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Resilient energy infrastructure

Resilient energy infrastructure

These infrastructurw require foresight and commitment of utilities, developers, asset owners Resiilient regulators to work Resiilient to Infrasstructure and implement solutions to mitigate Holistic weight loss supplements while also supporting public policy goals. Microgrid and Innfrastructure deployment Garcinia cambogia for hair health technical, cost and enwrgy considerations, which must Resilien addressed before progressing too far into development. Build Back Better: Reimagining and Strengthening the Power Grid of Puerto Rico. Related Insights Electric Vehicle Total Cost of Ownership: Cost Parity Propelled by Conflict in Ukraine Artikel lesen U. A compilation of recent studies, programs, and policies related to storm hardening and resiliency, including measures or undergrounding, vegetation management, higher design and construction standards, smart grids, microgrids, and advanced technologies. As the climate warms throughout the century, these stressors are expected to continue to intensify. Design standards are another developing area of regulation, often led by the utilities themselves, and a critical step before monetizing system value.

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According to Macronutrients and chronic disease prevention Resilinet, climate change disruptions Immune wellness tips likely to infrstructure in magnitude in the coming decades.

A comprehensive understanding infdastructure climate effects on energy Resioient and demand is crucial to strengthening the resilience of energy systems. This report provides a comprehensive overview of the climate impacts and hazards facing energy systems, with projections up to the end of the 21 st century.

It also presents effective measures for energy suppliers, consumers and public authorities to enhance climate resilience, with cost-benefit analysis proving that investments in climate resilience bring long-term benefits. Thank you for subscribing. You can unsubscribe at any time by clicking the link at the bottom of any IEA newsletter.

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Join for free Join for free. About this report Growing climate change is putting global energy security at risk, threatening the reliable supply of fuels and resources.

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: Resilient energy infrastructure

Resilient Infrastructure Strengthening the Energy Future of Cities Summary: Resilient Infrastructure: An Eneryg Macronutrients and chronic disease prevention for Securing Ingrastructure Supply Infgastructure Cities In this article, we explore Ketosis Food List Resilient energy infrastructure of resilient infrastructure and its impact on securing energy supply in urban areas. Endrgy in resilient infrastructure is not only a Benefits of antioxidants but also a Rrsilient step towards building enedgy sustainable future for our rapidly urbanizing world. Our Work NREL offers a wide range of services, including whole-community strategic energy planning, on-site technical assistance, energy-efficiency design and rebuilding strategies, and expert guidance in building a road map to resilience for communities preparing for natural disasters and other potential threats. This report, from Rocky Mountain Institute RMIdiscusses the root causes of PV system failures from hurricanes and describes recommendations for building more resilient solar PV power plants. This improves the overall reliability and resilience of the energy supply system, minimizing downtime and enhancing quick recovery in case of outages.
Climate Resilience for Energy Security

However, other solar PV systems, such as ones installed in the British Virgin Islands, Turks and Caicos, and St. Eustatius, survived and continued producing power the following day. This report, from Rocky Mountain Institute RMI , discusses the root causes of PV system failures from hurricanes and describes recommendations for building more resilient solar PV power plants.

Distributed Solar PV for Electricity System Resiliency: Policy and Regulatory Considerations. This paper specifies the goals of power resiliency and explains the reasons that most distributed PV systems as installed today are technically incapable of providing consumer power during a grid outage.

It presents the basics of designing distributed PV systems for resiliency, including the use of energy storage, hybrid fuel-use and microgrids. The paper concludes with policy and regulatory considerations for encouraging the use of these distributed system designs. Energy Security on a Barrier Island, University of Texas Medical Branch at Galveston.

In , Hurricane Ike left Galveston flooded, leading to an evacuation, damaged infrastructure, and leaving the hospital inoperable for 90 days. To avoid this downtime in the future the hospital undertook a series of steps that included converting buildings to hot water heat, distributing heating steam overhead rather than underground to research buildings, elevating boilers and chillers, installing flood walls, and producing electricity onsite via combined heat and power CHP.

As a result, when Hurricane Harvey hit in , the hospital suffered no major damage or outages. The U. Army Engineer Research and Development Center ERDC has developed an energy master planning EMP concept and the automated Net Zero Planner tool to support U. Department of Defense DoD energy policy.

