基于轻木Janus木基水伏发电机的设计与性能

doi:10.11707/j.1001-7488.LYKX20250681

摘要/Abstract

摘要：

目的: 通过化学改性方法，将天然轻木制备成一种具有非对称结构的Janus木基功能材料，使其具备优异的水伏发电性能，从而减少水伏技术对不可降解或昂贵纳米材料的依赖，为发展高性能、长寿命的木基水伏发电机提供新的设计思路。方法: 选用天然轻木作为基底，沿垂直于树木生长方向切割，保留其天然微观通道以及本征各向异性结构。利用TEMPO氧化反应，在木材纤维表面选择性引入带负电的羧基基团；通过柠檬酸酯化反应进行进一步功能化，在材料内部构筑不同的电荷密度。将不同改性程度的木材组合，构建具备显著电荷密度差异、稳固微观结构以及绿色简化制备工艺的Janus结构水伏发电机。结果: 微观结构分析表明，改性后的木材内部形成高度有序、定向排列的离子纳米通道，且通道内壁富含可解离的羧基等官能团，为离子的选择性快速输运提供了理想路径。基于该Janus木基材料的水伏发电机，其开路电压最高达184 mV，是天然轻木（输出电压仅为53 mV）的3.5倍，输出功率密度达0.29 nW·cm^?2。将7个该水伏发电单元进行串联集成，累计输出电压可达1.44 V，能够成功驱动一台小型计算器稳定工作，初步证明其在为微型电子设备供电方面的实用潜力。结论: 本研究通过两步连续化学改性构建Janus梯度结构的新策略，成功将天然轻木转化为高性能水伏发电材料，不仅为开发低成本、可生物降解的绿色能源转换器件提供了新的材料设计思路，也展现出木质基功能材料在可持续能源领域的巨大应用前景。

关键词: 天然轻木, 水伏发电, 双层结构, TEMPO氧化, 酯化改性

Abstract:

Objective: The purpose of this study is to prepare natural wood into a Janus wood-based functional material with an asymmetric structure via chemical modification methods, so as to endow it with excellent hydrovoltaic power generation performance, thereby reducing the dependence of hydrovoltaic technology on non-degradable or expensive nanomaterials, and providing new design ideas for the development of high-performance and long-life wood-based hydrovoltaic generators. Method: Natural balsa wood was selected as the substrate and cut along the direction perpendicular to the growth of trees to retain its natural micro-channels and expose the intrinsic anisotropic structure. Firstly, the negatively charged carboxyl groups were selectively introduced on the surface of wood fiber by TEMPO oxidation reaction. Further functionalization was performed by citric acid esterification reaction to construct different charge densities within the material. Subsequently, two kinds of wood with different degrees of modification were assembled to successfully prepare a water volt generator with Janus structure with significant differences in charge density, stable microstructure, and green simplified preparation process. Result: The microstructure analysis showed that highly ordered and aligned ion nanochannels were formed inside the modified wood, and the inner wall of the channel was rich in functional groups such as dissociative carboxyl groups, which provided an ideal path for the selective and rapid transport of ions. The open circuit voltage of the water volt generator based on the Janus wood-based material was able to reach up to 184 mV, which is about 3.5 times that of the natural wood (the output voltage is only 53 mV). At the same time, its output power density was increased to 0.29 nW·cm^?2. With seven water volt power generation units integrated in series, the cumulative output voltage was able to reach as high as 1.44 V, which can successfully drive a small calculator to work stably, which preliminarily proves its practical potential in power supply for micro-electronic devices. Conclusion: This work has successfully transformed natural wood into high-performance hydrovoltaic power generation materials through a novel strategy of two-step continuous chemical modification to construct a Janus gradient structure. This study not only provides a new material design idea for the development of low-cost, biodegradable green energy conversion devices, but also shows the great application prospects of wood-based functional materials in the field of sustainable energy.

Key words: natural balsa wood, hydrovoltaic generator, double-layer structure, TEMPO oxidation, esterification modification

中图分类号:

S785

曲婉婷,周昊,彭锋,陈阁谷. 基于轻木Janus木基水伏发电机的设计与性能[J]. 林业科学, 2026, 62(6): 216-223.

Wanting Qu,Hao Zhou,Feng Peng,Gegu Chen. Design and Performance of Balsa-Based Janus Wood Hydrovoltaic Generator[J]. Scientia Silvae Sinicae, 2026, 62(6): 216-223.

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