BES Highlights

Scientists designed peptide bundles that can be precisely linked to form extremely rigid polymer chains. These chains are much stiffer than other known polymers.

February 3, 2021

Designer Polymers Created from Peptide Bundles Promise Super-Strong Future Materials

Computational design of bundled peptide building blocks that can be precisely linked provides new ways to create customized polymers.

X-ray pulses focused on a liquid jet excite electrons. When the electrons lose energy, a flux of X-rays is released. The original pulse plus the new flux of photons then recirculate, further amplifying the X-rays that can be directed to experiments.

January 19, 2021

A Sharp New Eye to View Atoms and Molecules

A newly designed X-ray oscillator may enable atomic level precision with intense X-ray pulses.

Background: microscopy image of a zinc oxide nanoparticle. Foreground: time-lapsed images as particles merge while moving through a liquid. The lines represent electric fields. Bottom: image of the path particles take before merging.

January 15, 2021

Dynamic Duos: How Particles Attach

A new quantitative understanding of how, at what distance, and in what shape zinc oxide nanoparticles come together while separated by liquid.

A machine learning model incorporates information from a physics simulation to better model and optimize the X-ray pulse energy from a free-electron laser. The model better captures the system response than previous models.

December 23, 2020

Machine Learning Trims Tuning Time for Electron Beam by 65 Percent

Scientists use a machine learning algorithm to reduce tuning time of a dozen instruments at once.

A tiny terahertz laser is the first to reach three key performance goals at once: high power, tight beam, and broad frequency tuning.

December 23, 2020

Tiny Tunable Terahertz Lasers Ready to Fly in Space

A novel terahertz laser achieves the performance goals critical for new applications in sensing and imaging.

An X-ray image taken with a novel X-ray wavefront imager results in high precision measurements of intensity and direction of the X-ray beam.

December 23, 2020

New X-Ray Camera Achieves New Heights of Precision and Accuracy for Better Experiments

An X-ray image taken with a novel X-ray wavefront imager results in high precision measurements of intensity and direction of the X-ray beam.

Center-of-mass velocity flux contour map for the reaction of molecular beans to prepare two types of carbene.

December 15, 2020

New Study Evaluates Role of Carbenes on the Formation of Soot

Research uses directed gas phase preparation of two carbenes, triplet pentadiynylidene and singlet ethynylcyclopropenylidene.

An ultrafast X-ray pulse (magenta) excites a burst of activity (green) at the oxygen site (red) of a nitric oxide molecule. The green arrows represent the excitation and motion of electrons within the molecule.

December 4, 2020

A Swift Kick to Initiate Electronic Motion in Molecules

Observation of impulsive stimulated X-ray Raman scattering with attosecond soft X-ray pulses.

$Two techniques—co-localized electron back scattered diffraction imaging (left) and ultrafast optical microscopy (center and right)—help determine how local structural defects affect fast electron movement within a single microscopic crystal.$

December 4, 2020

Defects Slow the Electron’s Dance

Advanced techniques reveal how defects in nanoscale crystals affect how solar photovoltaics perform.

A terahertz laser pulse (purple) interacts with an electron beam (red) inside a special copper structure to “chirp” the electrons’ energies, causing the tail of the beam to catch up with the head as it drifts toward the target material (blue dots).

November 30, 2020

Laser-Driven “Chirp” Powers High-Resolution Materials Imaging

Harnessing the intensity of a terahertz laser pulse brings the resolution of electron scattering closer to the scale of electron and proton motion.

First
Previous
…
17
18
19
20
21
22
23
24
25
…
Next
Last