Each mole of ammonia requires one mole of nitrogen atoms. However, the nitrogen in the air occurs as diatomic molecules; therefore, only one-half mole of molecular nitrogen is required for each mole of ammonia.
Assuming you mean the decomposition of ammonia: 2NH3 --> N2 + 3H2, 100g NH3 = 5.88mol (100/17), and the ratio of ammonia to nitrogen is 2:1. 5.88mol/2=2.94mol, so that's the amount of nitrogen produced. 2.94x28 (molar mass of N2) gets you 82.3g nitrogen produced.
nitrogen plants eat
Their resemblance is only a fact that the ratio of Nitrogen and Phosphorus remains constant on earth. The phosphorus and nitrogen cycle both are utilized by organisms, and in order to get the required nutrients from the atmosphere.
Molarity is moles/liter, so in order to find the moles of a substance in a given volume, simply multiply molarity with volume (in liters). n=M*V
Nitrogen does not form pentahalides due to the non availability of d orbitals in its valence shell.
Ammonia is a covalant compound. It has a lone pair on the nitrogen atom.
0.1 mols of N2 * 3 mols of H3/1 mol of N2In other words, for 0.1 mols of N2 times 3 mols of H3 for ever mol of N2.I order to find the other numbers you are going to need a balanced equation:N2+3H2→ 2NH3So you would have 0.3 mols.
It contains nitrogen, and nitrogen is a mineral needed by all plants in order to survive. Without nitrogen, plants would have very stunted growth.
Assuming you mean the decomposition of ammonia: 2NH3 --> N2 + 3H2, 100g NH3 = 5.88mol (100/17), and the ratio of ammonia to nitrogen is 2:1. 5.88mol/2=2.94mol, so that's the amount of nitrogen produced. 2.94x28 (molar mass of N2) gets you 82.3g nitrogen produced.
1.5 moles of N2O5 Each molecule of NO3 contains one atom of nitrogen, so 3 moles of the compound will contain 3 moles of N atoms. However, N2O5 molecules each contain two nitrogen atoms, so each mole of N2O5 has two moles of nitrogen. So, in order to have three moles of N atoms, you need only 3/2 = 1.5 moles of N2O5.
In order to have a net charge of zero, nitrogen can have three bonds. it will often have more or less than that number with a charge on the atom. Example: Ammonia (NH3) versus Ammonium (NH4+)
Swamps and bogs are usually low in nitrogen because they don't have enough nitrogen-fixing bacteria and earthworms. These two things are needed in order to keep the soil aerated.
Given the balanced equation Kr + 3F2 --> KrF6 In order to find how many moles of F2 are needed to produce 3.0 moles of KrF6, we must convert from moles to moles (mol --> mol conversion). 3.0 mol KrF6 * 3 molecules F2 = 9.0 mol F2 --------- 1 molecule F2
...Dear lord. Okay. Nitrogen (dinitrogen - N2) is the most abundant molecule in our atmosphere. However, since it has a bond order of three and very strong bonds at that, it is generally useless. There are certain organisms, called nitrogen - fixing bacteria, though, that can convert nitrogen to ammonia (NH3). Ammonia is usable by plants, who incorporate it into amino acids, etc. and nitrate (NO3-). When animals eat the plants, they use these prefabricated molecules for themselves. This travels up the food chain. Finally, when an animal dies, bacteria break down the fixed nitrogen back to N2 and the process starts all over again.
Liquid ammonia used for this purpose is household cleaning type of ammonia. This should not harm trees at all as your application will be exterior spraying lightly on the surface of the bark of the trees and not soaking the ground with the ammonia in order to reach the roots. A different form of ammonia called ammonium nitrate is a type of fertilizer that is use to feed all types of plants. This type is a mixture of ammonia and nitrogen and is pelletized most of the time for the purpose of feeding. In the manner you are applying it should not harm the trees at all.
0.06667 moles
nitrogen plants eat