Litcius/Paper detail

Thermal and Dielectric Properties of Wolfberries as Affected by Moisture Content and Temperature Associated with Radio Frequency and Microwave Dehydrations

Shunqin Bai, Li Liu, Haibo Yu, Xiangyu Guan, Rui Li, Lixia Hou, Bo Ling, Shaojin Wang

2022Foods16 citationsDOIOpen Access PDF

Abstract

Knowledge of the thermal and dielectric properties of wolfberries is essential for understanding the heat transfer and the interaction between the electromagnetic field (10–3000 MHz) and the sample during radio frequency (RF) and microwave (MW) drying. The thermal and dielectric properties of wolfberries were determined as influenced by moisture content from 15.1% to 75.2%, w.b.) and temperature from 25 to 85 °C. The results showed that as the moisture content increased from 15.1% to 75.2% (w.b.), the true density of wolfberries decreased, but the specific heat capacity and thermal conductivity increased with increasing temperature and moisture content. The dielectric properties (DPs) of wolfberries decreased with increasing frequency from 10 to 3000 MHz. The dielectric constant increased with increasing temperature at lower a moisture content (below 45% w.b.) but decreased with increasing temperature at a high moisture content (above 60% w.b.). The cubic and quadratic polynomial models (R2 = 0.977 − 0.997) were best for fitting the dielectric constant and loss factor at four representative frequencies of 27, 40, 915, and 2450 MHz, respectively. The penetration depth increased with the decreased frequency, temperature, and moisture content, and was greater at RF frequencies than MW range, making the RF heating more effective for drying bulk wolfberries. These findings offered essential data before optimizing RF or MW dehydration protocols for wolfberries via computer simulation.

Topics & Concepts

Water contentDielectricDielectric heatingThermal conductivityMicrowaveMaterials scienceRadio frequencyMoisturePenetration depthDehydrationAnalytical Chemistry (journal)Dielectric lossThermalComposite materialChemistryThermodynamicsElectrical engineeringOptoelectronicsChromatographyOpticsBiochemistryGeotechnical engineeringQuantum mechanicsPhysicsEngineeringFood Drying and ModelingMicrobial Inactivation MethodsFreezing and Crystallization Processes