BIOLOGICAL, BEHAVIORAL, AND PHYSICAL CONTROL AS ALTERNATIVES FOR STORED PRODUCT AND QUARANTINE PESTS OF FRESH/DRIED FRUITS AND NUTS
Location: Commodity Protection and Quality
Title: Temperature and Moisture Dependent Dielectric Properties of Legume Flours Associated with Dielectric Heating
| Guo, Wenchuan - |
| Wang, Shaojin - |
| Tiwanri, Gopal - |
| Tang, Juming - |
Submitted to: Lebensmittel Wissenschaft und Technologie
Publication Type: Peer Reviewed Journal
Publication Acceptance Date: July 15, 2009
Publication Date: March 15, 2010
Citation: Guo, W., Wang, S., Tiwanri, G., Johnson, J.A., Tang, J. 2010. Temperature and Moisture Dependent Dielectric Properties of Legume Flours Associated with Dielectric Heating. Lebensmittel Wissenschaft und Technologie. Food Science and Technology. 43:193-201.
Interpretive Summary: A major problem in the storage and marketing of legumes is infestation by insect pests. Importing countries may set conditions concerning pests, including phytosanitary disinfestation treatments such as fumigation or certification that the shipment is free of certain insects. Consumer and environmental concerns over the use of chemical fumigants has generated interest in non-chemical alternatives such as heat treatments using radio frequency and microwave energy. To develop such heat treatments for legumes, it is important to determine the dielectric properties that govern the interaction between the electromagnetic energy and the legumes. Dielectric properties of chickpea, green pea, lentil and soybean flour samples at different frequencies, temperatures and moisture contents were measured by an open-ended coaxial-line probe and impendence analyzer. The dielectric constant and loss factor of the four legume flours decreased with increasing frequency but increased with increasing temperature and moisture content. The effective electrical conductivity of legume flours at the highest moisture content and temperature was 5-6 orders of magnitude smaller than that in high moisture vegetables, fruits and other foods at room temperatures. The difference in loss factors among the four legumes was clear at high moisture contents at 27 MHz and became negligible at 915 MHz for all moisture contents and temperatures. The penetration depth decreased with increasing frequency, temperature and moisture content, which was large enough at 27 MHz to develop large-scale industrial RF treatments.
Dielectric property data are important in developing thermal treatments using radio frequency (RF) and microwave (MW) energy and essential to estimate the heating uniformity in electromagnetic fields. Dielectric properties of flour samples from four legumes (chickpea, green pea, lentil, and soybean) at four different moisture contents were measured using an open-ended coaxial probe and impedance analyzer at frequencies of 10 to 1800 MHz and temperatures of 20 to 90°C. The dielectric constant and loss factor of the legume samples decreased with increasing frequency but increased with increasing temperature and moisture content. At low frequencies and high temperatures and moisture contents, negative linear correlations were observed between the loss factor and the frequency on a log-log plot, which was mainly caused by the ionic conductance. At 1800 MHz, the dielectric property data could be used to estimate the legume sample density judging from high linear correlations. Loss factors for the four legume samples were similar at 27 MHz, 20°C and low moisture contents (e.g. <15%). At the highest moisture content (e.g., 20%) soybean had the highest loss factor at 27 MHz and 20°C, followed by green pea, lentil and chickpea. The difference in loss factor among the four legumes did not show clear patterns at 915 MHz. Deep penetration depths at 27 MHz could help in developing large-scale industrial RF treatments for postharvest insect control or other applications that require bulk heating in legumes with acceptable heating uniformity and throughputs.