The influence of urea, β-alanine and glycine on combustion synthesized Y2O3 powders was studied. Standard enthalpies of reactions suggested that the heat released from combustion reactions increases from urea (−1778kJ/mol) to glycine (−1934kJ/mol) and then to β-alanine (−1995kJ/mol). Since the heat released during combustion reactions is generated at different rates, we suggested the use of a new concept – heat generation velocity – in order to explain the different characteristics of Y2O3 powders. Urea had the smallest heat generation velocity (0.4kJ/s), therefore the resulted powder was amorphous. In the case of β-alanine, the higher heat generation velocity (0.7kJ/s) led to the formation of nanocrystalline (5nm) Y2O3 having a surface area of 36m2/g. Glycine triggered the combustion reaction with the highest heat generation velocity (3.9kJ/s). Therefore the resulted Y2O3 had the largest crystallite size (21nm) and the smallest surface area (19m2/g).