An eco-friendly aircraft taxiing approach with collision and conflict avoidance

Major US electric utility climate pledges have the potential to collectively reduce power sector emissions by one-third

Imposing versus Enacting Commitments for the Long‐Term Energy Transition: Perspectives from the Firm

Greenhouse gas (GHG) emissions reduction in the electricity sector: Implications of increasing renewable energy penetration in Ghana's electricity generation mix

Comparison of the greenhouse gas and criteria pollutant emissions from the SF-BREEZE high-speed fuel-cell ferry with a diesel ferry

Energy-related activities are a major contributor of greenhouse gas (GHG) emissions. A growing body of knowledge clearly depicts the links between human activities and climate change. Over the last century the burning of fossil fuels such as coal and oil and other human activities has released carbon dioxide (CO2) emissions and other heat-trapping GHG emissions into the atmosphere and thus increased the concentration of atmospheric CO2 emissions. The main human activities that emit CO2 emissions are (1) the combustion of fossil fuels to generate electricity, accounting for about 37% of total U.S. CO2 emissions and 31% of total U.S. GHG emissions in 2013, (2) the combustion of fossil fuels such as gasoline and diesel to transport people and goods, accounting for about 31% of total U.S. CO2 emissions and 26% of total U.S. GHG emissions in 2013, and (3) industrial processes such as the production and consumption of minerals and chemicals, accounting for about 15% of total U.S. CO2 emissions and 12% of total ...

Environmental sustainability has emerged as a global imperative, necessitating a nuanced understanding of the determinants of greenhouse gas (GHG) emissions. Although previous studies have highlighted various environmental indicators the specific influence of technological innovation, renewable energy adoption, and forest cover on GHG emissions within G‐7 countries remains insufficiently explored. In this regard, this study examines the impact of these factors on GHG emissions across the G‐7 countries over the period 1995–2021. The empirical results reveal significant cross‐sectional dependence and confirm that technological innovation, renewable energy consumption, and forest conservation significantly contribute to reducing GHG emissions. In contrast, tourism development and economic growth are associated with increased environmental degradation. Moreover, causality analysis uncovers a unidirectional relationship from GHG emissions to technological innovations and from tourism to GHG emissions, alongside a bidirectional causal nexus between renewable energy and GHG emissions. Furthermore, advanced machine learning techniques, including Gradient Boosting (GB) and Extreme Gradient Boosting (XGBoost), identify these variables as key predictors of GHG emissions. These findings underscore the critical role of data‐driven, evidence‐based policymaking in advancing environmental sustainability. By strategically integrating technological advancements and renewable energy frameworks, G‐7 policymakers can more effectively mitigate climate change impacts. The study advocates for comprehensive and targeted policy interventions that address the intricate interplay between economic dynamics and environmental imperatives in the pursuit of a sustainable future.

Rising need for various renewable and non-renewable energy resources became vital for developing countries to meet their rapid economic growth under an exponentially growing population scenario. The primary goal of COP-26 for climate change mitigation is to reduce greenhouse gas (GHG) emissions from different sectors. Because of their significant contribution to global warming, GHG emissions from hydroelectric reservoirs have been a contentious topic of discussion since the pre-industrial age. However, the exact methodology for quantification of GHG and important parameters affecting emission rate is difficult due to limited equipment facilities, techniques for GHG measurement, uncertainties in GHG emissions rate, insufficient GHG database, and significant spatio-temporal variability of emission in the global reservoirs. This paper discusses the current scenario of GHG emissions from renewable energy, with a focus on hydroelectric reservoirs, methodological know-how, the interrelationship between parameters impacting GHG emissions, and mitigation techniques. Aside from that, significant methods and approaches for predicting GHG emissions from hydroelectric reservoirs, accounting for GHG emissions, life cycle assessment, uncertainty sources, and knowledge gaps, have been thoroughly discussed.

