search

UMD    CORE




Image: Schematic and photographic illustration of the wood aerogel. (a) Graphical illustration of the highly compressible, anisotropic wood aerogel directly fabricated from natural wood via a simple chemical treatment. (b) Photo images of the natural wood before compressing, under compressing, and after release, respectively. (c) Photo images of the wood aerogel before compressing, under compressing, and after recovery, respectively. (d) Photo image of the lightweight and biodegradable wood aerogel

Image: Schematic and photographic illustration of the wood aerogel. (a) Graphical illustration of the highly compressible, anisotropic wood aerogel directly fabricated from natural wood via a simple chemical treatment. (b) Photo images of the natural wood before compressing, under compressing, and after release, respectively. (c) Photo images of the wood aerogel before compressing, under compressing, and after recovery, respectively. (d) Photo image of the lightweight and biodegradable wood aerogel

 

Aerogel is traditionally made of synthetic materials and is similar to glass, but has gas or air in its pores – only a few nanometers wide – instead of liquid. Aerogel boasts a low thermal conductivity – low density, too – which is why NASA uses the material to cool rocket fuel. Additional applications include bio-scaffolds, energy storage devices, sensors, cold-weather apparel and shoe inserts. Recently, bio-aerogels have been developed out of bacteria cellulose, pectin and watermelon – all using an inefficient, bottom-up approach. The consumption of both energy and time is significant in these bottom-up approaches, which prevents large-scale production.

Scientists in the University of Maryland (UMD) Department of Materials Science and Engineering (MSE), led by MSE Professor Liangbing Hu, took the opposite approach – they went ‘top-down’ to create an anisotropic – having a physical property that has a different value when measured in various directions – aerogel made entirely out of natural wood – balsa, in this case. Balsa – which has low density, high porosity and thin cell walls – makes it the lightest wood on Earth.

After a block of Balsa wood is immersed in a mixed chemical solution, “the lignin and hemicellulose of the natural wood are removed, while the alignment of cellulose nanofibers is preserved, leading to a layered structure of the wood aerogel,” Hu’s research team stated in their paper.  The result, in essence, is a wood sponge, which is lightweight, highly compressible and anti-fatigue.  Moreover, wood aerogel is eco-friendly, easily and cheaply produced, scalable and effective, offering a range of applications, such as thermal insulation, acoustic insulation, pollution adsorption, sensory equipment, energy storage devices and electronics.

For additional information:

Jianwei Song, Chaoji Chen, Zhi Yang, Yudi Kuang, Tian Li, Yiju Li, Hao Huang, Iain Kierzewski, Boyang Liu, Shuaiming He, Tingting Gao, Sevket U. Yuruker, Amy Gong, Bao Yang and Liangbing Hu. “Highly Compressible, Anisotropic Aerogel with Aligned Cellulose Nanofibers.”  ACS Nano, 2018, 12 (1), pp 140-147. DOI: 10.1021/acsnano.7b04246.  

 



Related Articles:
Sturdy Insulator Made of Wood

February 12, 2018


«Previous Story  

 

 

Current Headlines

Feathers Not Included

Pines Receives UMD President's Medal

Davis to Serve as Faculty Mentor for NSF-Funded Global STEWARDS Program

MTI App that Rewards Smart Commuting Featured in Washington Post

Are you ready to compete in the e-Bike student challenge?

UMD Wins Vertical Flight Society's Student Design Competition

Bioinspired robotics REU students present final projects

John Baras to receive 2018 AIAA Aerospace Communications Award

Laurence Wins NSF CAREER Award

AEROS Program Stronger Than Ever 

 
 
Back to top  
CORE Home Clark School Home UMD Home Aerospace Engineering