利用选择性腐朽木材增强机械能转换。

Enhanced mechanical energy conversion with selectively decayed wood.

作者信息

Sun Jianguo, Guo Huizhang, Schädli Gian Nutal, Tu Kunkun, Schär Styfen, Schwarze Francis W M R, Panzarasa Guido, Ribera Javier, Burgert Ingo

机构信息

Wood Materials Science, Institute for Building Materials, ETH Zürich, 8093 Zürich, Switzerland.

WoodTec Group, Cellulose & Wood Materials, EMPA, 8600 Dübendorf, Switzerland.

出版信息

Sci Adv. 2021 Mar 10;7(11). doi: 10.1126/sciadv.abd9138. Print 2021 Mar.

DOI:10.1126/sciadv.abd9138

PMID:33692104

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7946366/

Abstract

Producing electricity from renewable sources and reducing its consumption by buildings are necessary to meet energy and climate change challenges. Wood is an excellent "green" building material and, owing to its piezoelectric behavior, could enable direct conversion of mechanical energy into electricity. Although this phenomenon has been discovered decades ago, its exploitation as an energy source has been impaired by the ultralow piezoelectric output of native wood. Here, we demonstrate that, by enhancing the elastic compressibility of balsa wood through a facile, green, and sustainable fungal decay pretreatment, the piezoelectric output is increased over 55 times. A single cube (15 mm by 15 mm by 13.2 mm) of decayed wood is able to produce a maximum voltage of 0.87 V and a current of 13.3 nA under 45-kPa stress. This study is a fundamental step to develop next-generation self-powered green building materials for future energy supply and mitigation of climate change.

摘要

利用可再生能源发电并减少建筑物的电力消耗是应对能源和气候变化挑战的必要举措。木材是一种优质的“绿色”建筑材料，由于其压电行为，能够实现机械能直接转化为电能。尽管这一现象在数十年前就已被发现，但其作为能源的开发却因天然木材极低的压电输出而受阻。在此，我们证明，通过一种简便、绿色且可持续的真菌腐朽预处理来提高轻木的弹性压缩性，压电输出可提高55倍以上。一块边长为15毫米×15毫米×13.2毫米的腐朽木立方体在45千帕的应力下能够产生0.87伏的最大电压和13.3纳安的电流。本研究是开发下一代自供电绿色建筑材料以满足未来能源供应和缓解气候变化的重要基础步骤。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/a3d4/7946366/42cf672044ef/abd9138-F1.jpg

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利用选择性腐朽木材增强机械能转换。

Enhanced mechanical energy conversion with selectively decayed wood.

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