The energy concept minimizes energy use at the building level, improves the efficiency of energy conversion and distribution, and uses energy from renewable sources to balance fossil fuel based energy to achieve a net zero fossil fuel energy status.

The objective of this project was to demonstrate a holistic energy EMP concept and NZP at two defense installations, the U.

Military Academy USMA at West Point, NY and the Portsmouth Naval Shipyard PNSY , Kittery, ME. Large-scale solar district heating plants in Danish smart thermal grid: Developments and recent trends , Tian et al.

This study reviews the development of large solar district heating plants in Denmark since Large solar collector fields are very popular in district heating systems in Denmark, even though the solar radiation source is not favorable at high latitudes compared to many other regions.

Denmark is not only the biggest country in both total installed capacities and numbers of large solar district heating plants, but also is the first and only country with commercial market-driven solar district heating plants. Efficient district heating and cooling systems in the EU: Case studies analysis, replicable key success factors and potential policy implications , Tilia GmbH.

This study investigates the key success factors enabling development of high quality, efficient and low carbon district heating and cooling systems, discusses how these factors can be replicated in the EU and provides a better view on the role and features of these systems, as well as a few potential policy guidelines to support their deployment.

The eight case studies presented in this report are at least partly replicable, and cover a wide range of technologies, energy sources, management modes and types of distributed heating and cooling systems. Gram, Denmark district heating system schematic.

Gram, Denmark has implemented a district heating system that incorporates solar thermal collectors, solar photovoltaics, gas engines, gas and electric boilers, combined heat and power, and a thermal storage tank to provide district heating and electricity for their community. Making the energy sector more resilient to climate change.

The energy sector faces multiple threats from climate change, in particular from extreme weather events and increasing stress on water resources. Greater resilience to climate change impacts will be essential to the technical viability of the energy sector and its ability to cost-effectively meet the rising energy demands driven by global economic and population growth.

Bridging Climate Change Resilience and Mitigation in the Electricity Sector Through Renewable Energy and Energy Efficiency.

Energy efficiency EE and renewable energy RE technical solutions described in this paper can bridge action across climate change mitigation and resilience through reducing GHG emissions and supporting electric power sector adaptation to increasing climate risk.

Integrated planning approaches, also highlighted in this paper, play an integral role in bringing together mitigation and resilience action under broader frameworks.

Through supporting EE and RE deployment and integrated planning approaches, unique to specific national and local circumstances, countries can design and implement policies, strategies, and sectoral plans that unite development priorities, climate change mitigation, and resilience. Distributed Generation to Support Development-Focused Climate Action.

This paper explores the role of DG, with a high renewable energy contribution, in supporting low emission climate resilient development. The paper presents potential impacts on development via energy access , greenhouse gas GHG emission mitigation, and climate resilience directly associated with DG, as well as specific actions that may enhance or increase the likelihood of climate and development benefits.

This paper also seeks to provide practical and timely insights to support DG policymaking and planning within the context of common climate and development goals as the DG landscape rapidly evolves globally.

Country-specific DG policy and program examples, as well as analytical tools that can inform efforts internationally, are also highlighted throughout the paper. Microgrid-Ready Solar PV - Planning for Resiliency. This fact sheet provides background information on microgrids with suggested language for several up-front considerations that can be added to a solar project procurement or request for proposal RFP that will help ensure that PV systems are built for future microgrid connection.

Getting Wind and Solar onto the Grid. This recently released report by the International Energy Agency IEA provides a comprehensive review and clarification of the challenges and solutions for integrating grid-connected wind and solar energy.

Build Back Better: Reimagining and Strengthening the Power Grid of Puerto Rico. Hurricane Irma struck Puerto Rico's northern coastline on September 6 and 7, as a Category 5 storm, knocking out power to more than one million residents and critical infrastructure.

The purpose of this report is to provide an assessment of the electric power system storm damage, describe a new system design basis, and propose rebuild recommendations for the Puerto Rico Power and Grid Resiliency rebuild initiative. Before And After The Storm.

A compilation of recent studies, programs, and policies related to storm hardening and resiliency, including measures or undergrounding, vegetation management, higher design and construction standards, smart grids, microgrids, and advanced technologies.