I. BACKGROUND II. CLIMATE CHANGE IMPACTS IN ARIZONA III. EXECUTIVE ORDER 2005-02 AND THE CLIMATE CHANGE ADVISORY GROUP IV. EXECUTIVE ORDER 2006-13 V. ARIZONA'S CLEAN CAR GHG STANDARDS VI. ARIZONA'S RENEWABLE ENERGY STANDARD VII. THE WESTERN CLIMATE INITIATIVE VIII. OTHER REGIONAL EFFORTS A. Arizona-Sonora Climate Change Initiative B. Southwest Climate Change Initiative C. The Climate Registry IX. OTHER ARIZONA EFFORTS A. Executive Order 2005-05 B. Smart Growth & the Growth Scorecard X. CONCLUSION I. BACKGROUND In the absence of meaningful federal action, it has been up to the states to show leadership on this critical issue. And that is exactly what we have done. Governor Janet Napolitano (1) Arizona is one of the newest and fastest growing states in the country. Over the last twenty years, Arizona's population has nearly doubled. (2) During that same time, greenhouse gas (GHG) emissions in Arizona have skyrocketed, due substantially to the state's population growth. An inventory and forecast of Arizona's GHG emissions prepared in 2005 for the Arizona Climate Change Advisory Group (CCAG) at the direction of then-Governor Janet Napolitano found that, between 1990 and 2005, Arizona's net GHG emissions increased by nearly 56 percent, from an estimated 59.3 million metric tons carbon dioxide equivalent (MMtCO2e) to an estimated 92.6 MMtCO2e. (3) Two sectors directly related to Arizona's rapid population growth--transportation and electricity--accounted for nearly 80 percent of Arizona's total GHG emissions in 2005. (4) Both sectors are growing at relatively high rates as Arizona's population grows. Indeed, with Arizona's population expected to continue to grow at a vigorous pace in the decades ahead, (5) the 2005 inventory and forecast projected that Arizona's GHG emissions would increase 148 percent over 1990 levels by 2020 if steps are not taken to reduce the emissions. (6) Because of Arizona's reliance on gasoline-fueled automobiles and demand for electricity produced by coal-fired power plants, Arizona's GHG emissions increased at a rate more than twice the national average during 1990-2005. (7) Further, Arizona's projected 148 percent growth-rate between 1990 and 2020 is more than three times the projected national average over the same period. (8) Arizona's forecasted GHG increase is the highest known projected emissions growth rate in the country. (9) On the other hand, because of Arizona's mild winters and relative absence of manufacturing and heavy industry, the state's per capita GHG emissions (the total level of statewide emissions divided by state population) is significantly less than the national average: 14 MtCO2e versus 22 MtCO2e. (10) Moreover, while the percentage of GHG emissions from electricity production in Arizona is greater than the national average, Arizona gets slightly less electricity from coal and more from low-GHG-emitting sources, such as nuclear power, hydroelectric power and renewable energy (such as solar and biomass). (11) While Arizona's high emissions growth rate presents challenges, it also provides major opportunities. Because nearly 80 percent of Arizona's GHG emissions are directly related to energy and transportation, Arizona can significantly reduce its GHG emissions by focusing on those sectors. Improved energy efficiency, increased use of renewable energy sources, building new infrastructure right, and increased use of cleaner transportation modes, technologies and fuels are key elements in accomplishing these reductions. They are also all essential ingredients of a new, greener economy toward which the state must move in any event. (12) II. CLIMATE CHANGE IMPACTS IN ARIZONA It is critical that Arizona take action to reduce its GHG emissions because the scientific evidence is clear that Arizona and the Southwest will be especially hard-hit by the impacts of climate change in the future. …

The Earth's surface temperature is steadily increasing due to the accumulation of greenhouse gases, a phenomenon known as global warming. Human activities are the root cause of this significant global issue. Reducing greenhouse gas (GHG) emissions is one of the most critical actions in climate change mitigation. Organizations can engage in activities that promote change and reduce greenhouse gases by acknowledging the significance of addressing climate change. By reducing GHG emissions and promoting the use of renewable energy, organizations can begin to address environmental issues. Therefore, the purpose of this investigation is to assess the reduction of GHG emissions in an educational institution by substituting electricity consumption from the electrical grid with renewable energy in the form of a solar PV rooftop on-grid system. The School of Renewable Energy's GHG emissions were assessed, covering three scopes of GHG emissions activities: direct emissions, indirect emissions, and other indirect emissions. The organization's activity data were collected over a 12-month period. Without installing a solar panel system, the organization reported total GHG emissions of 310.40 tCO2e, relying solely on imported electricity for internal use. The highest GHG emissions were from Scope 2, amounting to 239.38 tCO2e, primarily due to electricity importation. Scope 3 had the second highest GHG emissions, totaling 65.76 tCO2e, resulting from employee commuting and the use of purchased goods such as paper and tap water. Scope 1 had the lowest GHG emissions at 5.26 tCO2e, produced by the combustion of diesel and gasoline in both stationary and mobile sources, as well as CH4 emissions from the septic tank. The percentage of GHG emissions from Scope 2 activities was 77.12%, which was considered to have a significant environmental impact and contribute to global warming. This was because 478,851 kWh of electricity were imported. The installation of on-grid solar cells for power generation reduced imported electricity to 113,120 kWh. Consequently, GHG emissions from Scope 2 decreased to 56.55 tCO2e, leading to an overall reduction in the organization's GHG emissions to 127.57 tCO2e. The organization's GHG emissions decreased by 182.83 tCO2e as a result of using alternative energy to generate electricity. This assessment can serve as a database for educational institutions and prepare the government to report greenhouse gas emissions. Furthermore, it can serve as carbon credits for trading and exchanging carbon with other organizations to offset GHG emissions from various activities. In addition, it endorses the government's goal of achieving carbon neutrality and net zero emissions in the future.

