My Uncle Bruce leapt fully formed from my childhood memories onto the Powerhouse stage last week, channelled brilliantly by lead actor Laurence Coy. A Victorian Police Sergeant for twenty years, he epitomised a pithy realism and old school approach to manners and respect that involved a certain amount of biffo. There was a sergeant Bruce or Barry or Mick in many towns and suburbs across Australia.

David Williamson wrote the Removalists in 1974 and captured the type perfectly. Probably, neither Williamson or Coy knew my uncle: they didn’t have to, he was a type.

Uncle Bruce is still alive and well, “for an old fella”, but I have not asked his opinion of David Williamson’s The Removalist. I suspect he would recognise the elements of truth, point out the dramatic devices that have been employed to concentrate the action and focus the reader’s mind and then reflect that there is something to be said for the old ways, even though some coppers might have gone a bit far.
That view would be somewhat disingenuous. Coppers everywhere learn to rough up suspects without leaving too much evidence. I’ve experienced first-hand the way a phone book spreads the impact of a blow to avoid bruising. There is always a tension between the polite society that the police protect and the brutality involved in that protection.
The Removalist has survived as a play, and component of the higher school curriculum, because it is a classic. Beautifully structured in two acts, it has a wonderful balance between humour and tragedy, between human foibles and depravity. It employs Australian English and the vernacular beautifully and deals realistically with sexism, domestic violence, power and corruption without ever descending into polemic.
The production by Leland Kean and Critical Stages is faithful, fresh, exuberant and controlled. Ally Mansell’s staging is simple, clean and striking, Luiz Pamploa’s lighting makes its powerful presence felt from the dramatic opening scene. The actors flesh out the multi-dimensional nature of the characters that Williamson so cleverly wrote.
Ashley Lyons as the perpetrator/victim plays an obnoxious yobbo who unexpectedly gains our sympathy as a culturally oppressed bogan. He is repulsive, real and pathetic as the drama unfolds.
Josh Anderson as the hapless Constable Ross is immediately likeable and wins our full sympathy until his demons betray him and we again feel for him as he too is crushed.
The eponymous removalist fills the role of Puck: defining and offsetting the central drama; relieving us from its intensity and horror while highlighting it with wry observations. Perfectly played by Ben Wood who provides the gravitas and deftness to get the laughs without losing the sense of dread engendered by the shocking inanity of evil unfolding before us.
The women’s roles are minor and narrow, despite being the centre of the narrative arc. The play revolves around Caroline Brazier’s and Lucy Heffernan’s situation but their characters are limited to reacting to the men. As soon as they stand up for themselves they’re dismissed on the basis that as sexually active females they are immoral and therefore irrelevant.
The sublimation of the abuse and the powerlessness of the women is less a failure of the dramatist, the director or the actors than an accurate reflection of reality which The Removalist sets out to expose.
Ultimately, this drama is testosterone-fuelled: male on male violence resolves the dramatic tension. In the classic, sexist, definition it is a tragedy. The hero does not get the girl.
In addition to is power and poise as a dramatic work, The Removalist remains important because it captures the awakening of Australian society to a more enlightened approach to the issues of power, authority and the role of women.
During the seventies, art like The Removalist revealed to an affluent, educated Australian middle-class that the law of the jungle was rife and that our governments and police forces governed in the interests of the few, rather than the majority.
That burgeoning awareness led to a series of Royal Commissions and inquiries that ended a generation of conservative rule and entrenched favouritism. At the same time, what we now call first-wave feminism built on the work of the suffragette’s and began redefining the role of women.
The shocking relevance of the play forty years after it was written, is how entrenched those attitudes are still.
Not only do we still encounter the occasional magistrate who thinks a bit of ‘love pat’ is a reasonable form of foreplay, we have a Minister for Women who openly says that women do not have the right to determine whether or not they choose to have sex.
“The notion, on one hand, that men should be able to demand sex whenever they want or, on the other hand, that women can refuse it whenever they want, well there has to be a negotiation, a compromise” Tony Abbot, Minister for Women – ddth mmmm 2014.
Well no Tony, there does not. This is the attitude at the heart of the shocking statistic that one Australian woman each week is killed by her partner. Over half of these murders take place in Queensland, despite this state having only 25% of the population.
The Removalist goes to the core of this issue, exposing the multitude of ways that men express the attitude that women exist to serve male needs.
Women have stronger roles now, they have better comebacks, they are the protagonists, the playwrights, the directors. The shocking relevance then, of The Removalist in this day and age is that it exposes the past to which our current rulers so enthusiastically wish to drag us.
The great thing about having this vigorous and fresh but faithful production of this classic work is that it shows us that we have evolved. The stark contrast between the attitudes of the past, which our current rulers and mainstream media try to sell us as “normal” and the attitudes that we want to pass onto our children could not be highlighted more succinctly.
It is a pity this has such a short season. It has played to full houses so far and could possibly have sustained a longer run. In itself, that reminds us that Williamson has given Australian drama some solid foundations on which we can build. It may be dated, it may reflect some fundamental flaws of time in which it was written, but it is powerful drama.

