Science Highlights

Graphene Rewrites the Rules of Engagement

Graphene Rewrites the Rules of Engagement

Novel self-assembly can tune the electronic properties of graphene, possibly opening doors for tiny, powerful electronic devices.

Super-ion-Building-Blocks-lrg

It's a Bird, It's a Plane, It's Super-ion Building Blocks

Materials based on clusters of atoms called “super-ions” may revolutionize the whole solar cell industry.

LED Lighting May Now Shine Brighter

Scientists apprehended the atomic-scale, microscopic mechanism that limits light emission in LED lighting.

Closing the Loop: Ionic Liquids from Biomass Waste Could Pretreat Plants Destined for Biofuels

Recycling waste from biofuel production could lower cost for future biorefineries.

Water Gunks Up Biofuels Production from Bio-Oils

New findings will help extend the lifetime of catalysts used to process bio-oils in liquid systems.

A snapshot from a large quantum molecular dynamics simulation of the production of hydrogen molecules (green) from an aluminum-lithium alloy nanoparticle containing 16,661 atoms (represented by the silver contour of charge density) and dissolved charged lithium atoms (red).

Towards Eco-friendly Industrial-Scale Hydrogen Production

Atomic-scale simulations predict how to use nanoparticles to increase hydrogen production.

Absorption of sunlight in silicon solar cells results in losses due to heat from “hot” photo-excited electrons.

Taking on the Heat in Solar Cells: New Calculations Show Atomic Vibrations Hurt Efficiency

Theoretical modeling of energy loss in solar cells may lead to more efficient materials to convert sunlight to electricity.

The crystallized oxide (lighter regions) spelling the word “small” was “printed” on a non-crystallized layer (darker gray) by a well-controlled beam in an electron microscope.

Atomic Sculpting with a Microscope

A new tool allows atomic 3D printing.

Confined in droplets, exotic phases of liquid crystals have been simulated (left) and experimentally observed (right).

Tiny Droplets… Lead to Exotic Properties

Chameleon-like color changes are observed by confining liquid crystals within small drops.

Snakes on a plane: This atomic-resolution simulation of a peptoid nanosheet reveals a snake-like structure never seen before. The nanosheet’s layers include a water-repelling core (yellow), peptoid backbones (white), and charged sidechains (magenta and cyan). The right corner of the nanosheet’s top layer has been “removed” to show how the backbone’s alternating rotational states give the backbones a snake-like appearance (red and blue ribbons). Surrounding water molecules are red and white.

Understanding and Predicting Self-Assembly

Newly discovered “design rule” brings nature-inspired nanostructures one step closer.

Supercomputers Predict New Turbulent Interactions in Fusion Plasmas

Cutting-edge simulations provide an explanation for a mystery over half a century old.

The orange carotenoid protein of cyanobacteria binds a single carotenoid pigment molecule that may dissipate excess light energy when it moves within the protein.

Changing Colors for Built-in Sunblock

Molecular movements triggered by light redirect the flow of energy through photosynthetic cells to protect them from sun damage.

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