Renewable energy technologies (REs) are crucial to reducing greenhouse gas (GHG) emissions and mitigating climate change. REs can impact the environment negatively, particularly if they occupy large land areas. It is necessary to compare the potential benefits of using land to install REs with the possible loss of carbon sequestration in ecosystems where REs are installed. This effect can be particularly high in tropical countries. Such potential loss of carbon sequestration is generally ignored when evaluating the environmental impacts of proposed REs. This study examined the trade-offs between the loss of carbon fixation from land use in operating and projected hydro, wind, and solar power plants and GHG emissions from thermal power. We used MODIS products and official data from national agencies to estimate non-fixed carbon in areas occupied by REs and national data on GHG emissions from thermal power generation. We conclude that wind plants have the highest land occupation impact, while solar plants have the lowest. Hydropower plants have the highest non-assimilated carbon impact (loss of carbon fixation), but these values are significantly lower than GHG emissions from thermal power. Our results indicate that, although there are negative impacts from devoting large areas to power generation from REs, the amount of carbon injected into the atmosphere while generating the same amount of power from non-renewable sources is significantly greater. We recommend that cost-benefit analyses for adopting REs incorporate new approaches to quantify, more accurately, the true value of adopting these new energy-production strategies at the national scale.

Urban water cycle systems(UWCS), including water treatment facilities, distribution facilities, sewers, and wastewater treatment facilities, are energy intensive and significant source of greenhouse gas (GHG) emissions, making the reduction of GHG emissions and the transition to eco-friendly energy essential. This study identifies specific GHG emission sources at each stage of the UWCS and proposes detailed methods to achieve a 40% reduction in GHG emissions, implement RE100, and attain Net Zero by employing insets and offsets. This study develops scenarios for insets and offsets based on the baseline process of the UWCS, and investigates potential pathways to reduce GHG emissions by quantifying emissions from each process. Internal insets, which are self-implemented and technical measures, are prioritized, while external offsets are applied to compensate for the remaining emissions. Internal insets include the application of anaerobic digesters and combined heat and power(CHP), improvements in energy efficiency of equipment, reduction in water pipe leakage, implementation of water footprint labeling, and installation of on-site photovoltaic system. External offsets comprise renewable energy certificates(REC), power purchase agreements(PPA), green hydrogen fuel for vehicles, natural sequestration improvement, and emission trading system. GHG emissions at each stage within the UWCS are quantified using modeling software. Based on these results, the effectiveness of insets and offsets in achieving a 40% GHG emissions reduction, Net Zero, and RE100 goal is analyzed. The baseline total GHG emissions for the UWCS are estimated at 4,732.8 tCO2eq/yr, of which 56.8% is identified as targets for internal insets, and the remaining 43.2% is reduced through external offsets. A 40% GHG reduction can be achieved through internal insets, and Net Zero can be attained by incorporating additionally applying external offsets. The total power demand of UWCS facilities and equipment is calculated as 572.8 kW. Renewable energy is generated through anaerobic digesters and CHP(116.1kW) as well as on-site PV(395.0 kW), while RE100 compliance is achieved by securing an aditional 61.7 kW through REC/PPA. Achieving Net Zero and RE100 requires prioritizing strategies for insets, offsets and efficient resource allocation. For this, the technical feasibility and self-implementation potential of reduction efforts and the external conditions for offsets, should be carefully reviewed to optimize implementation strategies. GHG reduction and renewable energy utilization in the UWCS are key priorities for addressing the climate crisis and achieving sustainable water resource management, requiring technological innovation and institutional support. The comprehensive and systematic application of GHG insets and offsets is the optimal approach to achieving these goals. Furthermore, modeling software serves as a key tool for quantifying GHG emissions and formulating concrete, viable GHG reduction strategies. In addition to the technical and institutional approaches proposed in this study, achieving Net Zero and implementing RE100 requires the integrated consideration of economic factors in the future.

A guide to life-cycle greenhouse gas (GHG) emissions from electric supply technologies

GHG Mitigation in Power Sector: Analyzes of Renewable Energy Potential for Thailand’s NDC Roadmap in 2030

Heterogeneity of the impact of energy production and consumption on national greenhouse gas emissions

The nexus between greenhouse gas emission, electricity production, renewable energy and agriculture in Pakistan