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Technological hazard

Technical or technological disasters are caused by events that can be intense and sudden, induced by human processes. They originate from technological or industrial conditions, dangerous procedures, infrastructure failures or specific human activities (UNGA, 2016).

Technical systems are complex, with many dependent subsystems. The failure of one element within this system can cascade throughout the chain, causing a series of failures leading to a disaster. Technical hazards are increasing due to the scope of technological expansion. They include industrial activity that includes dangerous conditions, processes, all transport systems (land, sea, air), defensive or offensive weapons systems and power plants.

By 2050, most of humanity will live downstream of large dams built in the 20th century.

A new set of emerging technological risks under the Sendai Framework includes Information and communications technology (ICT)-related hazards. The increasing dependence upon complex large-scale network architectures of information technologies also increases exposure to cybersecurity threats. These threats include computer viruses, worms, Trojan horses, malware, spoofing attacks, identity theft, the theft and illegal disclosure of data, the loss of data and contamination of data. They have the potential to disrupt essential infrastructure operations such as communication, health, banking, transportation, energy, education and many other services.

Risk factors

  • Ageing, abandoned or idle installations.
  • Insufficient institutional and legal capacities.
  • Natural hazards: storms, landslides, floods or earthquakes can cause industrial accidents.

Vulnerable areas

  • Residential communities around industrial establishments tend to be most at risk because of their proximity.

Risk reduction measures

  • Assess the risks before planning and building critical infrastructure.
  • Develop policies and practices for continuity management.
  • Integrate the risks into planning, foresee and reduce cascading effects.
  • Create a hazard map to identify people at risk and their vulnerability.
  • Draft national, regional and local response plans.
  • Put in place early warning/monitoring systems to inform response.
  • Ensure contingency and response plans are in place at a national and local level to evacuate people on time.
  • Assess new technologies.
  • Improve crisis communication before, during and after the event.
  • Organize training and exercises for complex scenarios involving multiple interdependent failures.
  • Educate and raise awareness on potential risks.

Latest Technical Disaster additions in the Knowledge Base

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Documents and publications

This policy brief offers strategies aimed at improving coverage of basic chemicals-management legislation. Potential avenues for gaining traction in achieving wider implementation include: regional collaboration, drawing on the potential of the United

Stockholm Environment Institute
Documents and publications

This publication focuses on the challenges and their possible solutions in the areas of leadership, human performance and internal communication in a severe nuclear emergency. It presents a brief overview of some of the key concepts, especially how they

International Atomic Energy Agency
Update

Rising sea levels combined with more frequent and extensive flooding from coastal storms like hurricanes may increase the risk to chemical facilities near waterways in the United States. But even as flooding risks increase, chemical companies continue to build in vulnerable areas.

New York Times, the
Cover
Documents and publications

This educational case study focuses on the industrial accident in Tianjin, China in 2015, which resulted from an explosion caused by the improper storage of chemicals. This case study consists of a video and case document.

Hong Kong Jockey Club Disaster Preparedness and Response Institute
Harvard T.H. Chan School of Public Health
Documents and publications

This educational case study focuses on the 2011 Fukushima nuclear accident in Japan and consists of a case document and accompanying video.

About this case

On March 11, 2011, Japan suffered an unprecedented triple disaster. A 9.0 M earthquake occurred

Hong Kong Jockey Club Disaster Preparedness and Response Institute
Harvard T.H. Chan School of Public Health
Documents and publications

An investigation into the cooperation between the Netherlands, Belgium and Germany concerning the nuclear power plants in the border areas

This report outlines an investigation conducted to better understand the manner in which the Netherlands and

Dutch Safety Board
Documents and publications

This report consists of a set of expert contributions that have been enriched with national experiences from countries such as the United States and Japan in an effort to learn from non-nuclear events and build an all-hazards approach to emergency

Organisation for Economic Co-operation and Development
Research briefs

Mapping common pathways along which the effects of natural and man-made disasters travel allows more flexible and resilient responses in the future, according to UCL researchers. The team studied two scenarios with different hazards – extreme space weather events where the Sun’s activity may compromise satellite functions, including GPS, and cyber security attacks.

University College London (UCL)
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