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.
The nitrogen cycle begins with nitrogen fixation, where nitrogen gas is converted into ammonia by bacteria. Ammonia is then converted into nitrites and nitrates by nitrifying bacteria. Plants take up nitrates as nutrients, which are then consumed by animals. Finally, denitrifying bacteria break down nitrates back into nitrogen gas, completing the cycle.
N2 molecules break apart via nitrogen-fixing bacteria. Animals ingest nitrogen in nitrate-containing food after plants use nitrogen containing compounds. Organic matter decays via decomposers. N2 is formed via denitrifying bacteria.
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.
N2 molecules break apart via nitrogen-fixing bacteria. Other living entities such as plants and animals ingest nitrogen in nitrate-containing compounds. Organic matter decays via decomposers. N2 is formed via denitrifying bacteria.
The Urea molecule splits into two releasing carbon dioxide and ammonia.
It contains nitrogen, and nitrogen is a mineral needed by all plants in order to survive. Without nitrogen, plants would have very stunted growth.
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.
Ammonia is a covalant compound. It has a lone pair on the nitrogen atom.
Atmospheric nitrogen needs to be converted into ammonia in order to make it accessible to plants for growth. This conversion is done through a process called nitrogen fixation, which can be carried out by certain bacteria. Ammonia is a form of nitrogen that plants can easily take up and utilize to make essential proteins and other biomolecules.
The nitrogen cycle begins with nitrogen fixation, where nitrogen gas is converted into ammonia by bacteria. Ammonia is then converted into nitrites and nitrates by nitrifying bacteria. Plants take up nitrates as nutrients, which are then consumed by animals. Finally, denitrifying bacteria break down nitrates back into nitrogen gas, completing the cycle.
Plants need ammonia (NH3) to absorb and use nitrogen, which is an essential nutrient for their growth and development. Nitrogen is a key component of proteins, enzymes, and chlorophyll, all of which are necessary for plant health and vitality.
N2 molecules break apart via nitrogen-fixing bacteria. Animals ingest nitrogen in nitrate-containing food after plants use nitrogen containing compounds. Organic matter decays via decomposers. N2 is formed via denitrifying bacteria.
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.
N2 molecules break apart via nitrogen-fixing bacteria. Other living entities such as plants and animals ingest nitrogen in nitrate-containing compounds. Organic matter decays via decomposers. N2 is formed via denitrifying bacteria.
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
Oxygen, nitrogen, chlorine, bromine Water, ammonia, methane, hydrogen sulfide Carbon monoxide, carbon dioxide, methane, ethylene The correct answer is option 2: Water (H2O) < ammonia (NH3) < methane (CH4) < hydrogen sulfide (H2S).