26 July 2016, The Guardian, Disasters linked to climate can increase risk of armed conflict. Research found that 23% of violent clashes in ethnically divided places were connected to climate disasters. Climate-related disasters increase the risk of armed conflicts, according to research that shows a quarter of the violent struggles in ethnically divided countries were preceded by extreme weather.The role of severe heatwaves, floods and storms in increasing the risk of wars has been controversial, particularly in relation to the long drought in Syria. But the new work reveals a strong link in places where the population is already fractured along ethnic lines. Previous work has shown a correlation between climate disasters and fighting but the new analysis shows the disasters precede the conflict, suggesting a causal link. Experts have warned that an increase in natural disasters due to global warming is a “threat multiplier” for armed violence. The scientists behind the new research say it could be used to predict where future violence might flare, allowing preventative measures to be taken. “Armed conflicts are among the biggest threats to people, killing some and forcing others to leave their home and maybe flee to faraway countries,” said Prof John Schellnhuber, director of the Potsdam Institute for Climate Impact Research in Germany and one of the research team. The combination of climate disasters and ethnic tensions make an “explosive mixture,” he said. Read More here
Monthly Archives: July 2016
25 July 2016, IOP SCience: Readily implementable techniques can cut annual CO2 emissions from the production of concrete by over 20%. Due to its prevalence in modern infrastructure, concrete is experiencing the most rapid increase in consumption among globally common structural materials; however, the production of concrete results in approximately 8.6% of all anthropogenic CO2 emissions. Many methods have been developed to reduce the greenhouse gas emissions associated with the production of concrete. These methods range from the replacement of inefficient manufacturing equipment to alternative binders and the use of breakthrough technologies; nevertheless, many of these methods have barriers to implementation. In this research, we examine the extent to which the increased use of several currently implemented methods can reduce the greenhouse gas emissions in concrete material production without requiring new technologies, changes in production, or novel material use. This research shows that, through increased use of common supplementary cementitious materials, appropriate selection of proportions for cement replacement, and increased concrete design age, 24% of greenhouse gas emissions from global concrete production or 650 million tonnes (Mt) CO2-eq can be eliminated annually. Research Paper: Read More here
20 July 2016, CSIRO Blog, Supersonic magnesium. It’s used to make our smartphones and cars, and it makes our fireworks go off with a brilliant bang. It’s the third most commonly used structural metal and comprises 2% of Earth’s crust. We are of course talking about magnificent magnesium. Why do we think it’s so magnificent? Well, when magnesium is mixed with other metals it makes stable, super-strong alloys. Not only are these alloys used in our mobile phones and laptops, they are also highly sought after by car manufacturers who are turning to the metal as a solution for making lightweight, low-emission vehicles. Australia is sitting in the driver’s seat to deliver new, improved, ‘supersonic’ magnesium metal and take advantage of our vast untapped reserves of magnesite. So we’ve decided to take the wheel and develop an innovative technology, known as MagSonic, which produces magnesium using up to 80 per cent less energy and up to 60 per cent less carbon dioxide emissions than traditional processes. The process involves heating magnesia (magnesium oxide) with carbon to extreme temperatures to produce magnesium vapour and carbon monoxide. The gases are then passed through a supersonic nozzle – similar to a rocket engine – at four times the speed of sound. This cools the gases in milliseconds, condensing and solidifying the magnesium vapour to magnesium metal. Read More here
20 July 2016, The Guardian, Why is the World Bank backing coal power in Europe’s youngest country? In the early days of December 2015, as the Paris climate talks veered off course and off schedule, the US secretary of state John Kerry left his team of negotiators and flew to Kosovo to voice his support for a proposed US-built, World Bank-sponsored coal power station. Speaking alongside the prime minister, Isa Mustafa, Kerry told reporters at Pristina airport that the Kosovo e re (New Kosovo) plant would help the tiny, impoverished country do “its part to contribute to this global effort of nations who are committed to dealing with climate change” by replacing an extremely high-polluting cold war-era power plant. Kerry then returned to Paris and helpedland a deal intended to bring the fossil fuel era to an end. While many countries, including the US, continue to build coal plants at home, the fuel is increasingly a pariah in the world of development finance. Both the USand the World Bank have limited international finance for new coal power to exceptional circumstances – so rare that Kosovo’s is the only coal plant being considered for World Bank support anywhere on Earth. Despite this, Kosovan government officials are confident they will receive final approval from the World Bank when the project goes before its board, likely later this year. Strong advocacy is expected from the US delegation. Read More here