1.91 g H2 is allowed to react with 9.86 g N2, producing 1.74 g NH3. What is the theoretical yield in grams for this reaction under the given conditions? Express your answer to three significant figures and include the appropriate units.
1 Answer
Explanation:
- Write and balance the equation
#3H_2(g)+N_2(g)->2NH_3(g)# - Find the molar masses of the reactants and the product. Values are obtainable from the periodic table.
#H_2=2"g/mol"#
#N_2=28"g/mol"#
#NH_3=17"g/mol"# - Given the masses of the reactants, the number of moles can be calculated as illustrated below.
#etaH_2=1.91cancel(gH_2)xx(1molH_2)/(2cancel(gH_2))=0.955molH_2#
#etaN_2=9.86cancel(gN_2)xx(1molN_2)/(28cancel(gN_2))=0.352molN_2# - Now, identifying how much each reactant requires if the reaction goes into completion. Refer to the balanced equation for the needed molar ratio.
a.#ul(etaH_2=0.955mol " available"):#
#etaN_2=0.955cancel(molH_2)xx(1molN_2)/(3cancel(molH_2))=0.318molN_2#
Thus;
#0.955molH_2-=0.318molN_2#
b.#ul(etaN_2=0.352mol " available":#
#etaH_2=0.352cancel(molN_2)xx(3molH_2)/(1cancel(molN_2))=1.056molH_2#
Thus;
#0.352molN_2-=1.056molH_2# -
Find the limiting reactant through comparison: the required and the available number of moles; i.e.,
#(H_2" available")/(0.955molH_2)<(H_2" required")/(1.056molH_2)#
#color(red)(H_2 " is the limiting reactant."#
#(N_2" available")/(0.352molN_2)>(N_2" required")/(0.318molN_2)#
#N_2 " is the excess reactant."# -
Knowing the limiting reactant, the theoretical yield
#(TY)# can be computed as shown below. Refer to the balanced equation for the mole ratio and the molar mass of the#NH_3# as reflected in#"step" 2# for the following series of conversions:
#=0.955cancel(molH_2)xx(2molNH_3)/(1cancel(molH_2))#
#=1.91cancel(molNH_3)xx(17gNH_3)/(1cancel(molNH_3))#
#=32.5gNH_3#