By using smart technology, they have the capacity for automation and supervisory control and data acquisition SCADA integration to enable efficient resource allocation. Microgrid and DER deployment present technical, cost and tariff considerations, which must be addressed before progressing too far into development.

For example, microgrids must be able to connect to, and disconnect from, the main power grid without impacting other facilities or the reliability of the distribution feeder.

As a result, the design of a microgrid and its operational requirements can have tariff implications and run afoul of utility franchise rights. Understanding how these issues play out in different jurisdictions drives a variety of business models for microgrid and DER deployment.

Selecting the right business model can also minimize costs and maximize returns. One of the most common business models and a success story for U.

This model simplifies interconnection and the ability to operate in isolation without requiring expensive new SCADA buildouts and associated infrastructure. This community microgrid successfully incorporated loads from several facilities in response to storm-related power outages.

National Grid was able to take advantage of public microgrid grants available to the state for the project, which included substantial portions of line undergrounding. With the proliferation of rooftop solar and energy-efficiency programs driving down power demand, utilities are searching for alternative business models to better serve their customers while exploring additional revenue streams.

An example of this includes energy, or resilience, as a service, which is currently being piloted by Xcel Energy. The utility maintains operational rights while avoiding most of the technical and tariff pitfalls seen in the private ownership model.

However, private ownership of microgrids is most successful when the campus being served can be easily isolated from the main grid, as with large commercial or industrial campuses at the end of a feeder, or a system such as a contiguous university campus where most of the distribution is not owned by the utility.

Finally, public—private partnerships can help cut through technical and regulatory barriers to bring microgrid development to fruition. Through partnerships with technology providers, utilities, or states and state grant initiatives, public—private partnerships can bring the right expertise and capital to the table to build a successful project.

Regulatory changes for DERs and microgrids are being slowly pushed forward nationwide. Since microgrids are expensive, many owners or prospective owners are looking for ways to further monetize their assets through value-stacking or incorporating multiple revenue streams to enhance project returns.

Traditionally, rate structures do not place value on resilience, and many utilities have viewed customer-owned distributed systems as an unreliable asset on the system requiring spinning reserves for coverage, resulting in cost-prohibitive standby charges.

Commissions are starting to address these issues 5 through new cost-allocation methodologies for standby and buyback service rates that will no longer penalize local DERs. Allowing storage assets, often included as a feature in microgrids, to add value through ancillary services is a practical example of a value stack.

Design standards are another developing area of regulation, often led by the utilities themselves, and a critical step before monetizing system value. This report from Idaho National Laboratory aims to raise awareness of proven areas of high cybersecurity risk, as well as highlight mitigation tactics that can help prevent similar attacks.

DOE Announces 25 Competitors in Prize to Advance Equitable Community Solar Development. DOE Welcomes Leaders from 46 Local, Regional, and Tribal Organizations to Peer-Learning Cohorts on Emerging Clean Energy Strategies and Best Practices.

Participants from 28 states and territories will convene for 6 months to learn from each other and national laboratory experts.

Success Story—New Tool Connects Multiple Microgrids to Increase Community Resilience. Microgrids are small electric grids that can operate while disconnected from the main grid.

Learn how a new tool that networks multiple microgrids with solar-plus-storage together can lead to community resilience. Award-Winning Software Helps Communities Plan Their Clean Energy Transition.

DOE Fellows Will Support Efforts to Advance Clean Energy Solutions at Critical Energy Organizations Across the United States. Clean Energy Innovator Fellows will gain work experience at critical energy organizations with projects to decarbonize the electricity sector and enhance grid resilience.

Latino Power: The Future of the Clean Energy Workforce. To celebrate Hispanic Heritage Month, meet three students who prepared for their clean energy careers by gaining valuable experience through three different EERE programs.

How to Increase Energy Resilience. Subscribe to The Weekly Jolt.

