Abstract

Kernels recovered from fruit pits of 14 apricot (Prunus armeniaca L.) genotypes are tested for future application as feedstock for biodiesel production. The difference between the lowest and the highest oil yield between studied samples is over twofold and reached between 27.1 and 58.7% (w/w) dw. The oleic and linoleic acids are the two dominant fatty acids in apricot kernel oils; however, their content is affected meaningfully by the variety and amounted to 38.5–67.2 and 26.4–54.8%, respectively. Two significant correlations (p < 0.000005) are found between oil yield in kernels of different apricot genotypes and two fatty acids, oleic and linoleic (r = 0.947 and r = −0.927, respectively). The biodiesel parameters of 14 apricot genotypes are calculated empirically according to previously developed equations based on the fatty acid methyl esters composition of the potential feedstock. The European biodiesel standards of kinematic viscosity, cetane number, density, and iodine value are met for 13 investigated samples. The exception was noted for genotype HL PSŠ 5. The recorded differences between minimum and maximum value of individual biodiesel parameters calculated empirically for various apricot genotypes differed as follows: 0.20 mm2 s−1 (kinematic viscosity), 4.9 (cetane number), 0.06 MJ kg−1 (higher heating value), 0.0028 g cm−3 (density), 15.6 I2/100 g (iodine value), 1.67 °C (CFPP), and 2.15 h (induction period). The logarithmic regression model in comparison to linear regression model, better expressed the relationship between physicochemical properties of biofuel and the ΣPUFA/(ΣSFA + ΣMUFA) ratio. To confirm the usefulness of the applied empirical equations for biodiesel parameters prediction of the apricot feedstock, five cold‐pressed apricot kernel oils of different origin and with a varied composition of fatty acids are tested experimentally and compared with the values calculated empirically.Practical Applications: Apricot kernels have limited use in food industry due to a high content of the amygdalin. Therefore, application of apricot kernels as potential feedstock for the biodiesel production seems to be reasonable, especially due rich oil yield (up to even 60%). In this paper the impact of the apricot genotype on the potential application in the biodiesel industry as well as the relationship between the oil yield and apricot biodiesel quality is described. Obtained biodiesel parameters of 14 apricot (Prunus armeniaca L.) genotype oils can help estimate the economic perspectives of utilization as a potential energy source. The present study may contribute to the more targeted use of the apricot (Prunus armeniaca L.) kernels and promotes the efficient management of the plant material and environmental sustainability.Kernels recovered from fruit pits of 14 apricot (Prunus armeniaca L.) genotypes are tested for future application as feedstock for biodiesel production. High oil yield 27–58.7% (w/w) dw and predomination of the oleic and linoleic acids 38.5–67.2 and 26.4–54.8%, respectively, is recorded in the tested genotypes. The European biodiesel standards of kinematic viscosity, cetane number, density, and iodine value are met for all investigated samples, with the exception of genotype HL PSŠ 5.

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