Carbon Dioxide Is Responsible For Much Of Global Warming

Carbon Dioxide Is Held Responsible For Much Of Global Warming For Thi

Carbon dioxide is held responsible for much of global warming. For this discussion, conduct independent research on technological innovations that have been proven to reduce carbon dioxide emissions. Note the following as you begin your research: Good places to start your research include Basic Search: Strayer University Online Library, Google Scholar, or governmental websites such as the Environmental Protection Agency (EPA) or the U.S. Department of Transportation. You may also use the Internet to conduct your research.

Wikipedia and personal blogs, however, do not qualify as quality resources. In this posting, complete the following: Describe one technological innovation that has been proven to reduce carbon dioxide emissions. Explain to your classmates why you selected this particular technological innovation as opposed to others. Identify the two most useful resources you consulted about your selected technological innovation. Be sure to include the full citation for these resources and format them according to Strayer Writing Standards (SWS).

Paper For Above instruction

Global warming represents a significant challenge linked to increased greenhouse gases, particularly carbon dioxide (CO₂). Addressing this issue necessitates technological innovations aimed at reducing CO₂ emissions. One such innovation that has demonstrated effectiveness is the deployment of Carbon Capture and Storage (CCS) technology. CCS entails capturing CO₂ emissions from industrial sources or power plants before they reach the atmosphere, then transporting and storing them underground in geological formations. This technology has gained recognition as a potent means to mitigate CO₂ emissions, especially from fossil fuel-based energy generation, which remains a major contributor to global greenhouse gases.

I selected CCS as the focal technological innovation because of its direct approach in reducing emissions at the source, thereby complementing renewable energy strategies. Unlike renewable energy sources, which depend on the intermittent nature of resources such as sunlight and wind, CCS offers a near-term solution to lower emissions from existing infrastructure. Its versatility in applications, ranging from natural gas processing to cement manufacturing, makes it a broad-spectrum tool in climate change mitigation efforts. Furthermore, the development and deployment of CCS are supported worldwide by governments and organizations committed to achieving net-zero emissions by mid-century.

The first resource I found particularly useful is the report by the Global CCS Institute, which provides an extensive overview of the current status, technological advances, and future prospects of CCS worldwide (Global CCS Institute, 2021). This report offers technical details, case studies of operational CCS projects, and policy insights, making it invaluable for understanding the scope and potential of CCS. The second resource is the Environmental Protection Agency's (EPA) documentation on greenhouse gas mitigation strategies, which discusses the regulatory landscape and standards that influence CCS adoption in the United States (EPA, 2023).

These resources were instrumental because they provided both technical and policy perspectives, enabling a comprehensive understanding of CCS technology’s capabilities and challenges. The Global CCS Institute's report gave in-depth technical insights and real-world implementation examples, while the EPA documentation framed the policy environment necessary for wider adoption. Together, they provided a balanced view of how CCS can be an effective solution within the broader climate mitigation framework.

In conclusion, Carbon Capture and Storage stands out as a proven technological innovation capable of significantly reducing carbon dioxide emissions. Its direct approach to capturing CO₂ at emission sources, supported by extensive research and policy frameworks, makes it an essential component in the global effort to combat climate change. Leveraging such innovations, alongside renewable energy and efficiency measures, can pave the way towards a sustainable, low-carbon future.

References

• Global CCS Institute. (2021). Global Status of CCS 2021. Retrieved from https://www.globalccsinstitute.com/resources/global-status-report/
• Environmental Protection Agency. (2023). Greenhouse Gas Mitigation Strategies. Retrieved from https://www.epa.gov/climate-change/reducing-greenhouse-gas-emissions
• Li, X., Li, J., & Li, B. (2022). Advances in carbon capture technologies for sustainable development. Renewable and Sustainable Energy Reviews, 154, 111799.
• Haszeldine, R. S. (2009). Carbon capture and storage: how green is right now? Science, 325(5948), 1647–1652.
• Metz, B., et al. (2005). IPCC Special Report on Carbon Dioxide Capture and Storage. Intergovernmental Panel on Climate Change.
• Brown, S., & Williams, R. (2020). Economic impacts of CCS deployment in the energy sector. Energy Economics, 91, 104923.
• Zhang, Y., et al. (2019). Technical challenges of CCS: A review. Journal of Cleaner Production, 236, 117641.
• International Energy Agency. (2020). The Role of Carbon Capture, Utilization and Storage in Climate Change Mitigation. IEA Publications.
• Oregui, M., et al. (2023). Policy pathways to accelerate CCS deployment—A global perspective. Environmental Science & Policy, 144, 117-126.
• Lund, H., et al. (2019). Integrating CCS with renewable energy systems for sustainable development. Energy Reports, 5, 1237–1244.