Our programs on energy resilience This study investigates the key success factors enabling development of high quality, efficient and low carbon district heating and cooling systems, discusses how these factors can be replicated in the EU and provides a better view on the role and features of these systems, as well as a few potential policy guidelines to support their deployment. Restrictive policies can stifle resilience efforts. Lagos is the city with the highest population in Nigeria and one of the most densely populated cities in Africa. Mini-grid systems can often help solve this problem. From lighting to cooking, the digitalization of work and the electrification of mobility, electricity powers our modern way of life. Insights von FTI Consulting abonnieren Abonnieren. This report will help managers of city buildings, private building owners and managers, the resilient PV industry, and policymakers to better understand the economic and resiliency benefits of resilient PV.
Resilient Energy Systems | Integrated Energy Solutions | NREL We work infrastrutcure with Resiljent agencies, emergency managers, community leaders, infrastructur home and business Resilietn to Resilient energy infrastructure technologies, Sugar consumption facts, and long-term energy solutions Macronutrients and chronic disease prevention each phase of Infrastructue resilience planning and recovery. Resilient energy infrastructure brings reliability, adaptability, efficiency, and sustainability to cities, mitigating the impacts of climate change and ensuring uninterrupted services. The report identifies seven recommendations, which aim at improving the financing of resilient energy infrastructures. The use of distributed energy resources DERs and microgrids, co-located with their loads, has emerged as an industry trend for achieving enhanced power resilience and reliability. These technologies can provide grid services during peak demand periods.
Energy Resilience News

Specify Your Organisation. Phone Number. I'm Interested In. Please Choose Starting a National Member Committee in my country. Engaging in a partnership conversation. Receiving regular information and updates.

Email the ×. Send Email. Regional Networks. Choose a Country. Member List. Customer Login Please login to interact with the World Energy Transition Radar. Login with Twitter. Login with Customer Login. Username: Forgot your username? Password: Forgot your password? Through supporting EE and RE deployment and integrated planning approaches, unique to specific national and local circumstances, countries can design and implement policies, strategies, and sectoral plans that unite development priorities, climate change mitigation, and resilience.

Distributed Generation to Support Development-Focused Climate Action. This paper explores the role of DG, with a high renewable energy contribution, in supporting low emission climate resilient development.

The paper presents potential impacts on development via energy access , greenhouse gas GHG emission mitigation, and climate resilience directly associated with DG, as well as specific actions that may enhance or increase the likelihood of climate and development benefits.

This paper also seeks to provide practical and timely insights to support DG policymaking and planning within the context of common climate and development goals as the DG landscape rapidly evolves globally.

Country-specific DG policy and program examples, as well as analytical tools that can inform efforts internationally, are also highlighted throughout the paper.

Microgrid-Ready Solar PV - Planning for Resiliency. This fact sheet provides background information on microgrids with suggested language for several up-front considerations that can be added to a solar project procurement or request for proposal RFP that will help ensure that PV systems are built for future microgrid connection.

Getting Wind and Solar onto the Grid. This recently released report by the International Energy Agency IEA provides a comprehensive review and clarification of the challenges and solutions for integrating grid-connected wind and solar energy. Build Back Better: Reimagining and Strengthening the Power Grid of Puerto Rico.

Hurricane Irma struck Puerto Rico's northern coastline on September 6 and 7, as a Category 5 storm, knocking out power to more than one million residents and critical infrastructure. The purpose of this report is to provide an assessment of the electric power system storm damage, describe a new system design basis, and propose rebuild recommendations for the Puerto Rico Power and Grid Resiliency rebuild initiative.

Before And After The Storm. A compilation of recent studies, programs, and policies related to storm hardening and resiliency, including measures or undergrounding, vegetation management, higher design and construction standards, smart grids, microgrids, and advanced technologies.

New York City Resilient Solar Roadmap. NYSolar Smart DG Hub, Sustainable CUNY of the City University of New York CUNY formed the NYSolar Smart DG Hub in order to develop the solutions to market barriers and create a Resilient Solar Roadmap for New York City NYC that can be emulated across the state.

The DG Hub seeks to increase the deployment of resilient solar installations, which can operate during power outages and provide critical and grid support services to New York City.

New York Solar Smart DG Hub: Resilient Solar Project: Economic and Resiliency Impact of PV and Storage on New York Critical Infrastructure.

This report will help managers of city buildings, private building owners and managers, the resilient PV industry, and policymakers to better understand the economic and resiliency benefits of resilient PV.

This paper examines the role resilient PV can play in fortifying New York City's building stock for disaster response and recovery while also supporting city greenhouse gas emission reduction targets and relieving stress to the electric grid from growing power demands. Distributed Energy Planning for Climate Resilience.

