Science Highlights | U.S. DOE Office of Science (SC)

To make element 116, researchers fused isotopes of titanium and plutonium.

New Progress Toward the Discovery of New Elements

Scientists demonstrated a new way to produce the superheavy element livermorium (element 116) with titanium-50.

The dynamics of coupled oscillators, such as those shown here, can be simulated faster with a new quantum algorithm.

Springing Simulations Forward with Quantum Computing

A new quantum algorithm speeds up simulations of coupled oscillators dynamics.

Conversion of CO2 to butene via a solar-driven tandem process. First, CO2 is converted to ethylene using an electrochemical reactor and solar-derived electricity. Next, ethylene is converted to butene via thermal catalysis with heat from solar irradiation.

Driving Chemical Transformations Through the Power of Solar Energy

Researchers combine solar energy, electrochemistry, and thermal catalysis to remove the need for fossil fuel-driven chemical conversions.

A long-predicted ultrafast isomerization in the UV photochemistry of bromoform is visualized for the first time by femtosecond time-resolved electron diffraction. At 267 nm excitation, the reaction pathway surpasses direct dissociation by a 60:40 margin.

Bromoform Molecules Like to Rearrange Their Atoms

Ultrafast electron diffraction imaging reveals atomic rearrangements long suspected to be crucial in the photochemistry of bromoform.

Infrared Quantum Ghost Imaging Illuminates—But Doesn’t Disturb—Living Plants

Quantum ghost imaging of live plants at light levels lower than starlight gives new perspectives on plant processes.

Artist’s depiction of a proton’s interior. In quantum chromodynamics, the constituent quarks come in three “colors,” along with up and down “flavors.” Also shown are virtual quark-antiquark pairs and the gluons that bind the quarks together.

New Approach Merges Theoretical Fundamentals with Experimental Studies of the Proton’s Structure

A new approach to applying quantum chromodynamics paves the way for a deeper understanding of the strong nuclear interaction.

(a) Architecture of real-time field control on the DIII-D and KSTAR tokamaks. (b) This real-time 3D control drives plasma to the highest performance state for normalized fusion gain (energy out vs energy in, <em>G</em>) and confinement quality (<em>H</em><sub>89</sub>) without edge bursts.

Controller with Integrated Machine Learning Tweaks Fusion Plasmas in Real Time

Integrating machine learning with real-time adaptive control produces high-performance plasmas without edge instabilities, a key for future fusion reactors.

The Belle II experiment at the SuperKEKB accelerator measures particle interactions with extreme precision. Collisions of electron and positron beams create the high-energy environment needed to produce subatomic particles that do not otherwise exist in nature.

Belle II Detector Produces World’s Most Precise Measurements of Subatomic Particle Lifetimes

Particle lifetime measurements with early data from the Belle II experiment at the SuperKEKB accelerator demonstrate the experiment’s high precision.

(a) Fiber spools used for realizing a telescoping suite of fiber connections. (b) entanglement throughput measurements and corresponding capacity estimates by light measurements on a Polatis all-optical switch and at the source and detector.

Scientists Compare Throughput for Quantum vs. Conventional Networks

A comparison of throughput measurements and analytical capacity estimates for quantum networks finds surprising patterns.

Evolution paths of the single control qubit on the Bloch sphere in the hybrid approach to Grover’s algorithm.

Novel Hardware Approach Produces a New Quantum Computing Paradigm

New theoretical approach to quantum computing hardware design via an algorithm avoids some of the complex difficulties in modern quantum computers.

A neutrino moves through a gas of neutrons and is sensitive to correlations in spin and density in the neutron matter. These correlations determine how much energy transfers from the neutrino to the neutrons.

Improved Spin and Density Correlation Simulations Give Researchers Clearer Insights on Neutron Stars

New lattice simulations compute the spin and density correlations in neutron matter that affect neutrino heating during core-collapse supernovae.

Graphic showing the transverse motion of a quark (green sphere) inside a proton whose spin is aligned to its direction of motion (large yellow arrow).

Calculation Sharpens Imaging of Protons’ Insides

New theory-based approach gives access to quarks’ tiny transverse motion within protons.