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Scientists develop pioneering new spray-on solar cells

A team of scientists at the University of Sheffield are the first to fabricate perovskite solar cells using a spray-painting process – a discovery that could help cut the cost of solar electricity.

Experts from the University’s Department of Physics and Astronomy and Department of Chemical and Biological Engineering have previously used the spray-painting method to produce solar cells using organic semiconductors – but using perovskite is a major step forward.

Efficient organometal halide perovskite based photovoltaics were first demonstrated in 2012. They are now a very promising new material for solar cells as they combine high efficiency with low materials costs.

The spray-painting process wastes very little of the perovskite material and can be scaled to high volume manufacturing – similar to applying paint to cars and graphic printing.

Lead researcher Professor David Lidzey said: “There is a lot of excitement around perovskite based photovoltaics.

“Remarkably, this class of material offers the potential to combine the high performance of mature solar cell technologies with the low embedded energy costs of production of organic photovoltaics.”

While most solar cells are manufactured using energy intensive materials like silicon, perovskites, by comparison, requires much less energy to make. By spray-painting the perovskite layer in air the team hope the overall energy used to make a solar cell can be reduced further.

Professor Lidzey said: “The best certified efficiencies from organic solar cells are around 10 per cent.

“Perovskite cells now have efficiencies of up to 19 per cent. This is not so far behind that of silicon at 25 per cent – the material that dominates the world-wide solar market.”

He added: “The perovskite devices we have created still use similar structures to organic cells. What we have done is replace the key light absorbing layer – the organic layer – with a spray-painted perovskite.

“Using a perovskite absorber instead of an organic absorber gives a significant boost in terms of efficiency.”

The Sheffield team found that by spray-painting the perovskite they could make prototype solar cells with efficiency of up to 11 per cent.

Professor Lidzey said: “This study advances existing work where the perovskite layer has been deposited from solution using laboratory scale techniques. It’s a significant step towards efficient, low-cost solar cell devices made using high volume roll-to-roll processing methods.”

Solar power is becoming an increasingly important component of the world-wide renewables energy market and continues to grow at a remarkable rate despite the difficult economic environment.

Professor Lidzey said: “I believe that new thin-film photovoltaic technologies are going to have an important role to play in driving the uptake of solar-energy, and that perovskite based cells are emerging as likely thin-film candidates.”

Self-Cooling Solar Cells For Better Performance & Longevity

August 12th, 2014 by Guest Contributor

The Optical Society

This drawing demonstrates how solar cells cool themselves by shepherding away unwanted thermal radiation. The pyramid structures made of silica glass provide maximal radiative cooling capability. Credit: L. Zhu, Stanford University.

Scientists may have overcome one of the major hurdles in developing high-efficiency, long-lasting solar cells—keeping them cool, even in the blistering heat of the noonday Sun.

By adding a specially patterned layer of silica glass to the surface of ordinary solar cells, a team of researchers led by Shanhui Fan, an electrical engineering professor at Stanford University in California has found a way to let solar cells cool themselves by shepherding away unwanted thermal radiation. The researchers describe their innovative design in the premiere issue of The Optical Society’s (OSA) new open-access journal Optica.

Solar cells are among the most promising and widely used renewable energy technologies on the market today. Though readily available and easily manufactured, even the best designs convert only a fraction of the energy they receive from the Sun into usable electricity.

