Adv 1 – Leadership



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STEM Impact – Warming




STEM education key to solving warming

Mejia 9 – * Employment Services Manager at South Bay Workforce Investment Board, City University of New York-Baruch College (education) [Robert T. Mejia, “What’s Old is New: Green Jobs & What America’s Federal Workforce Investment System Can Do Now to Develop a Green Workforce”, 1/14/09, www.southbayresource.net/articles/whatsoldisnew.pdf, tables, charts, and graphs omitted]
In addition to adaptation, science, technology and innovation may prove to be our greatest allies in the battle to defeat global warming. A number of promising eco-tech solutions to our environmental challenges are starting to emerge; they hinge on further research and development, access to capital, and accommodating government regulations. Innovations such as Bio-char (a stable and rich charcoal produced from biomass) for carbon sequestration, improved soil fertility, sustainable (carbon-negative) energy production, and poverty reduction; the use of algae as an alternative fuel source; and bioorganisms and nano devices that clean up toxic spills and improve solar technology hold great potential for solving some of the world’s most difficult consumption challenges and contamination problems. Sustained advances and U.S. leadership in environmental technologies, not only in terms of global warming, but in terms of competitiveness, will rely on an expansion of the nation’s knowledge workforce, with a strong emphasis on green-centered science, technology, engineering and mathematics (STEM). Sadly, the U.S. lags other developed countries in its preparation of technologists, scientists, engineers and mathematicians. The U.S.’ share of the world’s scientists and engineers is projected to fall from 40 percent in 1975 to 15 percent in 2010.22 This trend must be reversed. As reported by the U.S. Department of Labor on January 15, 2008 in the Federal Register: There is a broad consensus that the long-term key to continued U.S. competitiveness and growth in an increasingly global economic environment is the adequate supply of qualified Science, Technology, Engineering, and Mathematics (STEM) workers capable of translating knowledge and skills into new processes, products and services. According to the National Science Foundation (NSF), scientific innovation has produced roughly half of all U.S. economic growth in the last fifty years and the STEM disciplines, including those who work in them, are critical engines to that innovation and growth--one recent estimate, while only five percent of the U.S. workforce is employed in STEM fields, the STEM workforce accounts for more than fifty percent of the nation’s sustained growth (Babco 2004). The National Academy of Sciences study, Rising Above the Gathering Storm (2006), argues that: Absent a serious and rapid response, the U.S. will lose quality jobs to other nations; lowering our standard of living, reducing tax revenues, and weakening the domestic market for goods and services. Once this cycle accelerates, it will be difficult to regain lost pre-eminence in technology-driven innovation and its economic benefits.23 In Thrive: The Skills Imperative, the Council on Competitiveness states that: Looking ahead, skills for sustainability could become a key competitive differentiator. As Joseph Stanislaw has noted: we are at the very beginning of a global race to create dominant green economies.(42) Global warming and competition for resources could very well change the ground rules of globalization-at the very least, the need to reduce carbon footprints and achieve higher resource productivity could alter corporate calculations about where and how to distribute operations and assets globally. America could get out in front of this paradigm shift. But it is not clear that the United States will have enough talent with the right set of skills, or has even defined the path forward on skills for sustainability.24 To defeat global warming, we must focus on developing both the intellectual and physical infrastructure of our country. A national campaign to promote STEM education in environmental technologies, with strong federal financing of community and public sector organizations to provide career and academic support, will make a difference.
Extinction

Tickell, 8 (Oliver, Climate Researcher, The Gaurdian, “On a planet 4C hotter, all we can prepare for is extinction”, 8/11http://www.guardian.co.uk/commentisfree/2008/aug/11/climatechange)

We need to get prepared for four degrees of global warming, Bob Watson told the Guardian last week. At first sight this looks like wise counsel from the climate science adviser to Defra. But the idea that we could adapt to a 4C rise is absurd and dangerous. Global warming on this scale would be a catastrophe that would mean, in the immortal words that Chief Seattle probably never spoke, "the end of living and the beginning of survival" for humankind. Or perhaps the beginning of our extinction. The collapse of the polar ice caps would become inevitable, bringing long-term sea level rises of 70-80 metres. All the world's coastal plains would be lost, complete with ports, cities, transport and industrial infrastructure, and much of the world's most productive farmland. The world's geography would be transformed much as it was at the end of the last ice age, when sea levels rose by about 120 metres to create the Channel, the North Sea and Cardigan Bay out of dry land. Weather would become extreme and unpredictable, with more frequent and severe droughts, floods and hurricanes. The Earth's carrying capacity would be hugely reduced. Billions would undoubtedly die. Watson's call was supported by the government's former chief scientific adviser, Sir David King, who warned that "if we get to a four-degree rise it is quite possible that we would begin to see a runaway increase". This is a remarkable understatement. The climate system is already experiencing significant feedbacks, notably the summer melting of the Arctic sea ice. The more the ice melts, the more sunshine is absorbed by the sea, and the more the Arctic warms. And as the Arctic warms, the release of billions of tonnes of methane – a greenhouse gas 70 times stronger than carbon dioxide over 20 years – captured under melting permafrost is already under way. To see how far this process could go, look 55.5m years to the Palaeocene-Eocene Thermal Maximum, when a global temperature increase of 6C coincided with the release of about 5,000 gigatonnes of carbon into the atmosphere, both as CO2 and as methane from bogs and seabed sediments. Lush subtropical forests grew in polar regions, and sea levels rose to 100m higher than today. It appears that an initial warming pulse triggered other warming processes. Many scientists warn that this historical event may be analogous to the present: the warming caused by human emissions could propel us towards a similar hothouse Earth.



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