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Coherent Energy Transfer and the Potential Implications for Consciousness
( J. Tory Tool ),( P. Kurian ),( T. J. A. Craddock ) 서울대학교 인지과학연구소 2018 Journal of Cognitive Science Vol.19 No.2
The argument that biological systems are too “warm and wet” to support quantum effects is becoming increasingly antiquated as research in the field of quantum biology progresses. In fact, not only is it becoming apparent that quantum processes may regularly take place in biological systems, but these processes may underlie the mechanisms of consciousness and propel our models of conceptualizing the human brain into the next era of scientific understanding. The phenomena of consciousness have allured scientists and philosophers for thousands of years, while a precise technical understanding has remained elusive. If possible, developing this understanding will likely be one of humanity’s greatest achievements. Knowing the fundamental processes that create conscious experience has far-reaching implications, from the potential birth of true artificial intelligence to a better understanding of mental health disorder etiologies and treatments. One major challenge in the mental health professions, and, ultimately, in empathy of any kind, is being able to see from and appreciate another person’s unique, subjective experience. Discoveries in the field of consciousness could help bridge this gap.
The behaviour of structures under fire – numerical model with experimental verification
Neno Torić,Alen Harapin,Ivica Boko 국제구조공학회 2013 Steel and Composite Structures, An International J Vol.15 No.3
This paper presents a comparison of results obtained by a newly developed numerical model for predicting the behaviour of structures under fire with experimental study carried out on heated and simply supported steel beam elements. A newly developed numerical model consists of three submodels: 3D beam model designed for calculating the inner forces in the structure, 2D model designed for calculation of stress and strain distribution over the cross section, including the section stiffness, and 3D transient nonlinear heat transfer model that is capable of calculating the temperature distribution along the structure, and the distribution over the cross section as well. Predictions of the calculated temperatures and vertical deflections obtained by the numerical model are compared with the results of the inhouse experiment in which steel beam element under load was heated for 90 minutes.