Combining Clarke's model with first‐principles calculation of average sound velocity, the minimum lattice thermal conductivities (κmin) of Y3Al5O12 (YAG), YAlO3 (YAP) and Y4Al2O9 (YAM) are predicted to be 1.59, 1.61, and 1.10 W·(m·K)−1, respectively. The weak Y–O polyhedra provide “weak zones” that scattering phonons and lead to the low κmin of ternary Y–Al–O compounds. In addition, the extremely low κmin of YAM is attributed to its higher levels of local disorder of crystal structure and weaker chemical bonding compared with those of YAG and YAP. Inspired by theoretical predictions, dense and phase‐pure YAM is synthesized and the experimental thermal conductivity is only 1.56 W·(m·K)−1at 1273 K. Finally, YAM is highlighted as a potential thermal barrier material for its low thermal conductivities at temperatures from 473 to 1273 K.
There are many heterogeneous roles involved in safety management. The behaviour interaction and strategic interactions among them will have an important impact on safety processes in the execution phase. Game theory is a powerful method for clarifying the influence mechanism and is currently experiencing rapid growth in operations, planning and management, as well as in safety management. To comprehensively sort out the current situation of game theory in safety management and finally find out the development trend of applying game theory in safety management. This paper reviews 57 related articles (2010-2019) surrounding game theory and safety management. The main results show that the applications of game theory in the research of safety management is helpful to find out the cause and motive force of unsafe behaviours. We find that currently, most researches are mainly in traffic safety, and researchers may point to food safety, construction safety, coal mine safety, electrical safety and other fields in the future. In addition, game theory plays a very important role in guiding the decision-making of stakeholders in the process of safety management.
The unique characteristics like periodic and locally resonant behaviors of acoustic metamaterials result in an anomalous response to the wave propagation and exhibit complete elastic wave bandgaps. However, these unusual properties arise from the geometry of the artificially designed metastructure and can be significantly affected under the exposure of the thermal environment. In this paper, we present a thermally tunable two-dimensional acoustic metamaterial with a hexagonal lattice. The numerical results demonstrated that by adjusting the externally applied temperature to the structure and imposing several different load conditions like thermal deformation and thermal stress, a tunable effective mass density of the metamaterial could be obtained. The proposed concept further extends the ongoing research in the field of tunable acoustic metamaterials.
We investigate nonlinear Dicke quantum phase transition (QPT) induced by inter-atomic nonlinear interaction and its quantum witness in a cavity-Bose–Einstein-condensate (BEC) system. It is shown that inter-atomic nonlinear interaction in a cavity BEC system can induce first-order Dicke QPT. It is found that this nonlinear Dicke QPT can happen in an arbitrary coupling regime of the cavity and atoms. It is demonstrated that the quantum speed limit time can witness the Dicke QPT through its sudden change at the critical point of the QPT.
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