Explore how scientists use lithography techniques to trap, arrange, and manipulate nanoparticles for revolutionary applications in medicine, electronics, and computing.
Explore recent breakthroughs in diamond quantum technology, from NV centers to scalable quantum systems and novel diamond creation methods.
Explore how Absolute Reaction Rate Theory bridges chemistry and physics by explaining the molecular transition state and activation energy in chemical reactions.
Explore the 60-year legacy of the J. Heyrovský Institute of Physical Chemistry, from Nobel Prize-winning polarography to cutting-edge quantum computing and environmental research.
Explore how microscopic stress and stacking faults in silicon carbide impact modern electronics and the scientific methods used to detect them.
Explore how hydrostatic pressure and chemical substitution tune phase transitions in UCr₂Si₂, revealing the quantum interplay between structure and magnetism.
Explore the fascinating chemical, magnetic and electronic properties of NaxCoO2, a versatile material with applications in batteries, thermoelectrics and catalysts.
Explore the fascinating world of quantum magnets and complex antiferromagnetic order on honeycomb lattices, from theoretical foundations to experimental discoveries.
Explore how quantum computing is revolutionizing molecular simulation, catalyst design, and drug discovery in chemical and biochemical engineering.
Explore how Electron Paramagnetic Resonance (EPR) spectroscopy helps scientists study molecules with unpaired electrons and their applications in chemistry.