Mohammad Hasani scite author profile

et al. 2021

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A study of the effect of gliding arc non-thermal plasma on almonds decontamination

Khalili

Shokri

Khani

et al. 2018

Escherichia coli is responsible for more than 90% of food poisoning cases and can survive for long periods under adverse conditions and refrigeration temperature. In this study, the effect of gliding arc plasma processing on infected Almond with Escherichia coli was investigated. The optimal conditions during the different applied powers and treatment time were determined. Moreover, the optimum condition was examined on other gram-negative bacteria as Salmonella and Shigella. The viability of almond bacteria was studied using colony-counting analysis and evaluation of active species in plasma was made by the optical emission spectroscopy (OES) method. Scanning electron microscopy (SEM) analysis was carried out to illustrate the morphological change and color measuring analysis was performed to investigate food quality after almond plasma treatment. Finally, it was shown that plasma technique has the capability of food industrialization and potential of method extension.

Probing negative ions and electrons in the afterglow of a low-pressure oxygen radiofrequency plasma using laser-induced photodetachment

J. Phys. D: Appl. Phys.

Marvi

Beckers

2021

Degradation of 4-chlorophenol in aqueous solution by dielectric barrier discharge system: effect of fed gases

J Environ Health Sci Engineer

Khani

Karimaei

et al. 2019

A dielectric barrier discharge system with a discharging zone where degradation processes happen is designed to remove 4chlorophenol from water. The removal of 4-chlorophenol was influenced by the processing parameters such as gas flow rate, flow ratio of oxygen and argon, applied voltage and total applied power. Increasing the power or gas flow rates within a certain range enhanced the removal efficiency. 99% of 4-chlorophenol was removed in 6.5 min at reactor's efficient point which is set by adjusting the flow ratio of introduced gases and voltage. The removal percent was about 95% at 5 min of non-thermal plasma treatment with peak voltage of 10 kV and oxygen and argon flow rate of 20 SCCM and 200 SCCM respectively. Then by adjusting the flow ratios in order to find the optimum point. At this point the efficiency reached its peak due to excessive introduction oxygen gas which results in production of more oxidative agents. HPLC and GC-MS analysis have been carried out in order to investigate the by-products of degradation process. After 6.5 min of treatment at efficient point of degradation reactor, a 64% decrease in COD index has been indicated.Keywords Dielectric barrier discharge . Non-thermal atmospheric plasma . 4-chlorophenol . AOP . Endocrine disruptors . Plasma in liquids * Babak Shokri

Temporal afterglow between two pulses of repetitively pulsed argon-acetylene plasma: measuring electron and negatively charged species densities

J. Phys. D: Appl. Phys.

Donders

Beckers

2023

The temporal afterglow between two pulses of a repetitively pulsed radio-frequency driven low-pressure argon-acetylene plasma is experimentally explored using laser-induced photodetachment combined with microwave cavity resonance spectroscopy. The densities of electrons and negatively charged species, i.e., anions and dust particles, are measured temporally resolved until 1.9 s in the temporal plasma afterglow. Two different plasma-on times are adjusted to investigate the dynamics of anions and dust particles in the afterglow phase. The measurements show that while electrons decay rapidly within the first few milliseconds of the afterglow phase, the negatively charged species reside much longer in the plasma after the plasma is switched off. The electron density decay is measured to be faster for a longer plasma-on time. This effect is attributed to an enhanced recombination rate due to a higher dust particle density and/or size. The density of negatively charged species decays within two different timescales. The first 20 milliseconds of the afterglow is marked with a rapid decay in the negatively charged species density, in contrast with their slow density decay in the second time scale. Moreover, a residual of the negatively charged species densities is detected as long as 1.9 s after extinguishing the plasma.