The University of Melbourne (UniMelb)



Established in 1853, the University of Melbourne is an international leader in research, learning and teaching — attracting students from more than 150 countries.

It is consistently ranked among the world’s leading universities, with international rankings placing it as number 1 in Australia and number 33 in the world (Times Higher Education World University Rankings 2015–2016).

The University of Melbourne’s success as a leading teaching and research organisation is based on the notion that our people are our point of difference. We strive to create and maintain a work environment which attracts and retains the best research workforce, including graduate researchers and professional staff who provide essential contributions to research.

Our academics are renowned researchers and industry leaders, recognised globally for their achievements. Our graduates are valued by employers across the world for their academic excellence, cross-cultural fluency, and active global citizenship.

Research at the University of Melbourne

Excellence in research is core to the University of Melbourne’s mission. The University is a globally-engaged, comprehensive, research-intensive university with the capacity to make significant contributions to global social, economic and environmental challenges.

The University of Melbourne is committed to nurturing scholarship, to developing new insights and promoting a wider understanding of the world in which we live. Through its ‘Research at Melbourne’ strategy, the University has committed to cherish and cultivate investigator-driven research in the fundamental enabling disciplines, while pursuing applied solutions to three Grand Challenges:

  • understanding our place and purpose
  • fostering health and wellbeing
  • supporting sustainability and resilience.

These Grand Challenges draw on the deep disciplinary expertise and scholarship of our researchers — who are working toward discoveries that contribute to the global reserve of knowledge, and inform major shifts in thinking. Importantly, the Grand Challenges are embedded across the University through its precincts and partnerships as well as through our international and graduate research training agenda.

The University of Melbourne retains sole responsibility for content © 2017 The University of Melbourne.

1 February 2016 - 31 January 2017

Region: Global
Subject/journal group: All

The table to the right includes counts of all research outputs for The University of Melbourne (UniMelb) published between 1 February 2016 - 31 January 2017 which are tracked by the Nature Index.

Hover over the donut graph to view the WFC 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.

556 102.13 85.29

Outputs by subject (WFC)

Subject AC FC WFC
Life Sciences 181 32.87 32.87
Earth & Environmental Sciences 21 5.48 5.48
Physical Sciences 307 41.87 25.03
Chemistry 68 31.76 31.76

Highlight of the month: The University of Melbourne (UniMelb)

Making superstructures from nanoparticles just like playing LEGO

© alwyncooper/E+/Getty

© alwyncooper/E+/Getty

Scientists have developed an inexpensive and versatile method for making modular building blocks from tiny particles, laying the foundations for new applications including drug delivery, chemical sensing and energy storage, according to a report published in Nature Nanotechnology.

Led by the University of Melbourne, a team of Australian and international researchers have developed a simple technique that transforms a variety of micro- and nanoparticles into LEGO brick-like components with different sizes, shapes, compositions and functionalities that can be used to create complex superstructures.

By first transforming the surface of the particles using a coating of polyphenol — an inexpensive and widely available adhesive — to resemble the ‘studs’ on LEGO bricks, and then using metal ions to interlock the particles, the researchers demonstrated a simple, cheap and modular approach for constructing superstructures, with lengths ranging from nanometres to centimetres.

  1. Nature Nanotechnology 11,1105–1112 (2016). doi: 10.1038/nnano.2016.172

View the article on the Nature Index

1 February 2016 - 31 January 2017

International vs. domestic collaboration by WFC

  • 29.06% Domestic
  • 70.94% International

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

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

Affiliated joint institutions and consortia

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