Tag Archives: science
Revealed: The Keys To Reducing The Impact Of Agriculture On Climate Change
Research published in the journal Science (5th July 2013) shows that allowing land use to be determined purely by agricultural markets results in considerable financial and environmental costs to the public. While the research has looked specifically at the UK, the same methods could be applied to any area of the world with similar results for many countries. Land use in most of Europe is dominated by agriculture. Nearly half the total annual value of EU agriculture is based on public financial support surpassing 70%, 40% and 30% in the case of Ireland, UK and Spain, respectively to name a few. The study demonstrates the importance of bringing ecosystem services into decision-making and to make full use of the potential gains from working with the natural environment and the underpinning biophysical processes. The study acknowledges that this does not come without practical challenges. A key challenge concerns the mechanics of securing the participation of farmers in delivering land-use changes to benefit society. A recommendation that the research team puts forward involves the reform of the European Union’s (EU’s) Common Agricultural Policy (CAP). Recasting the CAP as a Payment for Ecosystem Services mechanism would reward farmers for delivering a bundle of key of ecosystem services including climate change mitigation by the reduction of emission of greenhouse gases, water regulation, recreation and biodiversity conservation. “The EU’s Common Agricultural Policy must account for the cost of not working with nature. It is time to reward farmers for securing the vital ecosystem services that are highly valued by society. Farmers can be the stewards of our landscapes so that we as a society we can pass them in a healthy state to the next generations.” Continue reading
Giving Biofuels A Boost: Collaboration For Bioenergy Development
by Christopher J Brigham 11 July 2013 Ideally, successful biofuel development will rely on existing infrastructure, both to transport the fuel to the consumer and to utilise the fuel to generate power. Christopher J Brigham Partnerships between academia and industry on both sides of the Atlantic are key in bioenergy development, writes the University of Massachusetts ’ Christopher J Brigham… Alternative fuels, especially biofuels, are currently hot topics in both the academic and private sectors throughout the world. In many cases, an innovative idea in academic research will become the next revolutionary industrial process, and in some cases, the next potential global solution. I have previously stressed the notion that the academic scholars of today are the innovators and entrepreneurs of tomorrow. As in spheres such as information technology, space, and economics, the next generation of powerful, marketable ideas in biofuel production and technology will come from the universities and institutes of technology. Scientists, politicians, business leaders, and other citizens from both the US and EU offer a myriad of views on global climate change and how this problem will be mitigated in the coming years. Increasingly, biofuel alternatives to petroleum are being developed, such as the use of sugarcane-based ethanol in Brazil. Ethanol, as an inefficient and somewhat problematic biofuel, is really only effective if the proper infrastructure is developed along with it (which has been done in Brazil). Ideally, successful biofuel development will rely on existing infrastructure, both to transport the fuel to the consumer and to utilise the fuel to generate power. There has been an increased focus in the US on researching cost-effective production of biofuels that are compatible with existing transportation infrastructure. This focus is driven by a renewed focus on funding of scientific research in the US, including the American Reinvestment and Recovery Act (ARRA) , which produces funding opportunities for academic and private sector researchers. ‘Fossil fuel consumption remains high’ In both the US and the EU, fossil fuel consumption for energy remains high. Given the concentrated efforts of EU nations to shift to other sources of energy (wind power, solar energy, biodiesel, etc.), the EU-27 have slowed any increase in petroleum consumption, if not altogether halted it. In the US, fossil fuel consumption has decreased somewhat in recent years, but petroleum-based fuels still dominate the US energy consumption landscape. Keeping in mind the EU and US reliance on foreign sources of oil, uncertainty about the size of a finite supply of fossil-based petroleum, and the increasing demand for renewable products, it makes sense for biofuels to be offered as an alternative fuel source, especially for powering motor vehicles. It should be said that ‘alternative’ fuel source does not mean ‘replacement’ fuel source. We must respect the notion that the Earth’s petroleum supply is large enough to sustain our current habits, perhaps for the entirety of our lifetimes, but also prepare for the possibility that the fossil fuel supply is indeed finite. Academic institutions are major players in biofuels research innovation. Many patents and other intellectual property have been developed as a result of academic research on bioenergy. Currently, programmes like Advanced Research Projects Agency – Energy (ARPA-E) in the US are funding innovative and transformative research in many different aspects of the energy space, from biofuels to rethinking the way the energy grid operates. Similar programmes have been established in the EU, focusing on valorisation of waste biomass, biodiesel production, and other relevant topics. While funds from these programmes go mainly to academic institutions, fostering the next wave of innovation, there is also opportunity for partnership with the private sector. This could be crucial for the development of ideas in bioenergy and bringing them to market. Transatlantic collaboration I propose a partnership in biofuels research and development that has been largely underexplored, if not unexplored: the opportunity for US and EU universities to work together to address the challenge of creating an affordable and efficient bioenergy infrastructure. In a global economy, continued cooperation among respected global institutions is a must. A pooling of resources between the US and EU could have economic and even political advantages for the nations involved, and could help shape the energy future on both sides of the Atlantic. Christopher J Brigham PhD Assistant Professor University of Massachusetts Dartmouth www.umassd.edu [This article was originally published on 1 st July 2013 as part of Science Omega Review Europe 02] Read more: http://www.scienceom…t#ixzz2Yk2V4ZrS Continue reading
