We can use Australia's vast energy resources to produce fuels like hydrogen. We're enabling this technology through a new Future Science Platform.

Australia is known for its vast energy resources. We’ve got ample sun, wind, biomass, natural gas and coal, and while these resources can be used effectively on their own, we can also use them to produce other energy sources, like hydrogen.

Why use one energy source to create another? Our future energy mix will consist of many different sources to ensure we have energy when and where it’s needed, in the cleanest form. Through hydrogen, we can effectively create low-emissions energy for our own use, store it for later, or transport it overseas where it’s in demand. It’s a way to use what we already have, but tailored for a particular purpose.

Water, water, everywhere (let’s turn it into hydrogen)

Hydrogen is all around us, just not quite in the form that we need. It’s the H2 in water (H20), the H4 in methane (CH4), the H22 in our table sugar (C12H22O11) … the list goes on. To isolate pure hydrogen, we need to force a reaction, and there are a few ways to do this:

  • Reforming: currently the most common way of producing pure hydrogen whereby heat is applied to natural gas, causing hydrogen atoms to be separated from the carbon atoms. Technologies such as carbon capture and storage (CCS) can be applied to this process to limit emissions.
  • Electrolysis: an electric current can be passed through water to separate hydrogen molecules from oxygen. Renewable sources could potentially be used to drive this reaction, making the whole process very clean.
  • Biomass gasification: literally turning our trash into (gaseous) treasure, whereby a process involving heat, steam and oxygen can be performed to convert biomass (and waste products) into hydrogen.

While the majority of hydrogen is currently produced from fossil fuel sources (around 96% at 2014), there is a real opportunity for Australia to produce low or zero emission hydrogen. We live on the continent with the most solar energy coverage in the world, so it makes sense to capitalise!

A very useful fuel

How can we use hydrogen? Let us count the ways. It can support power generation, transport, food production, agriculture, and more.

One of the most common uses is in fuel cells, combining hydrogen and oxygen to produce electricity, heat, and water. A fuel cell will produce electricity as long as fuel (hydrogen) is supplied. That means no recharging, and no harmful emissions. They are an option for creating heat and electricity for buildings, and electrical power for vehicles. Right now, we’re looking into the feasibility of hydrogen and fuel cells in powering major facilities like the MCG.

Carried away

One of the bigger challenges with hydrogen is that its low density means that it’s difficult to transport. To get around this, ‘carrier fuels’, like ammonia, can be used to take the hydrogen to where it’s needed. Almost counter-intuitively, ammonia (NH3) has a higher density of hydrogen that pure hydrogen (H2), so it’s a very efficient way to transport the fuel. And we already have much of the infrastructure needed to achieve this, even as an export fuel.

Hydrogen can also carry energy to be used ‘on demand’, perhaps using our existing gas grid as delivery method. The concept of ‘power-to-gas’ means that hydrogen can be injected into the gas grid where it is effectively ‘stored energy’. This could potentially stabilise the fluctuations we encounter when the sun isn’t shining and wind isn’t blowing.

In the lab

We’re working on a number of technologies to increase the efficiency of hydrogen production, storage, and conversion to a suitable form for export and domestic use. These include inexpensive electrolysers to catalyse renewable production, membranes to extract hydrogen from carrier fuel at point of use and ways to use hydrogen to create synthetic fuels that can replace diesel and gasoline. We also have a laboratory dedicated to testing ‘hybrid energy systems’, whereby two or more energy technologies are combined for overall benefits – hydrogen lends itself particularly well to these systems.

Researcher in CSIRO lab
Researcher in CSIRO lab

Dr Michael Dolan in our hydrogen laboratory,

The time is right

Australia is known as a leading exporter of energy resources, but the time is right to take a leadership position in what could be the ‘next big thing’. We can use our rich energy resources to produce hydrogen, either as an export or to be used domestically in transport, power generation and to offset more carbon-intensive processes.

We’re already seeing momentum. The South Australian Energy Plan released earlier in 2017 mentions hydrogen as an area for further investigation. Victoria announced funding for a commercial-scale hydrogen refuelling station for garbage trucks. And further afield, Japan has made clear its intentions for hydrogen to play a major role in powering its Tokyo Olympics in 2020.

While technologies are emerging and converging, what’s needed is a central coordination point, and we’re seeking to do just that through a new Future Science Platform (FSP) focused on Hydrogen Energy Systems. This platform will help us development technologies that allow us to export solar energy, as well as providing low emissions energy solutions for Australians.

From what we’re doing in the lab, to pilot and demonstration scale testing, there’s plenty of activity planned. We’ve also got a strong network of partners and collaborators to support current, practical research and technology initiatives across the hydrogen energy value chain.

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24 comments

  1. The oxygen and hydrogen should be produce separately via electrolysis, simple enough .And
    then fed back together into a hydrogen cell to produce electricity. Rather than use atmospheric oxygen with hydrogen. It would produce maximum electric power output this way, without taping into our natural oxygen supply.
    With the safety factor of storing these two gases separately. Feeding browns gas into a reactor works OK but is highly explosive with its oxygen content. especially before it gets to the reactor.
    Shuddhi.

    .

  2. In regard of producing Hydrogen in a sustainable way, there is an alternative approach which needs to be validated by further research. This approach makes use an unusable energy forms to date. A research in this topic has been planned, yet need some researchers for collaboration.

  3. Meanwhile, 30 years ago – Hydrogen Power – https://www.youtube.com/watch?v=lJKCZhyh4nE

  4. I’m all for the research and innovation but I wish we could see people reporting a ‘whole system’ view on energy efficiency, cost and whole life carbon footprint before worrying too much about the detail of making it happen. Sunshine might be “free” but useful solar energy distributed to the point of consumption is not. Similarly, does combining hydrogen with nitrogen to produce ammonia for “easy transport” include allowance for only 22-odd percent of the transported mass actually being a useable energy source that would need a whole new energy producing / distributing and consuming infrastructure to be in place to make it viable? It would be good to see the commercial model first to validate the concept. Remember that King Canute couldn’t command the rising tide to stop – similarly, mankind cannot control the climate by manipulating the trace quantities of CO2 in the atmosphere – nature has far bigger guns at its disposal and will continue to use them irrespective of man’s efforts.

  5. A hybrid catalytic-genetically engineered chemosynthetic bacteria system recently developed at Harvard is able to attach evolved hydrogen directly to atmospheric CO2 to produce hydrocarbons from the air, currently at 13% solar to fuel efficiency.

    http://www.sciencemag.org/news/2016/06/microbe-linked-solar-panels-are-better-plants-converting-sunlight-energy

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