Molecular-Level Precursor Engineering Enables High Utilization of Closed Nanopores in Hard Carbon for Sodium-Ion Batteries

IF 7.4 1区化学 Q1 CHEMISTRY, MULTIDISCIPLINARY

Chemical Science Pub Date : 2026-04-17 DOI:10.1039/d6sc01648k

Rui Li, Beilei Yuan, Yupeng Feng, Yuhan Li, Na Jiang, Ping Liu, Liangzhi Li, Weiyue Li, Chunwei Dong, Shuchun Hu, Qi Liu, Jian Chen, Fei Li, Jianping Long, Anjun Hu

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Abstract

Closed nanopores in hard carbon (HC) are widely regarded as the primary host for low-voltage plateau capacity in sodium-ion batteries, yet their electrochemical inactivity due to poor accessibility remains a critical bottleneck. Here we report a molecular-templating liquid-phase carbonization strategy that engineers biomass precursors with sodium acetate to unlock closed-pore utilization. Sodium acetate simultaneously enriches oxygen-containing functionalities and generates molecular-scale pre-pores during liquid-phase carbonization, enabling controllable closed-pore density and size in bamboo-derived HC. Upon high-temperature treatment, these pre-pores evolve into percolating mesoporous channels that bridge otherwise isolated closed nanopores, thereby constructing an efficient ion-transport network and markedly shortening the solid-state diffusion distance. As a result, the closed-pore utilization reaches 86%, delivering a substantially enhanced plateau contribution together with an expanded interlayer spacing (d₀₀₂ = 0.391 nm). The optimized HC exhibits a high reversible capacity of 369 mAh g^-1 at 0.1C with 88.9% initial Coulombic efficiency, retains ~85% capacity after 500 cycles at 2 C, and maintains 257 mAh g^-1 at -20 °C. This work establishes a molecular-level precursor-engineering route to transform closed pores from “present” to “accessible”, providing a general design principle for high-energy HC anodes.

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分子水平前体工程使钠离子电池中硬碳纳米孔的高利用率成为可能

硬碳（HC）中的封闭纳米孔被广泛认为是钠离子电池低压平台容量的主要宿主，但由于其不易接近而导致的电化学不活性仍然是一个关键瓶颈。在这里，我们报告了一种分子模板液相碳化策略，用乙酸钠工程生物质前体来解锁闭孔利用。在液相碳化过程中，乙酸钠同时丰富了含氧官能团，并产生了分子尺度的预孔，使竹源HC的闭孔密度和大小可控。经过高温处理后，这些预孔演变成渗透性介孔通道，桥接孤立的封闭纳米孔，从而构建有效的离子传输网络，显著缩短固态扩散距离。结果，闭孔利用率达到86%，平台贡献显著增强，层间间距扩大（d002 = 0.391 nm）。优化后的HC在0.1C时具有369 mAh g-1的高可逆容量，初始库仑效率为88.9%，在2℃下循环500次后容量保持~85%，在-20℃时保持257 mAh g-1。本研究建立了一种分子水平的前体工程路线，将封闭孔隙从“存在”转变为“可达”，为高能HC阳极的设计提供了一般原则。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Chemical Science CHEMISTRY, MULTIDISCIPLINARY-

CiteScore

14.40

自引率

4.80%

发文量

1352

审稿时长

2.1 months

期刊介绍： Chemical Science is a journal that encompasses various disciplines within the chemical sciences. Its scope includes publishing ground-breaking research with significant implications for its respective field, as well as appealing to a wider audience in related areas. To be considered for publication, articles must showcase innovative and original advances in their field of study and be presented in a manner that is understandable to scientists from diverse backgrounds. However, the journal generally does not publish highly specialized research.