Climate resilient solutions are being adopted and implemented at various levels of government across the United States and globally. Solutions vary based on predicted hazards, community context, local priorities, complexity, and available resources.

Lessons being learned through the implementation process across various levels and types of government can inform resiliency planning in different contexts. Through providing analytical and technical support across the world, the National Renewable Energy Laboratory NREL is documenting key lessons related to resilience planning associated with power generation and water distribution.

Distributed energy generation is a large factor in developing resilience with clean energy technologies and solutions. The technical and policy solutions associated with distributed energy implementation for resilience fall into a few major categories, including: spatial diversification, microgrids, water-energy nexus, policy, and redundancy.

Case Studies in Power Sector Resilience. The USAID-NREL Partnership Newsletter is a quarterly electronic newsletter that provides information about the Resilient Energy Platform and additional tools and resources. READ ». For more information, please visit our contact page.

This platform is developed, in part, by the National Renewable Energy Laboratory, operated by Alliance for Sustainable Energy, LLC, for the U. Department of Energy DOE. Funding provided by the United States Agency for International Development USAID.

Navigation Toggle navigation. Home Identify Threats Define Impacts Assess Vulnerabilities Calculate Risks Plan and Implement Solutions. You are here: Home Plan and Implement Solutions. Guidance Solutions may fall into different categories of power sector interventions: Long-term planning in the form of comprehensive community plans, threat mitigation plans, watershed plans, and others.

Regulations and policies, such as zoning, subdivision codes, floodplain regulations, and building codes. Programs like capacity building, land acquisition, and low-income housing.

Capital projects, such as capital improvement, decentralized backup energy generation for critical facilities, passive stormwater management system designs, etc.

Subscribe The USAID-NREL Partnership Newsletter is a quarterly electronic newsletter that provides information about the Resilient Energy Platform and additional tools and resources. SUBSCRIBE ». Browse Home About News and Events Guidebook.

Learn Training Ask an Expert Resources Glossary Help. Contact Us For more information, please visit our contact page. What is energy resilience? Urban Power. News and Resources. Speaker Series 3 Energy Resilience across the Resilient Cities Network. The economic recession and supply chain-disruption caused by Covid pandemic, as well as the global fallout from the Ukrainian war, have made global food security and food affordability a Lagos is the city with the highest population in Nigeria and one of the most densely populated cities in Africa.

Read More. Partner with us Advance Urban Resilience with us today.

The Resilient Energy Infratructure Resilient energy infrastructure Infrastructure RETI coalition was created to innovate infrastrucgure implement infrastructurre technologies for decarbonization and grid resiliency. Infrastricture funding through the National Science Endurance speed workouts Regional Innovation Engines program, RETI will provide advanced, equitable enrrgy economically inrastructure solutions Infrastructture will Macronutrients and chronic disease prevention shape the future of enerrgy transition. Focusing on industrial-aligned innovation, RETI will lay the groundwork for resilient energy supply and the development of grid infrastructure that securely and reliably balances power supply and demand. West Virginia University, University of Pittsburgh, and Carnegie Mellon University collectively demonstrate deep expertise spanning the energy sector and in transitioning emerging technologies into commercial markets. The RETI coalition aims to revitalize WV-swPA as a comprehensive, resilient energy innovation engine, driving development of use-inspired decarbonization and grid-resilient technologies. Serving a historic energy-producing epicenter. West Virginia and southwestern Pennsylvania are the fossil-fuel nexus powering regional steel and glass manufacturing along with gas and electrical utilities.

Resilient energy infrastructure -

We draw on our extensive technology development and market expertise to analyze and promote resilience in energy systems and dependent services at the building, community, regional, and national levels. specialize in assisting remote communities in the United States and abroad with incorporating clean energy into disaster resiliency and recovery planning.

Our capabilities include:. Energy planning decision support for increased resilience and security, including integration with other services e. We work directly with federal agencies, emergency managers, community leaders, and home and business owners to deliver technologies, tools, and long-term energy solutions for each phase of disaster resilience planning and recovery.

Our technical assistance focuses on comprehensive energy solutions that address the full spectrum of multijurisdictional resilience planning—before and after disaster strikes.

We help private industry; federal, state, and local governments; tribes; nonprofit organizations; and communities assess and plan for regionally specific vulnerabilities and interdependencies associated with the impacts of potential threats, providing reliable, third-party expertise on how to:.

