Calculate the amount of heat evolved in the complete oxidation of #"8.17 g"# of #"Al"# #(M_M = "26.98 g/mol")# at #25^@"C"# and #"1 atm"# pressure?
a 101 kJ
b 127 kJ
c 203 kJ
d 237 kJ
e 254 kJ
#DeltaH_f^@("Al"_2"O"_3(s)) = -"1676 kJ/mol"#
#4"Al"(s) + 3"O"_2(g) -> 2"Al"_2"O"_3(s)#
a 101 kJ
b 127 kJ
c 203 kJ
d 237 kJ
e 254 kJ
Note that the minus sign is used here to illustrate that the heat is being given off.
In other words, you know that standard enthalpy change for this reaction
is equal to
This implies that this reaction
which can be written as
will have
Use the molar mass of aluminium to calculate the number of moles present in your sample
According to the balanced chemical equation, the reaction will produce
The answer is rounded to three sig figs, the number of sig figs you have for the mass of aluminium.
In other words, you have
Once again, the minus sign is used to show that the heat is being given off.
Notice that you can get the same result by using the standard enthalpy change of formation of aluminium oxide
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To calculate the amount of heat evolved in the complete oxidation of 8.17 grams of aluminum (Al) at 25°C and 1 atm pressure, we'll first find the moles of aluminum involved in the reaction using its molar mass, and then use the appropriate enthalpy change value for the reaction.
-
Calculate moles of aluminum: [ \text{Molar mass of aluminum (Al)} = 26.98 \text{ g/mol} ] [ \text{Moles of Al} = \frac{\text{Mass}}{\text{Molar mass}} = \frac{8.17 \text{ g}}{26.98 \text{ g/mol}} ]
-
Determine the enthalpy change value: The enthalpy change (( \Delta H )) for the complete oxidation of aluminum is ( -1669.8 ) kJ/mol.
-
Calculate the amount of heat evolved: [ \text{Heat evolved} = \text{Moles of Al} \times \Delta H ] [ \text{Heat evolved} = \left( \frac{8.17 \text{ g}}{26.98 \text{ g/mol}} \right) \times (-1669.8 \text{ kJ/mol}) ]
Perform the calculations to find the heat evolved in the complete oxidation of 8.17 grams of aluminum.
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When evaluating a one-sided limit, you need to be careful when a quantity is approaching zero since its sign is different depending on which way it is approaching zero from. Let us look at some examples.
When evaluating a one-sided limit, you need to be careful when a quantity is approaching zero since its sign is different depending on which way it is approaching zero from. Let us look at some examples.
When evaluating a one-sided limit, you need to be careful when a quantity is approaching zero since its sign is different depending on which way it is approaching zero from. Let us look at some examples.
When evaluating a one-sided limit, you need to be careful when a quantity is approaching zero since its sign is different depending on which way it is approaching zero from. Let us look at some examples.
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