Engineering biomass heterogeneity of puffed rice into optimal pore topology for high-performance supercapacitors

Dengfeng Yu; Feifei Sun; Gongyuan Zhao; Yuanlin Wang; Miao Yu; Ye Sun

doi:10.1016/j.jpowsour.2025.238514

Engineering biomass heterogeneity of puffed rice into optimal pore topology for high-performance supercapacitors

Dengfeng Yu
, Feifei Sun
, Gongyuan Zhao
, Yuanlin Wang
, Miao Yu^*
, Ye Sun^*

^*Corresponding author for this work

Harbin Institute of Technology
School of Chemistry and Chemical Engineering, Harbin Institute of Technology
University of Electronic Science and Technology of China

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

Rational pore architecture—featuring optimal size distribution, interconnected frameworks, and maximized accessible surface area—is critical to achieve high energy density without compromising power density. Biomass-derived porous carbons are known for their natural hierarchical porosity, self-doped heteroatoms, cost-effectiveness, and sustainability, yet suffering from unbalanced macro-/micro-pore ratios and unresolved template-activation tradeoffs. Herein, we report a puffed rice-derived three-dimensional honeycomb-like hierarchical porous carbon (HPC) via synergistic KOH activation and MnO sacrificial templating, producing an interconnected porous network with an ultrahigh specific surface area (3107 m² g⁻¹) and optimized ion transport pathways. The HPC delivers capacitances as high as 676 F g⁻¹(1 A g⁻¹, three-electrode) and 409 F g⁻¹(0.1 A g⁻¹, two-electrode) in 6 M KOH, with outstanding rate capability (75.3 % retention at 10 A g⁻¹) and cycling stability (93.7 % retention after 100,000 cycles). As a symmetric supercapacitor using EMIMBF₄electrolyte, HPC achieves 123.8 Wh kg⁻¹at 450 W kg⁻¹and retains 104 Wh kg⁻¹even at 12,600 W kg⁻¹. This work represents a paradigm shift in biomass utilization by converting inherent biological heterogeneity into a structural advantage through controlled pore engineering.

Original language	English
Article number	238514
Journal	Journal of Power Sources
Volume	660
DOIs	https://doi.org/10.1016/j.jpowsour.2025.238514
State	Published - 30 Dec 2025
Externally published	Yes

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy

Keywords

High energy density
Pore engineering
Porous carbon
Supercapacitors

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10.1016/j.jpowsour.2025.238514

Cite this

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title = "Engineering biomass heterogeneity of puffed rice into optimal pore topology for high-performance supercapacitors",

abstract = "Rational pore architecture—featuring optimal size distribution, interconnected frameworks, and maximized accessible surface area—is critical to achieve high energy density without compromising power density. Biomass-derived porous carbons are known for their natural hierarchical porosity, self-doped heteroatoms, cost-effectiveness, and sustainability, yet suffering from unbalanced macro-/micro-pore ratios and unresolved template-activation tradeoffs. Herein, we report a puffed rice-derived three-dimensional honeycomb-like hierarchical porous carbon (HPC) via synergistic KOH activation and MnO sacrificial templating, producing an interconnected porous network with an ultrahigh specific surface area (3107 m2 g−1) and optimized ion transport pathways. The HPC delivers capacitances as high as 676 F g−1(1 A g−1, three-electrode) and 409 F g−1(0.1 A g−1, two-electrode) in 6 M KOH, with outstanding rate capability (75.3 \% retention at 10 A g−1) and cycling stability (93.7 \% retention after 100,000 cycles). As a symmetric supercapacitor using EMIMBF4electrolyte, HPC achieves 123.8 Wh kg−1at 450 W kg−1and retains 104 Wh kg−1even at 12,600 W kg−1. This work represents a paradigm shift in biomass utilization by converting inherent biological heterogeneity into a structural advantage through controlled pore engineering.",

keywords = "High energy density, Pore engineering, Porous carbon, Supercapacitors",

author = "Dengfeng Yu and Feifei Sun and Gongyuan Zhao and Yuanlin Wang and Miao Yu and Ye Sun",

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AU - Yu, Dengfeng

AU - Sun, Feifei

AU - Zhao, Gongyuan

AU - Wang, Yuanlin

AU - Yu, Miao

AU - Sun, Ye

PY - 2025/12/30

Y1 - 2025/12/30

N2 - Rational pore architecture—featuring optimal size distribution, interconnected frameworks, and maximized accessible surface area—is critical to achieve high energy density without compromising power density. Biomass-derived porous carbons are known for their natural hierarchical porosity, self-doped heteroatoms, cost-effectiveness, and sustainability, yet suffering from unbalanced macro-/micro-pore ratios and unresolved template-activation tradeoffs. Herein, we report a puffed rice-derived three-dimensional honeycomb-like hierarchical porous carbon (HPC) via synergistic KOH activation and MnO sacrificial templating, producing an interconnected porous network with an ultrahigh specific surface area (3107 m2 g−1) and optimized ion transport pathways. The HPC delivers capacitances as high as 676 F g−1(1 A g−1, three-electrode) and 409 F g−1(0.1 A g−1, two-electrode) in 6 M KOH, with outstanding rate capability (75.3 % retention at 10 A g−1) and cycling stability (93.7 % retention after 100,000 cycles). As a symmetric supercapacitor using EMIMBF4electrolyte, HPC achieves 123.8 Wh kg−1at 450 W kg−1and retains 104 Wh kg−1even at 12,600 W kg−1. This work represents a paradigm shift in biomass utilization by converting inherent biological heterogeneity into a structural advantage through controlled pore engineering.

AB - Rational pore architecture—featuring optimal size distribution, interconnected frameworks, and maximized accessible surface area—is critical to achieve high energy density without compromising power density. Biomass-derived porous carbons are known for their natural hierarchical porosity, self-doped heteroatoms, cost-effectiveness, and sustainability, yet suffering from unbalanced macro-/micro-pore ratios and unresolved template-activation tradeoffs. Herein, we report a puffed rice-derived three-dimensional honeycomb-like hierarchical porous carbon (HPC) via synergistic KOH activation and MnO sacrificial templating, producing an interconnected porous network with an ultrahigh specific surface area (3107 m2 g−1) and optimized ion transport pathways. The HPC delivers capacitances as high as 676 F g−1(1 A g−1, three-electrode) and 409 F g−1(0.1 A g−1, two-electrode) in 6 M KOH, with outstanding rate capability (75.3 % retention at 10 A g−1) and cycling stability (93.7 % retention after 100,000 cycles). As a symmetric supercapacitor using EMIMBF4electrolyte, HPC achieves 123.8 Wh kg−1at 450 W kg−1and retains 104 Wh kg−1even at 12,600 W kg−1. This work represents a paradigm shift in biomass utilization by converting inherent biological heterogeneity into a structural advantage through controlled pore engineering.

KW - High energy density

KW - Pore engineering

KW - Porous carbon

KW - Supercapacitors

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DO - 10.1016/j.jpowsour.2025.238514

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JO - Journal of Power Sources

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ER -

Engineering biomass heterogeneity of puffed rice into optimal pore topology for high-performance supercapacitors

Abstract

UN SDGs

Keywords

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