Deakin University

Australia

At Deakin University our researchers are making a positive impact on the lives and well-being of communities — not just in Australia, but around the world — through exceptional innovation and research.

Using our industry, government and institutional networks, we are building our global research footprint across four key themes, supported by four world-class Research Institutes and 13 Strategic Research Centres.

Improving health and wellbeing

Covering the broad spectrum of health, our research is helping to improve the lives and wellbeing of people and communities on a global scale. From medicine, ageing, chronic illness and disability, to nutrition, physical activity and child health, we're continually striving to uncover new frontiers through persistent curiosity and ground-breaking research.

Designing smarter technologies

Deakin is a world leader in carbon and short fibre, metals and steel research, electromaterials, corrosion, nanotechnology, composite materials and energy storage systems. Our open access carbon fibre/composite research facility, Carbon Nexus, is supporting the transition to advanced manufacturing, while engineering and IT researchers are providing robotics, simulation modelling and haptics solutions to clients across many sectors.

Enabling a sustainable world

Deakin leads one of the world’s most prestigious environmental and marine science research programs. Our scientists are helping to protect Australia’s vulnerable flora and fauna from disease, from rapid development and from climate change. In the agricultural sphere, teams of experts are providing water management advice and designing smart solutions to global challenges such as food security, sustainable agriculture and environmental sustainability.

Advancing society and culture

Our research is helping to advance understanding of intercultural relations, politics, migration, racism and governance. In education, researchers are cultivating society and culture by informing policy across all educational sectors, with an emphasis on developing partnerships and working toward achieving equity and social justice. Our creative arts researchers are also breaking new ground, often at the intersection between research, art and technology.

Deakin University retains sole responsibility for content © 2017 Deakin University.

1 August 2017 - 31 July 2018

Region: Global
Subject/journal group: All

The table to the right includes counts of all research outputs for Deakin University published between 1 August 2017 - 31 July 2018 which are tracked by the Nature Index.

Hover over the donut graph to view the FC output for each subject. Below, the same research outputs are grouped by subject. Click on the subject to drill-down into a list of articles organized by journal, and then by title.

Note: Articles may be assigned to more than one subject area.

AC FC
59 14.77

Outputs by subject (FC)

Subject AC FC
Chemistry 29 8.46
Life Sciences 16 3.02
Earth & Environmental Sciences 3 0.41
Physical Sciences 22 4.99
4 1.05
8 2.16
3 0.22
1 0.01
1 0.04
5 1.52

Highlight of the month

An icy grip on tissue engineering

© Johner Images/Getty

© Johner Images/Getty

Ice crystals could help tissue engineers create templates on which to grow replacement tissues for damaged body parts. 

Cells use many cues, including their physical surroundings, to grow into functioning tissues in the body. In muscle, for example, an extracellular scaffold of aligned collagen nanofibers helps muscle cells line up so they all pull in the same direction. Making artificial tissue scaffolds is challenging, because it is difficult to create networks of aligned nanofibers that also incorporate the pores that cells need to penetrate the scaffold and grow. Now, Deakin University researchers have used ice crystals to emulate these nanoscale pores.

When the team dunked a solution of silk strands into a beaker of liquid nitrogen, the high temperature gradient triggered the rapid formation of fine ice crystals aligned along that gradient. Silk strand nanofibers then grew along the crystals, forming an aligned nanofiber network. When this material was placed in a regular freezer, large ice crystals slowly grew between the nanofibers, creating a network of pores that remained when the scaffold was thawed.

Supported content

  1. ACS Nano 12, 5780–5790 (2018). doi: 10.1021/acsnano.8b01648

View the article on the Nature Index

See more research highlights from Deakin University

More research highlights from Deakin University

Top articles by Altmetric score in current window

Extinction risk is most acute for the world’s largest and smallest vertebrates

Proceedings of the National Academy of Sciences of the United States of America

2017-10-03

Global sea turtle conservation successes

Science Advances

2017-09-01

Convergence of marine megafauna movement patterns in coastal and open oceans

Proceedings of the National Academy of Sciences of the United States of America

2018-02-26

Child first language and adult second language are both tied to general-purpose learning systems

Proceedings of the National Academy of Sciences of the United States of America

2018-02-13

1 August 2017 - 31 July 2018

International vs. domestic collaboration by FC

  • 53.27% Domestic
  • 46.73% International

Note: Hover over the graph to view the percentage of collaboration.

Note: Collaboration is determined by the fractional count (FC), which is listed in parentheses.

Affiliated joint institutions and consortia

Return to institution outputs