Measuring and Monitoring Urban Impacts on Climate Change from Space

As urban areas continue to expand and play a critical role as both contributors to climate change and hotspots of vulnerability to its effects, cities have become battlegrounds for climate change adaptation and mitigation. Large amounts of earth observations from space have been collected over the last five decades and while most of the measurements have not been designed specifically for monitoring urban areas, an increasing number of these observations is being used for understanding the growth rates of cities and their environmental impacts. Here we reviewed the existing tools available from satellite remote sensing to study urban contribution to climate change, which could be used for monitoring the progress of climate change mitigation strategies at the city level. We described earth observations that are suitable for measuring and monitoring urban population, extent, and structure; urban emissions of greenhouse gases and other air pollutants; urban energy consumption; and extent, intensity, and effects on surrounding regions, including nearby water bodies, of urban heat islands. We compared the observations available and obtainable from space with the measurements desirable for monitoring. Despite considerable progress in monitoring urban extent, structure, heat island intensity, and air pollution from space, many limitations and uncertainties still need to be resolved. We emphasize that some important variables, such as population density and urban energy consumption, cannot be suitably measured from space with available observations.

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Sensing Global Changes in the Local Patterns of Energy Consumption in Cities During the Early Stages of the COVID-19 Pandemic

10.21203/rs.3.rs-846222/v1 ◽

2021 ◽

Author(s):

Francisco Rowe ◽

Caitlin Robinson ◽

Nikos Patias

Keyword(s):

Energy Consumption ◽

Urban Areas ◽

Energy Demand ◽

Global Changes ◽

Night Time ◽

Global Pandemic ◽

Urban Energy ◽

Spatio Temporal ◽

Dominant Narratives ◽

Urban Energy Consumption

Abstract COVID-19, and the wider social and economic impacts that a global pandemic entails, have led to unprecedented reductions in energy consumption globally. Whilst estimates of changes in energy consumption have emerged at the national scale, detailed sub-regional estimates to allow for global comparisons are less developed. Using night-time light satellite imagery from December 2019-June 2020 across 50 of the world’s largest urban conurbations, we provide high resolution estimates (450m2) of spatio-temporal changes in urban energy consumption in response to COVID-19. Contextualising this imagery with modelling based on indicators of mobility, stringency of government response, and COVID-19 rates, we provide novel insights into the potential drivers of changes in urban energy consumption during a global pandemic. Our results highlight the diversity of changes in energy consumption between and within cities in response to COVID-19, somewhat refuting dominant narratives of a shift in energy demand away from dense urban areas. Further modelling highlights how the stringency of the government’s response to COVID-19 is likely a defining factor in shaping resultant reductions in urban energy consumption.

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FRAMEWORK FOR MEASURING URBAN ENERGY SECURITY : CITIZEN PERSPECTIVE

Jurnal Pengembangan Kota ◽

10.14710/jpk.7.1.34-45 ◽

2019 ◽

Vol 7 (1) ◽

pp. 34

Author(s):

Yudha Prambudia ◽

Arief Rahmana ◽

Anita Juraida

Keyword(s):

Energy Consumption ◽

Final Stage ◽

Energy Security ◽

Critical Role ◽

Security Evaluation ◽

Urban Context ◽

Urban Energy ◽

Urban Energy Consumption ◽

Systematic Framework

The ever increasing urban energy consumption has always been an important issue of urban energy security. Citizen plays critical role in shaping the energy consumption. Therefore, citizen perspective can give significant impact to urban energy security evaluation. This research aims to provide a systematic framework to measure urban energy security taking into account the perspective of citizen and showcase its implementation in a case of Bandung city. The proposed framework is a straight five stages process as follow; (1) establishing the urban context, (2) defining energy security relevant to the context, (3), determining dimensions of energy security , (4) determining indicators and and metrics, and (5) the final stage is calculating energy security. The implementation case shows Bandung’s energy security is at Middle Low status. It also verify that the framework is operationally viable and it can capture the significance of citizen perspective.

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The Paradox of Climate Change Mitigation and Adaptation in Danish Housing

Open House International ◽

10.1108/ohi-04-2012-b0003 ◽

2012 ◽

Vol 37 (4) ◽

pp. 19-28

Author(s):

Rob Marsh

Keyword(s):

Climate Change ◽

Energy Consumption ◽

Solar Energy ◽

Theoretical Study ◽

Climate Adaptation ◽

Mitigation Strategy ◽

Mitigation Strategies ◽

Space Heating ◽

Climate Mitigation ◽

Passive Solar

Climate change means that buildings must greatly reduce their energy consumption. It is however paradoxical that climate mitigation in Denmark has created negative energy and indoor climate problems in housing that may be made worse by climate change. A literature review has been carried out of housing schemes where climate mitigation was sought through reduced space heating demand, and it is shown that extensive problems with overheating exist. A theoretical study of regulative and design strategies for climate mitigation in new build housing has therefore been carried out, and it is shown that reducing space heating with high levels of thermal insulation and passive solar energy results in overheating and a growing demand for cooling. Climate change is expected to reduce space heating and increase cooling demand in housing. An analysis of new build housing using passive solar energy as a climate mitigation strategy has therefore been carried out in relation to future climate change scenarios. It is shown that severe indoor comfort problems can occur, questioning the relevance of passive solar energy as a climate mitigation strategy. In conclusion, a theoretical study of the interplay between climate adaptation and mitigation strategies is carried out, with a cross-disciplinary focus on users, passive design and active technologies. It is shown that the cumulative use of these strategies can create an adaptation buffer, thus eliminating problems with overheating and reducing energy consumption. New build housing should therefore be designed in relation to both current and future climate scenarios to show that the climate mitigation strategies ensure climate adaptation.

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A new clustering and visualization method to evaluate urban energy planning scenarios

10.31224/osf.io/b9znk ◽

2018 ◽

Author(s):

Sara Torabi Moghadam ◽

Silvia Coccolo ◽

Guglielmina Mutani ◽

Patrizia Lombardi ◽

Jean Louis Scartezzini ◽

...

Keyword(s):

Energy Consumption ◽

Urban Areas ◽

Energy Demand ◽

Planning Process ◽

Energy Transition ◽

Climatic Conditions ◽

Energy Planning ◽

Transition Strategies ◽

Urban Energy ◽

The City

The spatial visualization is a very useful tool to help decision-makers in the urban planning process to create future energy transition strategies, implementing energy efficiency and renewable energy technologies in the context of sustainable cities. Statistical methods are often used to understand the driving parameters of energy consumption but rarely used to evaluate future urban renovation scenarios. Simulating whole cities using energy demand softwares can be very extensive in terms of computer resources and data collection. A new methodology, using city archetypes is proposed, here, to simulate the energy consumption of urban areas including urban energy planning scenarios. The objective of this paper is to present an innovative solution for the computation and visualization of energy saving at the city scale.The energy demand of cities, as well as the micro-climatic conditions, are calculated by using a simplified 3D model designed as function of the city urban geometrical and physical characteristics. Data are extracted from a GIS database that was used in a previous study. In this paper, we showed how the number of buildings to be simulated can be drastically reduced without affecting the accuracy of the results. This model is then used to evaluate the influence of two set of renovation solutions. The energy consumption are then integrated back in the GIS to identify the areas in the city where refurbishment works are needed more rapidly. The city of Settimo Torinese (Italy) is used as a demonstrator for the proposed methodology, which can be applied to all cities worldwide with limited amount of information.

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