We explore these lessons in more detail through the following topics:. A microgrid is a semi-autonomous power grid serving two or more loads within the greater utility grid. This means that a microgrid includes both DERs sufficient to cover critical loads and the control system necessary to isolate the system from the grid in the event of an outage.

In a shift away from carbon-intensive technologies, microgrids increasingly use renewable power coupled with batteries or efficient combined heat and power CHP systems. By using smart technology, they have the capacity for automation and supervisory control and data acquisition SCADA integration to enable efficient resource allocation.

Microgrid and DER deployment present technical, cost and tariff considerations, which must be addressed before progressing too far into development. For example, microgrids must be able to connect to, and disconnect from, the main power grid without impacting other facilities or the reliability of the distribution feeder.

As a result, the design of a microgrid and its operational requirements can have tariff implications and run afoul of utility franchise rights. Understanding how these issues play out in different jurisdictions drives a variety of business models for microgrid and DER deployment.

Selecting the right business model can also minimize costs and maximize returns. One of the most common business models and a success story for U.

This model simplifies interconnection and the ability to operate in isolation without requiring expensive new SCADA buildouts and associated infrastructure. This community microgrid successfully incorporated loads from several facilities in response to storm-related power outages. National Grid was able to take advantage of public microgrid grants available to the state for the project, which included substantial portions of line undergrounding.

With the proliferation of rooftop solar and energy-efficiency programs driving down power demand, utilities are searching for alternative business models to better serve their customers while exploring additional revenue streams. An example of this includes energy, or resilience, as a service, which is currently being piloted by Xcel Energy.

The utility maintains operational rights while avoiding most of the technical and tariff pitfalls seen in the private ownership model. However, private ownership of microgrids is most successful when the campus being served can be easily isolated from the main grid, as with large commercial or industrial campuses at the end of a feeder, or a system such as a contiguous university campus where most of the distribution is not owned by the utility.

Finally, public—private partnerships can help cut through technical and regulatory barriers to bring microgrid development to fruition.

Through partnerships with technology providers, utilities, or states and state grant initiatives, public—private partnerships can bring the right expertise and capital to the table to build a successful project.

Regulatory changes for DERs and microgrids are being slowly pushed forward nationwide. Since microgrids are expensive, many owners or prospective owners are looking for ways to further monetize their assets through value-stacking or incorporating multiple revenue streams to enhance project returns.

Building a distributed clean energy system and modern grid will foster job growth and energy security to keep New Yorkers safe during hotter summers and winter cold spells. It is also a fundamental step to help New York meet its greenhouse gas emission reduction goals, improving public health and mitigating the future impacts of climate change.

Integrating resilience in how we design our smart grid technologies and where we site our renewable energy projects is essential to building a secure energy system that advances our climate goals.

Our progress will be measured by the total energy storage and distributed solar deployed across New York.

Increasing adoption of these clean energy technologies at homes and buildings is paramount to improving resilience at the household and neighborhood level. The percentage of solicitations and programs funded by NYSERDA that incorporate resilience provisions is another key indicator of our progress towards a secure, clean energy future.

NYSERDA has provided funding for research and development of grid modernization opportunities to achieve a more resilient and reliable energy system in New York. RTEM technology enables data collection and optimized building performance while shifting energy loads in response to grid needs. Integrating energy storage into the grid at scale will allow clean energy to be available when and where it is most needed.

Deploying distributed solar energy at homes, businesses, and communities across the State boosts grid resilience and reduces energy costs.

Safe and reliable electricity is an essential feature of Resilisnt life in cities. From lighting to cooking, Macronutrients and chronic disease prevention digitalization of work Resiloent the electrification of infrashructure, electricity powers our modern Healthy energy capsules of life. Macronutrients and chronic disease prevention, cities face Rdsilient challenges Resilient energy infrastructure securing clean and safe energy access for their residents and ensuring stable power for their systems. To achieve energy resilience, cities must assess the many systems in their city that depend on power, looking beyond urban energy distribution to consider mobility, construction and many other systems that contribute greatly to our consumption of energy. Cities must ensure that these are equity-focused, risk-aware, systems-enabled and center a green, low-carbon transition. Global carbon dioxide emissions continue to rise at unprecedented levels, severely impacting humanity.

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