Skip Navigation  |  
    
0
Skip Navigation | ANU Home | Search ANU | HORUS
The Australian National University
Research School of Physical Sciences and Engineering
ANU College of Science
RSPhysSE
RSPhysSE Home
Student Opportunities
Positions Vacant
Administration & Internal Information
Weekly Bulletin
Virtual Tour
History
Images
Annual Report
Research Areas
Contact Us
Departments
Applied Mathematics
Atomic & Molecular Physics
Electronic Materials Engineering
Laser Physics
Nonlinear Physics
Nuclear Physics
Plasma Research
Theoretical Physics
Optical Sciences Group
Links
Oliphant Endowment Fund
Centres, CRCs & Networks
College of Science
University OH&S
School Support Services
RSPhysSE Webmail
Printer Friendly Version of this Document

Cleanroom Science on the Road to Cleaner Air

Team members with the pressurised glove box used for sample preparation
Ball milling of graphite powder may the key to efficient production of carbon nanotubes such as those pictured in image 3
carbon nanotubes seen through an electron microscope

Jun Yu, Hua Chen, Lewis T Chadderton, Jim S Williams, Yong Jun Chen, Hongzhou Zhang, Bill Li, Tom Halstead, Alexey Glushenkov, Ying Chen

Rising world oil prices and concerns about greenhouse gas emissions are increasing pressure to find a viable alternative to petrol and diesel as transport fuels. One very promising candidate is hydrogen which can be combined with atmospheric oxygen in fuel cells to produce the large quantities of electrical power required to drive a car. Hydrogen is a very attractive transport fuel because it is abundant, renewable and its consumption in fuel cells produces no greenhouse emissions at all.

The difficulty to date has been devising a safe way to store the volatile gas in a motor vehicle. Both gas cylinders and hydrogen liquid in cryogenic containers present an explosion hazard in the event of an accident. One revolutionary option for hydrogen storage is carbon nanotubes - microscopic cage like tubes of carbon atoms. Because of their structure and size the tubes have the ability to adsorb hydrogen gas in large quantities which can be re-released by mild heating. One stumbling block is that to date, manufacture of very large quantities of nanotubes has simply not been an economically viable proposition.

However work by scientists at the ANU may be set to change all this. A novel process involving high-energy ball milling followed by a series of carefully controlled annealing stages has enabled scientists to manufacture large quantities of nanotubes in carbon, boron nitride and other materials cheaply and easily. This ANU process is readily adaptable to manufacture of nanotubes on an industrial scale and has led to the first commercial availability of boron nitride tubes. It is now hoped that the ANU nanotube technology will be a crucial step on the road to hydrogen cars and a safer cleaner environment.

Research Highlight Poster

(pdf - 356.49 KB)
 
 

Back Home

Research Areas
 
 
Page last updated: 30 July 2007
Please direct all enquiries to: RSPhysSE Webmaster
Page authorised by: Director, RSPhysSE
The Australian National University — CRICOS Provider Number 00120C