Showing papers by "Timothy J. Mason published in 2014"

Sonochemical degradation of endocrine disrupting chemicals 17β-estradiol and 17α-ethinylestradiol in water and wastewater

Abstract: The sonochemical degradation of 17β-estradiol (E2) and 17α-ethinylestradiol (EE2) in water and wastewater was investigated at ultrasonic frequency of 850 kHz. The effects of pH, initial concentrations, temperature, power and dissolved organic carbon were examined. The results obtained indicated that the rate of ultrasonic degradation of E2 and EE2 in water and wastewater is influenced by the pH, power, air sparging and the dissolved organic content of the aqueous solutions. Mass degradation rates of E2 and EE2 per kW ranged from 1.7 to 4.0 mg kW−1 at varying process parameters. The degradation process followed the pseudo-second-order kinetic model with rate constant of 1.71 × 10−2 min−1 at 25 °C. The value for activation energy (E a = 15.21 kJ mol−1) obtained from Arrhenius-type plot, indicated that the ultrasonic degradation of steroid hormones is thermodynamically feasible, and does not progress only on radical reactions but other intermediate reaction processes. In wastewater, the higher dissolved organic carbon significantly reduced the effectiveness of degradation of the E2 and EE2 showing that ultrasound treatment will be more effective as a tertiary treatment option in wastewater applications.

The effect of ultrasound on the growth and viability of microalgae cells

Abstract: Ultrasound has shown potential for both increasing microalgal lipid extraction yields and for the control of microalgal blooms through cell disruption. The effect of ultrasound on the viability of microalgae was investigated on the following species: Dunaliella salina, Chlamydomonas concordia and Nannochloropsis oculata. Sonication with a 20 kHz probe (0.086 W cm−3) caused complete cell disruption of D. salina after 4 min. This microalgae species does not have a true cell wall. In the case of C. concordia which has a thin cell wall complete cell disruption under the same conditions took 16 min. Under the same conditions, there was no visible disruption of N. oculata, a species which has a thick cell wall. However spectro-fluorophotometer analysis of the sonicated suspension of N. oculata showed that although the cells were intact, the level of intracellular chlorophyll was reduced by ~10 %. This clearly indicated damage to the microalgal cell wall. After 16 min, treatment cultures of all three species remained viable. Programmed cell death (PCD) has been induced in some microalgal species to terminate algal blooms; ultrasonic application did not induce PCD in any species tested. The supernatant of sonicated D. salina and C. concordia has also been shown to be able to boost the growth of established cultures. These results provide important information concerning the uses of ultrasound in both the microalgal biofuels industry and for the control of microalgal blooms.