A Study on the Feasibility of Replacing Conductive Materials with Carbonized Wood

Yun Yeong Kwak; Min Ji Kim; Jin Ho Seo

doi:10.7584/JKTAPPI.2025.4.57.2.81

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2025 Vol.57, Issue 2 Preview Page

Original Paper

A Study on the Feasibility of Replacing Conductive Materials with Carbonized Wood 탄화목을 활용한 전도성 물질 대체 가능성 연구

30 April 2025. pp. 81-90

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Abstract

The increasing incidence of wildfires has resulted in a substantial accumulation of wildfire-charred wood, most of which remains underutilized. This study investigated the potential of carbonized wood as a conductive material by fabricating conductive paper using wood carbonized at 1,000°C for 1 hour and multi-walled carbon nanotubes (MWCNTs). FE-SEM analysis showed that a higher content of charred wood resulted in irregular particle formation, disrupting the MWCNT network. FT-IR analysis confirmed modifications in functional groups, while surface resistance measurements showed increased electrical resistance and reduced electrical conductivity with higher charred wood content. However, additional dip coating cycles improved electrical conductivity by improving material contacts and electron transport pathways. These results indicate that wildfire-charred wood is a promising candidate for conductive applications and provide valuable insights into optimizing material composition for improved performance.

Keywords

Carbonization

wildfire damaged wood

electrical conductivity

conductive material

References

Jeong, K. O. and Kim, D. J., A study on the improvement of safety management by analyzing the current status and response system of forest fire accidents, Journal of the Society of Disaster 18(3):457-469 (2022).

10.15683/kosdi.2022.9.30.457

Park, E. H., Kim, M. H., Han, J. H., Yoo, H. J., Yang, S. H., Kim, S. M., Kim, A. Y., Won, D. J., and Kim, S. W., Light-absorption properties of fresh biomass burning aerosols observed at the Anmyeondo global atmosphere watch (GAW) regional station: A case study in April 2023, Journal of Korean Society for Atmospheric Environment 40(6):614-627 (2024).

10.5572/KOSAE.2024.40.6.614

Park, J. H., Park, B. S., Shim, K. B., and Jo, T. S., Variation of material properties of fire-killed timber (I) - Mechanical properties of fire-killed Korean red pine in the east coast area, Journal of the Korean Wood Science and Technology 33(6):8-16 (2005).

Park. J. H., Kim, K. M., Lee, D. S., and Park, B. S., Variation of material properties of fire-killed timber (II) - Impact of time on degradation of mechanical properties, Journal of the Korean Wood Science and Technology 36(6):30-35 (2008).

10.5658/WOOD.2008.36.1.030

Marttila, J., Mottonen, V., Haapala, A., Ylimaki, P., Kilpelainen, P., and Verkasalo, E., Wood material properties of forest fire-damaged Norway spruce and Scots pine for mechanical wood processing in Finland, Applied Sciences 14(1):238 (2023).

10.3390/app14010238

Kwon, S. M., Cho, J. H., Lee, S. J., Kwon, G. J., Hwang, B. H., Lee, G. H., Han, G. S., Cha, D. S., and Kim, N. H., Evaluation for wood pellets from Pinusdensiflora wood damaged by forest fire, Journal of the Korean Wood Science and Technology 35(4):14-20 (2007).

Yang, A. R., Hwang, J. H., Cho, M. S., and Song, S. W., Soil physical and chemical properties with plantation regions and stand age in Pinusrigida and Larixkaempferi plantations, Journal of Korean Forest Society 102(4):578-586 (2013).

10.14578/jkfs.2013.102.4.578

Ju, Y. K. and Lee, J. H., A study on the problems and improvement by analyzing the disastrous large-scale forest fire response system: Focused on simultaneous forest fires along the east coast, Journal of Safety and Crisis Management 12(5):21-28 (2022).

