บทคัดย่องานวิจัย

Simultaneous measurement of neon diffusivity and skin resistance of ‘Braeburn’ and ‘Jonica’ apples

Q. Tuan Pham, Wendy Schotsmans, Q. Tri Ho, Bert E. Verlinden, Pieter Verboven and Bart M. Nicolaï

Postharvest Biology and Technology, Volume 50, Issue 1, October 2008, Pages 53-63

2008

บทคัดย่อ

Simultaneous measurement of neon diffusivity and skin resistance of ‘Braeburn’ and ‘Jonica’ apples

resistance to transport of metabolic gases simultaneously from the results of tracer gas efflux experiments. It is based o­n curvefitting the gas concentrations calculated from a finite element gas transport model to measured data. The latter were obtained by impregnating apples with the inert tracer gas neon and transferring them to a neon-free jar, where they release the absorbed neon; the neon concentration in the second jar was monitored. Two models were tested, o­ne where neon is absorbed into the gas phase (pores) o­nly and o­ne where it was also absorbed into the cells. The test involved two cultivars, ‘Braeburn’ and ‘Jonica’ (a Jonagold color mutant), each stored for o­ne, 17 and 33 weeks under controlled atmosphere, with 30 replicates in each batch. For the outer cortex region the average diffusivity (based o­n the concentration gradient in the fruit) was 7.59 × 108 m2 s1 for ‘Braeburn’ and 14.4 × 108 m2 s1 for ‘Jonica’. Average skin resistances were 4.28 × 105 for ‘Braeburn’ and 4.54 × 105 for ‘Jonica’. Using a co-diffusion model the diffusivities of O2 and CO2 were also estimated from the results for neon. The diffusivity results imply that the response time of the fruit to a change in atmosphere is of the order of 5–10 h. The lower diffusivity and hence lack of uniformity in the internal atmosphere of ‘Braeburn’ apples might explain why they are more susceptible to core damage than ‘Jonica’. The main limitation of the present tests is that o­nly the first few minutes of the efflux period was monitored, hence the property values obtained relate o­nly to the outer layers of tissue (about 3 mm).