Part of this loss is the unavoidable consequence of converting sunlight into electricity. A surprisingly vexing amount, however, is due to solar cells overheating.

Under normal operating conditions, solar cells can easily reach temperatures of 130 degrees Fahrenheit (55 degrees Celsius) or more. These harsh conditions quickly sap efficiency and can markedly shorten the lifespan of a solar cell. Actively cooling solar cells, however—either by ventilation or coolants—would be prohibitively expensive and at odds with the need to optimize exposure to the Sun.

The newly proposed design avoids these problems by taking a more elegant, passive approach to cooling. By embedding tiny pyramid- and cone-shaped structures on an incredibly thin layer of silica glass, the researchers found a way of redirecting unwanted heat—in the form of infrared radiation—from the surface of solar cells, through the atmosphere, and back into space.

“Our new approach can lower the operating temperature of solar cells passively, improving energy conversion efficiency significantly and increasing the life expectancy of solar cells,” said Linxiao Zhu, a physicist at Stanford and lead author on the Optica paper. “These two benefits should enable the continued success and adoption of solar cell technology.”

Solar cells work by directly converting the Sun’s rays into electrical energy. As photons of light pass into the semiconductor regions of the solar cells, they knock off electrons from the atoms, allowing electricity to flow freely, creating a current. The most successful and widely used designs, silicon semiconductors, however, convert less than 30 percent of the energy they receive from the Sun into electricity – even at peak efficiency.

The solar energy that is not converted generates waste heat, which inexorably lessens a solar cell’s performance. For every one-degree Celsius (1.8 degree F) increase in temperature, the efficiency of a solar cell declines by about half a percent.

“That decline is very significant,” said Aaswath Raman, a postdoctoral scholar at Stanford and co-author on the paper. “The solar cell industry invests significant amounts of capital to generate improvements in efficiency. Our method of carefully altering the layers that cover and enclose the solar cell can improve the efficiency of any underlying solar cell. This makes the design particularly relevant and important.”

In addition, solar cells “age” more rapidly when their temperatures increase, with the rate of aging doubling for every increase of 18 degrees Fahrenheit.

To passively cool the solar cells, allowing them to give off excess heat without spending energy doing so, requires exploiting the basic properties of light as well as a special infrared “window” through Earth’s atmosphere.

Different wavelengths of light interact with solar cells in very different ways—with visible light being the most efficient at generating electricity while infrared is more efficient at carrying heat. Different wavelengths also bend and refract differently, depending on the type and shape of the material they pass through.

The researchers harnessed these basic principles to allow visible light to pass through the added silica layer unimpeded while enhancing the amount of energy that is able to be carried away from the solar cells at thermal wavelengths.

“Silica is transparent to visible light, but it is also possible to fine-tune how it bends and refracts light of very specific wavelengths,” said Fan, who is the corresponding author on the Optica paper. “A carefully designed layer of silica would not degrade the performance of the solar cell but it would enhance radiation at the predetermined thermal wavelengths to send the solar cell’s heat away more effectively.”

To test their idea, the researchers compared two different silica covering designs: one a flat surface approximately 5 millimeters thick and the other a thinner layer covered with pyramids and micro-cones just a few microns (one-thousandth of a millimeter) thick in any dimension. The size of these features was essential.  By precisely controlling the width and height of the pyramids and micro-cones, they could be tuned to refract and redirect only the unwanted infrared wavelengths away from the solar cell and back out into space.

“The goal was to lower the operating temperature of the solar cell while maintaining its solar absorption,” said Fan. “We were quite pleased to see that while the flat layer of silica provided some passive cooling, the patterned layer of silica considerably outperforms the 5 mm-thick uniform silica design, and has nearly identical performance as the ideal scheme.”

Zhu and his colleagues are currently fabricating these devices and performing experimental tests on their design. Their next step is to demonstrate radiative cooling of solar cells in an outdoor environment. “We think that this work addresses an important technological problem in the operation and optimization of solar cells,” he concluded, “and thus has substantial commercialization potential.”

Paper:  L. Zhu, A. Raman., K. Wang, M. Anoma, S. Fan, “Radiative Cooling of Solar Cells,” Optica 1, 32-38 (2014).

Originaly published on The Optical Society website.

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