10.14251/jscm.2022.5.21

Lee, Y. E., Song, J. H., Im, S. J., Kwon, K. N., and Kwon, C. G., An examination of the fire behavior of Pinusdensiflora fuel beds with thinning intensity, Journal of Korean Society of Forest Science 113(3):308-318 (2024).

10.14578/jkfs.2024.113.3.308

Plavniece, L., Dobele, G., Volperts, A., and Zhurinsh, A., Hydrothermal carbonization vs. pyrolysis: Effect on the porosity of the activated carbon materials, Sustainability 14(23):15982 (2022).

10.3390/su142315982

Yerdauletov, M., Nazarov, K., Mukhametuly, B., Yeleuov, M. A., Daulbayev, C., Abdulkarimova, R., Yskakov, A., Napolskiy, F., and Krivchenko, V., Characterization of activated carbon from rice husk for enhanced energy storage devices, Molecules 28(15):5818 (2023).

10.3390/molecules2815581837570791PMC10421275

Khan, T. A., Kim, H. J., Gupta, A., Jamari, S. S., and Jose, R., Synthesis and characterization of carbon microspheres from rubber wood by hydrothermal carbonization, Journal of Chemical Technology & Biotechnology 94(5):1355-1689 (2019).

10.1002/jctb.5867

Zhao, C., Liu, X., Chen, A., Chen, J., Lv, W., and Liu, X., Characteristics evaluation of bio-char produced by pyrolysis from waste hazelnut shell at various temperatures, Energy Sources, Part A: Recovery, Utilization, and Environmental Effects 46(1):1-11 (2020).

10.1080/15567036.2020.1754530

Dobele, G., Volperts, A., Plavniece, A., Zhurinsh, A., Upskuviene, D., Balciunaite, A., Niaura, G., Colmenares-Rausseo, L. C., Tamasauskaite-Tamasiunaite, L., and Norkus, Eugenijus., Thermochemical activation of wood with NaOH, KOH and H₃PO₄ for the synthesis of nitrogen-doped nanoporous carbon for oxygen reduction reaction, Molecules 29(10):2238 (2024).

10.3390/molecules2910223838792100PMC11124516

Peng, X., Zhang, L., Chen, Z., Zhong, L., Zhao, D., Chi, X., Zhao, X., Li, L., Lu, X., Leng, K., Liu, C., Liu, W., Tang, W., and Loh, K. P., Hierarchically porous carbon plates derived from wood as bifunctional ORR/OER electrode, Advanced Materials 31(16):1900341 (2019).

10.1002/adma.20190034130843289

Chen, C., Zhang, Y., Li, Y., Dai, J., Song, J., Yao, Y., Gong, Y., Kierzewski, J., Xie, J., and Hu, L., All-wood, low tortuosity, aqueous, biodegradable supercapacitors with ultra-high capacitance, Energy & Environmental Science 10(2):538-545 (2017).

10.1039/C6EE03716J

Chen, C., Kuang, Y., Zhu, S., Burgert, I., Keplinger, T., Gong, A., Li, T., Berglund, L., Eichhorn, S. J., and Hu, L., Structure-property-function relationships of natural and engineered wood, Nature Reviews Materials 5(9):642-666 (2020).

10.1038/s41578-020-0195-z

Bui, D. N. and Son, Y. G., Effect of MWCNT type and flow type on the electrical conductivity of polycarbonate/MWCNT nanocomposites, Journal of the Korea Academia-Industrial Cooperation Society 19(9):13-19 (2018).

10.5762/KAIS.2018.19.9.13

Ajayan, P. M., Nanotubes from carbon, Chemical Reviews 99:1787-1800 (1999).

10.1021/cr970102g11849010

Sinnott, B. S., Chemical functionalization of carbon nanotubes, Journal of Nanoscience and Nanotechnology 2:113-123 (2002).

10.1166/jnn.2002.10712908295

Kim, B. Y., Characteristics of electroconductive paper manufactured with carbon fiber, Journal of KTAPPI 41(3):29-34 (2009).

