Then, for all but the simplest members of each series, the position of the different atoms matters as well, and you get different compounds called isomers. There are millions of possibilities.
Well I use carbon dioxide in my fire extinguisher. What do you use carbon dioxide, or to put it another way? In what do you use carbon dioxide? Humans breathe out carbon dioxide... Breathing it out is not exactly using it. That would be more like making it.