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The mass of NH3 mole = its molecular weight = 14 + 3 x 1 = 17 The mass of H2O mole = its molecular weight = 2 x 1 + 16 = 18 This means that one mole of NH3 weigh less than one mole of H2O
The Haber Process produces ammonia (NH3) which can serve as the precursor/starting material for the manufacturing of plant fertilizers as well as explosives.
NH3 is its own compound.The elements in NH3 are nitrogen and hydrogen.
MnCl2 + NH3
NH3 is Ammonia, which is not an acid.
17
The densities of NH3 at variable temperatures are - At boiling point - 0.86 kg/m3 At 15 oC - 0.73 kg/m3 At -33 oC - 681.9 kg/m3 (liquid) At -80 oC - 817 kg/m3 (transparent solid)
You first need to find the mass weight of NH3. wt. of N + (wt. of H)= 14.0067 + 3(1.0067)= 17.03052 Now that you have the mass weight, you divide 15 into 17.03052... 15.0/17.03052 = 0.8807 moles in 15. g of NH3
The mass of NH3 mole = its molecular weight = 14 + 3 x 1 = 17 The mass of H2O mole = its molecular weight = 2 x 1 + 16 = 18 This means that one mole of NH3 weigh less than one mole of H2O
Covalent. NF3 is the fluoride equivalent of ammonia (NH3).
The molecular weight of NH3 is 17.03-grams per mole and 14.01 for N2. The reaction is N2 + 3H2 = NH3. Therefore for every 1-mole of N2 as a reactant 1-mole of NH3 is produced. .2941-moles of NH3 is produced with a mass of 5.01-grams.
The Haber Process produces ammonia (NH3) which can serve as the precursor/starting material for the manufacturing of plant fertilizers as well as explosives.
I assume you are talking about the Haber Process:3H2 + N2 ----> 2NH3If 3.71 mol of N2 is produced, there will be 7.42 mol of ammonia produced (as per mol ratios).Using the formula, n = g/mw ---> g = 7.42 x 17.034= 126.39228 grams of NH3
NH3
Using the molar mass of nh3, we find that we have 2.5 moles of nh3. Since 3 moles of h2o are produced per 2 moles of nh3, we see that we will produce 3.75 moles of h2o. This is equivalent to around 3.79 g.
NH3 is its own compound.The elements in NH3 are nitrogen and hydrogen.
Algae participates in a process called nitrogen fixation. In this process, Nitrogen (N2) is removed from the air and converted into ammonia (NH3). This process is especially important due to the need for ammonia in the biological process of biosynthesis.