Kim, B. Y., Accelerated aging characteristics of electroconductive paper, Journal of KTAPPI 43(2):24-30 (2011).

Kim, H. J. and Um, G. J., The manufacturing of electromagnetic shielding sheet using the carbon and wood fiber mixture, Journal of KTAPPI 38(4):68-75 (2006).

Lee, C. S., Lee, W. K., Yoon, J. H., and Song, C. C., Distribution pattern of Pinusdensiflora and Quercus Spp. stand in Korea using spatial statistics and GIS, Journal of Korean Forest Society 95(6):663-671 (2006).

Jee, M. H. and Baik, D. H., Morphological and electrical properties of multi-walled carbon nanotube-based fiber using general wet-spinning and alkaline post-treatment methods, Fibers and Polymers 21(11):2456-2461 (2020).

10.1007/s12221-020-0942-1

Kumar, M., Xiong, X., Wan, Z., Sun, Y., Tsang, D. C. W., Gupta, J., Cao, B., Cao, X., Tang, J., and Ok, Y. S., Ball milling as a mechanochemical technology for fabrication of novel biochar nanomaterials, Bioresource Technology 312:123613 (2020).

10.1016/j.biortech.2020.12361332513509

Wang, X., Fang, Q., Zheng, T., Xu, Y., Dai, R., Qiao, Z., Ruan, D., and Wang, Y., Enhancing sodium-ion energy storage of commercial activated carbon by constructing closed pores via ball milling, Nanomaterials 14(1):65 (2023).

10.3390/nano1401006538202519PMC10780331

Singh, S., Pei, Y. Q., Miller, R., and Sundararajan, P. R., Long-range, entangled carbon nanotube networks in polycarbonate, Advanced Functional Materials 13(11):868-872 (2003).

10.1002/adfm.200304411

Stavarache, I., Lepadatu, A. M., Teodorescu, V. S., Ciurea, M. L., Iancu, V., Dragoman, M., Konstantinidis, G., and Buiculescu, R., Electrical behavior of multi-walled carbon nanotube network embedded in amorphous silicon nitride, Nanoscale Research Letters 6(1):88 (2011).

10.1186/1556-276X-6-8821711608PMC3212237

Jiang, Z., Chen, D., Yu, Y., Miao, J., Liu, Y., and Zhang, L., Composite fibers prepared from multi-walled carbon nanotubes/cellulose dispersed/dissolved in ammonium/dimethyl sulfoxide mixed solvent, RSC Advances 7(4):2186-2192 (2017).

10.1039/C6RA25318K

Atieh, M. A., Bakather, O. Y., Al-Tawbini, B., Bukhari, A. A., Abuilaiwi, F. A., Fettouhi, M. B., Effect of carboxylic functional group functionalized on carbon nanotubes surface on the removal of lead from water, Bioinorganic Chemistry and Applications 2010(11):603978 (2010).

10.1155/2010/60397821350599PMC3038556

Montanheiro, T. L. A., Cristóvan, F. H., Machado, J. P. B., Tada, D. B., Durán, N., and Lemes, A. P., Effect of MWCNT functionalization on thermal and electrical properties of PHBV/MWCNT nanocomposites, Journal of Materials Research 30(01):55-65 (2014).

10.1557/jmr.2014.303

Qi, H., Liu, J., and Mäder, E., Smart cellulose fibers coated with carbon nanotube networks, Fibers 2(4):295-307 (2014).

10.3390/fib2040295

Information

Publisher :Korea Technical Association of The Pulp and Paper Industry
Publisher(Ko) :한국펄프종이공학회
Journal Title :Journal of Korea TAPPI
Journal Title(Ko) :펄프종이기술
Volume : 57
No :2
Pages :81-90
Received Date : 2025-04-04
Revised Date : 2025-04-18
Accepted Date : 2025-04-21
DOI :https://doi.org/10.7584/JKTAPPI.2025.4.57.2.81

Journal of Korea TAPPI ISSN:0253-3200(Print) 펄프종이기술

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