Integrative Risk Management - towards resilient cities
28 August - 1 September 2016 • Davos • Switzerland
IDRC Davos 2016 CONFERENCE AGENDA
The programme includes the IDRC Davos 2016 agenda of sessions, plenary sessions, special panels and workshops. Click on the session title for more details.
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Poster 5: Urban Areas and Critical Infrastructure: Challenges and Opportunities for Resilient Cities
Time: 31/Aug/2016: 12:55pm-2:00pm
Topics: Energy Supply, Mobility / Transportation, Critical Infrastructures, Critical Infrastructures, Water & Energy Supply
Keywords: energy supply, water use, decentralisation, independency, solar energy; terror attack;
Safe and Decentralised Solar Hydrogen Fuel Production and Storage for Residential Building and Mobility Applications [PB 54]
1Empa. Swiss Federal Laboratories for Materials Science & Technology, Switzerland; 2University of Pretoria; 3University of Botswana; 4Empa. Swiss Federal Laboratories for Materials Science & Technology, Switzerland
Large scale facilities pose a potential risk and threat because with one isolated attack large damage can be obtained, for example in a city, potentially with a large number of human casualties.
I present a solar energy harvesting strategy which allows to generate fuel for housing and mobility in a decentralised form. A city or a part of a city cannot be shut down from energy supply by a terrorist attack on this energy generation and storage infrastructure, because it is virtually fully decentralised and independent (no electric grid).
This system is based on photo-electrochemical cell technology and takes advantage of the solar energy arriving at small landscapes in local neighbourhoods in the range of few 100 sqm area per operation unit. The fuel is hydrogen, or hydrocarbons such as methane or methanol, when carbon dioxide greenhouse gas is included in the chemical process cycle. The necessary water for the process comes from the local sewage wastewater system.
The problem of energy storage in absence of sunshine during the day is also solved by this technology, because a storable fuel is produced. The pronounced safety feature of this approach is that many small units are built, which are impossible to demolish in a terror strike, as opposed to single large industrial complexes which are very attractive for terrorists to attack because of the high destructive "efficiency" by a single plot, but also by the commensurate public attention and "terror", literally, which comes with the attack on a landmark scale facility.
The negative part in this calculation comes from the loss of efficiency by moving from few large units to many small units. This is likely the price which society has to pay for the gain in safety from terrorism.
Artur Braun is a Physicist from RWTH Aachen with doctoral degree from ETH Zürich 15 year expertise in renewable energy and environmental technologies. He was postdoc researcher on batteries in Berkeley and carbon soot in Kentucky, prior to becoming research group leader and Marie Curie Fellow at Empa in Switzerland. His scientific focus is on charge transfer processes in materials for use in renewable energy systems, like fuel cells, batteries, photoelectrochemical cells, which he studies at neutron and synchrotron facilities. Dr. Braun's Erdös number is a prestigious low 3. He is IPCC expert on renewables and was Meeting Chair for the 2015 MRS Spring Meeting in San Francisco, and is listed by Foreign Policy magazine as a Top 100 Leading Global Thinker of 2014.
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Conference: IDRC Davos 2016
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