Van der Waals' forces
Predominantly its higher molecular mass. The higher mass of a molecule of C5H12 requires more energy to cause it to move fast enough to escape its intermolecular bonding than does the lower mass C2H6 molecule. The intermolecular bonding itself may be stronger in the higher molecular mass molecule, but this is relatively minor compared with the difference in molecular mass.
A hydrocarbon is C2H6.
C2H6 is ethane. It's one of the constituents of natural gas.
C2h6
Van der Waals' forces
C8h18
Predominantly its higher molecular mass. The higher mass of a molecule of C5H12 requires more energy to cause it to move fast enough to escape its intermolecular bonding than does the lower mass C2H6 molecule. The intermolecular bonding itself may be stronger in the higher molecular mass molecule, but this is relatively minor compared with the difference in molecular mass.
A hydrocarbon is C2H6.
1molecule of C2H6 contains 2 carbon atoms
C2H6 is ethane. It's one of the constituents of natural gas.
Balanced equation first. 2C2H6 + 7O2 -> 4CO2 +6H2O I suspect C2H6 of limiting the reaction. 2 moles C2H6 (1.6 moles O2/2 moles C2H6) = 1.6 moles O2 left over and all of the C2H6 is consumed.
C2h6
C2h6
yes!
C6H14 because it has a higher molar mass and is more complex
Ethane.