is often considered as a relative m

is often considered as a relative measure of material stability.
The oxidation is an exothermic process and the reaction heat
evolved makes it possible to employ differential scanning calorimetry
(DSC) or differential thermal analysis (DTA) for its study. The
standard tests for IP determination are predominantly carried out
under isothermal conditions. However, under these conditions
the oxidation peaks are often flat and their onsets, corresponding
to the end of IP, cannot be determined exactly. On the other hand,
the oxidation peaks obtained from non-isothermal measurements
at various heating rates are distinct and their onsets can be read
accurately (Šimon & Kolman, 2001; Šimon, Kolman, Niklová, &
Schmidt, 2000). In previous works, a theory for the kinetic description
of IP from non-isothermal DSC measurements with linear increase
of temperature based on Arrhenius equation has been
outlined (Šimon & Kolman, 2001). The theory was successfully applied
to the study of thermooxidation of edible oils (Šimon & Kolman,
2001; Šimon et al., 2000), fatty acids methyl esters (Polavka,
Paligová, Cvengroš & Šimon, 2005), polyolefines (Gregorová, Cibulková,
Košíková, & Šimon, 2005), polyisoprene rubber (Cibulková,
Šimon, Lehocky´ , & Balko, 2005a; Cibulková, Šimon, Lehocky´, &
Balko, 2005b), pharmaceuticals (Šimon, Veverka, & Okuliar,
2004), thermooxidative stability of dried milk (Šimon & Polavka,
2006) and styrene butadiene rubber (Cibulková, Šimon, Lehocky´ ,
Kosár, & Chochulová, 2009). Induction period determination based
on Arrhenius equation gives realistic data for thermooxidation of
edible oils at higher temperatures as it has been documented in
(Šimon et al., 2000).
The aim of most stability studies is to extrapolate the data obtained
from the accelerated tests to lower temperatures. The
extrapolation is almost exclusively carried out using Arrhenius