Science Highlights

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.

Selective etching of palladium (blue) from palladium-platinum core-shell nanoparticles (left) yields hollow platinum (grey) nanocages with high activity for the oxygen reduction reaction.

Hollow and Filled with Potential

Hollow shape-selected platinum nanocages represent a new class of highly active catalysts.

MD simulation shows membranes with an asymmetric molecular distribution of about 0.6 nm; yellow = gold; red = organo-thiol ligand molecules.

Janus-like Nanoparticle Membranes

Sub-nanometer molecular asymmetry between the two different faces of nanoparticle membranes formed at air-water interface is revealed.

What Is the Size of the Atomic Nucleus?

The neutron skin of the nucleus calcium-48 is much thinner than previously thought.

Researchers from the Molecular Foundry, working with users from Columbia University led by Latha Venkataraman, have created the world’s highest-performance single-molecule diode using a combination of gold electrodes and an ionic solution.

Viable Single-Molecule Diodes

Major milestone in molecular electronics scored by Molecular Foundry and Columbia University team.

Visualized model of a superlubricity (low-friction) system: gold = nanodiamond particles; red = graphene nanoscroll; green = underlying graphene on silica; black = diamond-like carbon surface.

Near Zero Friction from Nanoscale Lubricants

Researchers have attained superlubricity, the near absence of friction, at a carbon-silica interface using nanodiamonds wrapped in graphene flakes.

Understanding the conditions and pathways that position populations of isolated ions and shared proton species as they react in water allows scientists to better understand the chemistry of concentrated hydrogen chloride solutions, which has implications in chemical processes ranging from refining oil to building longer-lasting batteries

Keeping the Ions Close: A New Activity

Study changes perception on how acids behave in water.

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