Resilience of chemical industrial areas through attenuation-based security

This paper investigates the possibility of attenuation-based security within chemical industrial areas. Representing chemical industrial areas as mathematical networks, we prove by case-study that the resilience to disaster of such areas may follow a power-law distribution. Furthermore, we examine w...

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Veröffentlicht in:	Reliability engineering & system safety 2014-11, Vol.131, p.94-101
Hauptverfasser:	Reniers, G.L.L., Sörensen, K., Khan, F., Amyotte, P.
Format:	Artikel
Sprache:	eng
Schlagworte:	Applied sciences Attenuation Attenuation-based security Chemical engineering Chemical industrial clusters Domino effects Exact sciences and technology Firm modelling Industrial areas Industrial parks Islands Mathematical networks Networks Operational research and scientific management Operational research. Management science Reliability theory. Replacement problems Resilience Resilience engineering Risk theory. Actuarial science Security Terrorism Terrorist attacks
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creator	Reniers, G.L.L. Sörensen, K. Khan, F. Amyotte, P.
description	This paper investigates the possibility of attenuation-based security within chemical industrial areas. Representing chemical industrial areas as mathematical networks, we prove by case-study that the resilience to disaster of such areas may follow a power-law distribution. Furthermore, we examine what happens to the network when highly hazardous installations would be intelligently protected against malicious acts: the network disintegrates into separate smaller networks. Hence, islands are formed with no escalation danger in between. We conclude that it is possible to protect chemical industrial areas in such a way that they are more resilient against terrorism.
doi_str_mv	10.1016/j.ress.2014.05.005
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Representing chemical industrial areas as mathematical networks, we prove by case-study that the resilience to disaster of such areas may follow a power-law distribution. Furthermore, we examine what happens to the network when highly hazardous installations would be intelligently protected against malicious acts: the network disintegrates into separate smaller networks. Hence, islands are formed with no escalation danger in between. 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Representing chemical industrial areas as mathematical networks, we prove by case-study that the resilience to disaster of such areas may follow a power-law distribution. Furthermore, we examine what happens to the network when highly hazardous installations would be intelligently protected against malicious acts: the network disintegrates into separate smaller networks. Hence, islands are formed with no escalation danger in between. We conclude that it is possible to protect chemical industrial areas in such a way that they are more resilient against terrorism.</description><subject>Applied sciences</subject><subject>Attenuation</subject><subject>Attenuation-based security</subject><subject>Chemical engineering</subject><subject>Chemical industrial clusters</subject><subject>Domino effects</subject><subject>Exact sciences and technology</subject><subject>Firm modelling</subject><subject>Industrial areas</subject><subject>Industrial parks</subject><subject>Islands</subject><subject>Mathematical networks</subject><subject>Networks</subject><subject>Operational research and scientific management</subject><subject>Operational research. Management science</subject><subject>Reliability theory. Replacement problems</subject><subject>Resilience</subject><subject>Resilience engineering</subject><subject>Risk theory. 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subjects	Applied sciences Attenuation Attenuation-based security Chemical engineering Chemical industrial clusters Domino effects Exact sciences and technology Firm modelling Industrial areas Industrial parks Islands Mathematical networks Networks Operational research and scientific management Operational research. Management science Reliability theory. Replacement problems Resilience Resilience engineering Risk theory. Actuarial science Security Terrorism Terrorist attacks
title	Resilience of chemical industrial areas through attenuation-based security
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