If We Burn Wood For Energy, We Can’t Have Our Cake And Eat It
Whether more power stations should switch to burning wood or biomass is debatable. David Cheskin/PA Many countries have turned to the planet’s forests to meet their need for renewable energy, burning wood chips and pellets produced at home or abroad in power stations to generate electricity. But a report from the European Environment Agency published this week urged caution over what to burn, and how. There’s no question that if managed sustainably – which absolutely rules out turning tropical forests into palm oil plantations – wood-powered bioenergy can be an effective renewable energy source. In some cases, wood energy markets even encourage good forestry practice that can improve forest health and reduce fire and insect risks. And many experts agree that high yield, short rotation plantations of fast-growing willow or poplar make sense, depending on the land-uses these operations displace. But the question of whether wood bioenergy is problematic from a climate change perspective is much harder to answer. If we burn wood from a forest to produce heat or electricity or both, would the carbon emissions be re-sequestered as the forest re-grows? Is it accurate to consider wood biomass energy to be carbon neutral in terms of greenhouse gas emissions? Forest carbon is sequestered – soaked up from the atmosphere – by plants though photosynthesis, stored in living and dead biomass, and ultimately released back to the atmosphere in the form of carbon dioxide through plant and animal respiration and decomposition. This might suggest that the carbon locked up in forests is part of a global biogenic carbon cycle , separate and distinct from that humans have released by burning fossil fuels. It seems simple, intuitive even, but it’s not that straightforward. Even the concept of “biogenic carbon” is disputed. In our paper we contended that the concept of biogenic carbon is a red herring, because what really matters is the net amount of carbon in the atmosphere, regardless of source. Others will adamantly disagree. In many cases, poorly supported assumptions continue to underpin a sudden rush to develop wood bioenergy power generation around the world – often backed by subsidies. In my opinion, policies promoting wood bioenergy have developed quicker than the science that examines the potential tradeoffs, net effects, and consequences. Science needs time to explore the complexities of an issue like bioenergy. Only proper study can the scientific community provide more informed answers to important policy questions. The crux of the debate comes down to whether or not there will be an initial increase in greenhouse gas emissions if more wood is used for bioenergy (a carbon “debt”), particularly if it is harvested from growing trees, followed by a delay before a net emissions reduction is achieved (the “dividend”). And if so, how long that delay would be. This was structure of the argument laid out in a now infamous study conducted for the state of Massachusetts in the US. A paper by Dr Giuliana Zanchi and colleagues found immediate emissions benefits from using biomass leftover from harvests or from plantations established on marginal agricultural land, assuming biomass was substituted for coal and gas. But intensified harvesting of existing forests was projected to incur a carbon debt lasting many decades. Generating thermal energy instead of electricity has been shown to incur much shorter debt, for example. Getting this right is vital, because we have a window of only the next few decades to stabilise atmospheric greenhouse gases, beyond which some scientists believe climate disruption will be irreversible. So, assuming there will be some degree of debt in the near future and a consequent time lag before an overall net reduction of emissions, we can minimise both by following certain practises. Using by-product or waste biomass, that does not involve intensive forest harvesting , practising excellent sustainable forestry techniques, and building small-scale, highly efficient energy generation applications with minimal waste. Policies should promote high-efficiency energy applications, such as combined heat and power. Studies have found smaller bioenergy projects such as those for homes, housing estates or municipal buildings have much lower net emissions than large, industrially-sized plants. The choice of what not to use is just as important – substituting wood for coal results eliminates considerably more carbon emissions than substitution for natural gas. My research group , using data from bioenergy harvests and energy production across the northeastern United States, came to completely different conclusions depending on the baseline used as a reference to evaluate net emissions. The results swung from carbon negative to carbon positive if the baseline used was the amount of carbon that would have been sequestered had wood bioenergy not been used (with all other things being equal, and taking into account avoided emissions and direct and indirect energy uses associated with wood harvesting). Conversely, if the baseline is simply the amount of carbon currently being emitted at the present date, then most forest management schemes, including wood bioenergy, lowered cabon emissions over the long term. This was true so long as they incorporated the principles of sustainable harvest scheduling that maintain stable forest levels to stock carbon across the landscape as a whole. Should we stop investing in and promoting wood bioenergy? No – but we should proceed with caution, using the best available science. Policymakers will need to weigh the benefits and tradeoffs to minimise unintended consequences such as emissions increasing in the short-term. Go local, go small scale, go high efficiency, and develop rigorous forest harvesting standards and guidelines. When it comes to wood bioenergy, it is unlikely we will be able to have our cake and eat it too. Continue reading