A sponge that filters hot air and captures carbon dioxide
Deanna D’Alessandro, The University of Sydney (credit: L’Oréal Australia/sdpmedia.com.au)
We need better ways of capturing carbon dioxide emissions from power stations and industry. And we won’t be using hydrogen cars until we’ve developed practical ways of carrying enough hydrogen gas in the fuel tank. Deanna D’Alessandro’s understanding of basic chemistry has led her to create new, incredibly absorbent chemicals that could do both these jobs and much more.
It’s all to do with surface area. Working in California and in Sydney she has constructed crystals that are full of minute holes. One teaspoon of the most effective of her chemicals has the surface area of a rugby field. What’s more, the size and shape of the pores can be customised using light. So she believes she can create molecular sponges that will mop up carbon dioxide, hydrogen, or in theory almost any gas – and then release it on cue. Continue reading Mopping up gases→
The Australian National University, Canberra/The University of Melbourne
Rowena Martin, The Australian National University, Canberra/The University of Melbourne (credit: L’Oréal Australia/sdpmedia.com.au)
In the 1950s it seemed as if medical science was winning the fight against malaria with the help of the ‘wonder drug’ chloroquine. Over the past half century the drug has saved hundreds of millions of lives.
But now the parasite that causes malaria has fought back. Chloroquine-resistant malaria has become common in developing countries. Rowena Martin is working to understand what happened, and to develop new ways of treating malaria. Continue reading Fighting back against malaria→
Walter and Eliza Hall Institute of Medical Research
Most women in Australia who have breast cancer recover. But many then relapse years later.
Rowena Martin, The Australian National University, Canberra/The University of Melbourne (credit: L’Oréal Australia/sdpmedia.com.au)
Marie-Liesse Asselin-Labat wants to know why. If she can solve this mystery, her work will open up opportunities for new drugs and treatments. Her achievements to date suggest that she is well placed to succeed.
In 2006 she was part of the Walter and Eliza Hall Institute of Medical Research team that received global attention for its discovery of breast stem cells – a significant step in understanding how breast cancer starts. Marie-Liesse built on this finding with a series of papers exploring how these cells develop and are influenced by oestrogen and other steroids. Continue reading How does breast cancer start?→
Since 1998, a public-private partnership between L’Oréal and UNESCO has promoted women in science. The L’Oréal-UNESCO Awards For Women in Science recognises outstanding women researchers who have contributed to scientific progress.
Marnie Blewitt wants to understand how genes are controlled. Credit: Sam D’Agostino, SDP Photo
Dr Marnie Blewitt wants to know how a human being is made: how does a single fertilised egg develop into an adult with millions of cells performing a myriad of different functions.
“How does a cell know which of its 30,000 or so genes should be active and which should be dormant?” says Marnie, a researcher at the Walter and Eliza Hall Institute of Medical Research.
Tamara Davis is looking for dark energy. Credit: timothyburgess.net
In 1998 astronomers made an astonishing discovery—the expansion of the Universe is accelerating. The discovery required a complete rethink of the standard model used to explain how the Universe works.
“Now we know that stars, planets, galaxies and all that we can see make up just four per cent of the Universe,” says Dr Tamara Davis, a University of Queensland astrophysicist.
“About 23 per cent is dark matter. The balance is thought to be dark energy, which we know very little about.”
Zenobia Jacobs, University of Wollongong. Credit: timothyburgess.net
Dr Zenobia Jacobs wants to know where we came from, and how we got here. When did our distant ancestors leave Africa and spread across the world? Why? And when was Australia first settled?
Zenobia Jacobs wants to know where we came from, and how we got here. When did our distant ancestors leave Africa and spread across the world? Why? And when was Australia first settled?
These are difficult and controversial questions. But Zenobia has a deep understanding of time and how to measure it. She has developed a way of accurately dating when individual grains of sand were buried with human artefacts. And that technique is transforming our understanding of human evolution.
University of Queensland / University of Copenhagen
In 1998 astronomers made an astonishing discovery-the expansion of the Universe is not happening at a steady rate, nor is it slowing down toward eventual collapse. Instead, it is accelerating. The discovery required a complete rethink of the standard model used to explain how the Universe works.
“Now we know that stars, planets, galaxies and all that we can see make up just four per cent of the Universe,” says Tamara Davis, a University of Queensland astrophysicist.
“About 23 per cent is dark matter. The balance is thought to be dark energy, which we know very little about.”
Why are some plant seeds very small and others large? Angela Moles tackled this simple question by compiling information on 12,669 plant species. She discovered that plant seeds in the tropics are, on average, 300 times bigger than seeds in colder places like the northern coniferous forests. She then used these data to follow the evolutionary history of seed size over hundreds of millions of years.
Angela Moles working with plants (Photo credit: L’Oréal/SDP Photo)
The study was the first of its kind and the results, published in Science and PNAS, have revolutionised our understanding of the factors that determine the size of offspring in plants and animals. Angela is a leader in developing a new approach to ecology—one that could allow us to accurately model and predict the impact of climate change on ecosystems. Continue reading Big ecology: From tundra to savanna→
Hundreds of Aussie science achievements that you can share in speeches, posts and publications
