Overall

Language: English

Conflict of Interest: In relation to this article, we declare that there is no conflict of interest.

Publication history: Received June 4, 2025
Revised November 27, 2025
Accepted December 28, 2025
Available online April 25, 2026

This is an Open-Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/bync/3.0) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

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Char Contribution as Heterogeneous Reaction To NO Reduction During Rice Husk Reburning in a Drop Tube Furnace

Seungtae Oh^1† Jin Ki Lee² Myung Chul Shin² Ji Wan Kim³ Hyuk Jin Jang² Seong-Ju Kim^2†

Department of Mechanical and Automotive Engineering , Kongju National University ¹Global Institute of Manufacturing Technology (GITECH) , Kongju National University ²Low-Carbon Emission Control R&D Department, Research Institute of Sustainable Development Technology , Korea Institute of Industrial Technology ³Environment & Energy Engineering Team, Blast Furnace Business Division , Hyundai-Steel Company

stoh@kongju.ac.kr, seongju@kitech.re.kr

Korean Journal of Chemical Engineering, April 2026, 43(5), 1437-1446(10)
https://doi.org/10.1007/s11814-025-00639-2

Abstract

Biomass reburning has emerged as a promising method for reducing nitrogen oxide (NO) emissions. However, a comprehensive

understanding of reburning reactions using biomass remains limited. In particular, the char contribution to NO

reduction requires further clarifi cation, especially when using rice husk. This study investigates the contribution of rice

husk char to NO reduction during the reburning process in a drop-tube furnace. The eff ects of reaction temperature, NO

concentration, and equivalence ratio on the contribution of the homogeneous and heterogeneous reactions were analyzed.

Results showed that increasing the reburning temperature enhanced the heterogeneous reaction by promoting CO release

from the char surface, thereby increasing the char’s contribution to the overall reburning reaction. As the initial NO concentration

increased, NO reduction increased for both rice husk and its char; however, due to the limited amount of fuel

for reburning reactions, the rate of increase in NO reduction decreased. The homogeneous reaction decreased above a

certain equivalence ratio because oxygen limitation reduced the conversion of intermediate species into N 2 . In contrast,

the char reaction increased and eventually reached saturation with an increasing equivalence ratio, further enhancing char

contribution. These fi ndings provide valuable insights for optimizing biomass reburning systems, particularly by clarifying

the distinct role and operational dependencies of heterogeneous char-NO reactions.

Keywords

Char contribution · NO reduction · Rice husk · Reburning · Heterogeneous reaction