Electronic CHANGE TOPIC

Electronic properties news, March 2019

Researchers have used machine learning to create molecular models for faster screening of materials such as organic electronics.

Researchers have found a layered material made from sodium, tin and arsenic that can act as both an electron-holder and a hole-holder.

Researchers have found that thin layers of niobium arsenide, a Weyl semimetal, have three times the conductivity of copper at room temperature.

Researchers have discovered the strongest topological conductor yet, in the form of thin crystal samples with a spiral-staircase structure.

fast-screening of potential non-noble metal two-dimensional catalysts for hydrogen evolution reaction

Hydrogen from seawater without decay or delay

Sandwiching a layer of graphene between two layers of 2D boron nitride can produce superlattices that confer novel electrical properties.

Scientists have used a new technique called ultrafast surface X-ray scattering to visualize the motion of atoms in a 2D material.

The twist angle between layers of 2D semiconductors provides a ‘tuning knob’ to turn them into an exotic quantum material.

Physicists have discovered that placing 2D semiconductors on top of each other and twisting them causes the emergence of novel hybrid properties.

By combining supercomputing with experimental methods, researchers have been able to identify promising materials for dye-sensitized solar cells

Researchers used machine learning to simulate the quantum mechanics analysis of two capacitor materials, greatly speeding up the process.

Researchers have developed a blueprint for understanding and predicting the properties and behavior of nanoparticles containing multiple elements.

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Scientists have made ultra-thin solar cells from gallium arsenide that are flexible enough to wrap around the average pencil.

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Researchers found that the semiconductor indium nitride (InN)will emit green light if reduced to 1 nanometer-wide wires.