Quantum materials represent a groundbreaking frontier in materials science, where quantum mechanical principles drive unique and extraordinary properties. These materials include superconductors, topological insulators, and quantum dots, which exhibit behaviors like zero electrical resistance or spin-dependent conductivity. Their ability to manipulate quantum states has profound implications for advanced technologies, including quantum computing, energy storage, and next-generation electronics.
Researchers in materials engineering focus on understanding and designing these materials at atomic and molecular levels to unlock their full potential. By leveraging quantum phenomena, they aim to create ultra-efficient energy systems, faster communication networks, and transformative medical devices. Quantum materials are not only expanding scientific knowledge but also shaping a sustainable and technologically advanced future, making them a pivotal area of exploration.
Title : The effect of substitution of Mn by Pd on the structure and thermomagnetic properties of the Mn1−xPdxCoGe alloys (where x = 0.03, 0.05, 0.07 and 0.1)
Piotr Gebara, Politechnika Czestochowska, Poland
Title : Prospective study of copper sulfide nanofilms
Paulo Cesar De Morais, Catholic University of Brasilia, Brazil
Title : Modeling phase crystallization in Ge-rich Ge-Sb-Te PCRAMs
Alain Portavoce, IM2NP/CNRS, France
Title : Application of vanadium and tantalum single-site zeolite catalysts in heterogeneous catalysis
Stanislaw Dzwigaj, Sorbonne University, France
Title : Process parameters optimization and mechanical properties of additively manufactured ankle-foot orthoses based on polypropylene
Mohamed Yousfi, INSA Lyon, IMP Laboratory, France
Title : Determination of phase stress flow curves in dual phase steels through micromechanical adaptive iteration algorithm
Silvie Maria Tanu Halim, McMaster University, Canada