This journal was released in 1997 and is ranking in the first third regarding the impact factor. This journal is the core publication in the field of time-dependent structural materials. It is published by the leading publishing house of scientific and expert publicism, Springer-Kluwer. Chief editorialship of the journal allows our team direct contact with the research activities of leading experts in this field around the world.
C.04 Editorial board of an international magazine
COBISS.SI-ID: 3749403The European Masters in Engineering Rheology – EURHEO offers an advanced integrative interdisciplinary education programme on Rheology and its applications to different Engineering areas. EURHEO combines the expertise of seven leading European Universities. Pursuant to the rules of the European postgraduate schools, each student participating in the EURHEO programme has to do research work in at least three universities in three countries. On completion of their studies, students receive two diplomas.
D.02 Establishment of a research centre, laboratory, study course, association
Research group has co-organized symposium entitled "Rheology of solids" organized within the "Annual European Rheology Conferences - AERC 2010, April 15-17, 2009, Cardiff, United Kingdom; European Society of Rheology". Organizers of the symposium were I. Emri, and Dietmar Drummer.
B.01 Organiser of a scientific meeting
"International Conference on Mechanics of Time-Dependent Materials" - MTDM is organized every two years in collaboration between the Centre for Experimental Mechanics (UL-FS), Californian Institute of Technology – Caltech (USA), and Aoyama University (Japan) with the purpose of exhanging ideas, and presenting the new scientific contribution in the field of the mechanics of time-dependent materials. The last conference was organized in September 2010 in Portorož (http://www.mtdm10.si/).
C.01 Editorial board of a foreign/international collection of papers/book
COBISS.SI-ID: 252271104At given boundary conditions all systems are in most probable state, i.e., stable state. However, by changing boundary conditions through outside excitation we may enforce new stable states which are normally not observed. The new stable sate is “dissipative” – it consumes energy to be maintained. The time-scale of excitation, and its spatial orientation defines how the matter will be re-distributed within a given space, and consequently change the overall inherent structure that results in the change of the macroscopic properties of the system.
B.04 Guest lecture
COBISS.SI-ID: 11672347