His major research focused on
engineering seismology and geotechnical earthquake engineering. He specialised in earthquake hazard assessment, the earthquake resistant design of geotechnical structures (dams and foundations) and strong-motion seismology; on which he published widely (more than 300 publications, of which several papers appeared in highly cited journals), provided consulting services and edited work of other colleagues in numerous journals. He was co-founder of the Journal of Earthquake Engineering and one of the early creators of the European Association for Earthquake Engineering. He is among the most widely cited authors in the diverse fields of
civil engineering and
earthquake engineering, and one of the most cited authors in the field of engineering seismology to which he is considered by many to be a founding father.
Seismic dam and slope stability His doctoral work on the seismic stability of dams (1958) dealt, among other issues, with the prediction of permanent displacements in earth dams after earthquakes and formed the basis of what is today known as the
Newmark's sliding block analysis method (1965).
Newmark himself acknowledged Ambraseys' contribution to this method through
"... the comments and suggestions... of his colleague for several months, while he was visiting the University of Illinois...". Moreover,
Harry Bolton Seed, the founding father of the diverse academic field geotechnical earthquake engineering, in the 19th
Rankine Lecture acknowledged the influence of Ambraseys,
"... who introduced him to the problems of earthquakes and encouraged him to become involved in this new area pointing out the enormous field laboratory that existed in California..." Ambraseys' early work on the seismic stability of earth dams set the foundations of a new method of analysis which was later further developed by other researchers, the "shear beam" method; which was an early attempt to consider the dynamic behavior of an earth dam due to seismic wave propagation. His early work on seismic stability of dams attracted the attention and inspired numerous young researchers in that field. The most notable example is his first PhD student
Sarada K. Sarma whose research led to the development of the
Sarma method of seismic slope stability. Extensions of that work and on the calculation of seismic displacements led to new developments regarding earthquake induced ground displacements. Ambraseys had also in his early days researched in the aspect of theoretical ground response analysis. In fact, his pioneering work on the seismic response of dam was based on those early considerations of ground response and was their extension by considering the geometry of an earth dam as a truncated wedge. He led a European effort to collect and process various strong motion data from the European region. Finally, a huge amount of data was published providing access to seismic researchers and practitioners in Europe. Many people argue that Ambraseys's greatest contribution is in the field of historical seismicity. He personally searched, found and collected an enormous amount of information about earthquakes which existed in various libraries, manuscripts and other forms of written communication around the world. In 1985 he applied historical seismology to make an influential
prediction about the maximum magnitude of earthquakes in the UK: "The seismicity of the UK is clearly different from that of eastern USA or W Africa in that either (i) no earthquakes of M ≥ 6.0 occur or (ii) 700 years is not long enough to reveal such events in the UK, whereas 100 years is more than adequate in the eastern USA and W Africa ... Is there anywhere on the continents seismically quieter than the UK?" His ability to speak fluently a number of languages allowed his direct involvement in the search for the original sources of earthquake information. Finally, he was in a good position to identify several erroneous information about earthquake events, and therefore he was able to develop new correct catalogues of earthquake history with updated and corrected information.
Other contributions He also worked on hydrodynamics and investigated how to calculate hydrodynamic forces on various types of structures. Moreover, his contribution to tsunamis has been significant, and there is an intensity scale named after him (
Sieberg-Ambraseys Tsunami Intensity Scale). == Earthquake engineering educator ==