Behind the Paper
The real stories behind the latest research papers, from conception to publication, the highs and the lows
Filtered by: Electrical & Electronic Engineering
Optical manipulation of electronic dimensionality in a quantum material
Exotic phenomenon can be achieved in quantum materials by confining electronic states into two dimensions. For example, quantized Hall effect can be resulted in a unit cell of a periodic 2D system (Nobel prize in 1988), relativistic fermions are realized in a single layer of carbon atoms arranged in a two-dimensional (2D) honeycomb lattice while such electronic state is absent in the bulk graphite (Nobel prize in 2010), superconducting transition temperature can be enhanced by confining materials into 2D, and so on. Ordinarily, the 2D electronic system can be artificially created by exfoliating the layered materials, growing on substrates via molecular beam epitaxy, or building interfaces between two different materials. Searching for new methods to confine electronic states into 2D is important in condensed matter physics.
Crosslinking polymers break membrane separation boundaries
Current membranes suffer from the well-known permeability-selectivity upper bound. Here is the story behind the work of making the most selective microporous polymer membranes with record high gas separation efficiency, beating the latest gas separation upper bounds.
Magnetic manipulation of non-magnetic objects: Our solution to a seemingly paradoxical problem
We've discovered how to use rotating magnetic fields to dexterously manipulate objects made of metals that are typically considered non-magnetic. This has the potential to contribute a solution to the problem of space debris.
