Agustiningrum, D.A.; Siregar, I.Z.; Damayanti, R.; Taruno, W.P.; Nugraha, H.; Rohmadi, R.; Karlinasari, L. Electrical Properties at Multi-Frequencies for Analysis of Physical and Anatomical Properties of Fast-Growing Standing Teak Trees at Various Ages. Forests2024, 15, 669.
Agustiningrum, D.A.; Siregar, I.Z.; Damayanti, R.; Taruno, W.P.; Nugraha, H.; Rohmadi, R.; Karlinasari, L. Electrical Properties at Multi-Frequencies for Analysis of Physical and Anatomical Properties of Fast-Growing Standing Teak Trees at Various Ages. Forests 2024, 15, 669.
Agustiningrum, D.A.; Siregar, I.Z.; Damayanti, R.; Taruno, W.P.; Nugraha, H.; Rohmadi, R.; Karlinasari, L. Electrical Properties at Multi-Frequencies for Analysis of Physical and Anatomical Properties of Fast-Growing Standing Teak Trees at Various Ages. Forests2024, 15, 669.
Agustiningrum, D.A.; Siregar, I.Z.; Damayanti, R.; Taruno, W.P.; Nugraha, H.; Rohmadi, R.; Karlinasari, L. Electrical Properties at Multi-Frequencies for Analysis of Physical and Anatomical Properties of Fast-Growing Standing Teak Trees at Various Ages. Forests 2024, 15, 669.
Abstract
Fast-growing teak is widely cultivated in Indonesia to address the supply and demand of teak trees. However, efforts still need to be made to evaluate the condition of standing teak trees during their growth period. Studies on nondestructive testing (NDT) of wood based on electrical properties through dielectric spectroscopy (DS) are recently being developed, especially for standing tree evaluation. The study aimed to analyze the dielectric value of a fast-growing standing teak tree at frequency ranges 250 kHz – 60 MHz and to understand the relationships between physical and anatomical properties. Dielectric spectroscopy data were collected directly on the trees 4, 5, and 7 years old using a capacitance measurement system. Meanwhile, physical and anatomical samples were taken using a Ø 0.5 cm increment borer. The results showed that fiber length (FL), lumen diameter (LD), and fiber wall thickness (FWT) were significantly different at each tree age. This research found the optimal dielectric frequency to discriminate the wood properties in standing trees. There is a weak relationship (R= 0.2) in predicting the anatomical wood properties, while moderate to strong relationships (R= 0.4 to R= 0.8) are found in predicting wood density based on the selected frequency and moisture content variables. Further analyses and data processing can be improved by finding significant variables in the capacitance measurement system.
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