'Shining' light on the inner details and breakup of deuterons
Photon-deuteron collisions offer insight into the gluons that bind the building blocks of matter—and what it takes to break protons and neutrons apart.
image: In ultra-peripheral collisions between gold (Au) ions and deuterons (d), photons (γ) surrounding the fast-moving ions interact with gluons (yellow coils) to reveal their distribution within the deuteron. view more
Credit: Image courtesy of Brookhaven National Laboratory
DOE/US DEPARTMENT OF ENERGY
The Science
Scientists have found a way to “see” inside deuterons, the simplest atomic nuclei, to better understand the “glue” that holds the building blocks of matter together. The new results come from collisions of photons (particles of light) with deuterons, which are made of just one proton bound to one neutron. In these collisions, the photons act like an X-ray beam to provide the first glimpse of how particles called gluons are arranged within the deuteron. These collisions can also break the deuteron apart, giving insights into what holds the proton and neutron together.
The Impact
By studying the deuteron, the simplest nucleus in nature, scientists gain an understanding of the more complex atomic nuclei that make up essentially all visible matter in the universe. This research on deuterons helps explain how nuclei emerge from quarks and gluons, and how the masses of nuclei are dynamically generated by gluons. Deuterons also play an important role in the energy production inside the sun, which starts with two protons fusing into a deuteron. Studying deuterons may help scientists better understand fusion reactions. This could lead to strategies for harnessing fusion power to make electricity on Earth.
Summary
In this work, scientists from the STAR Collaboration looked at existing data from deuteron-gold collisions at the Relativistic Heavy Ion Collider (RHIC), a Department of Energy (DOE) user facility. At RHIC, researchers can use photons surrounding fast-moving gold ions to examine the role of gluons. By studying gluon dynamics in the deuteron, the simplest atomic nucleus, scientists gain understanding of how the distribution and behavior of gluons, as force-carrier particles, change as nuclei become more complex. In the RHIC collisions studied in this work, scientists used the STAR detector to track how much momentum was transferred from gluons within the deuteron to particles created in these interactions. Since that momentum transfer relates to where the gluons are located inside the nucleus, the scientists used the data to map out the gluon distribution in the deuteron. In addition, each photon-gluon interaction also deflects the deuteron—and sometimes breaks it apart. STAR tracked “spectator neutrons” that came from this breakup to learn more about how gluons hold these nuclei together.
Understanding the role of gluons in nuclear matter will be a focus of the Electron-Ion Collider (EIC), a new facility that is in the planning stages at Brookhaven National Laboratory. EIC will use photons generated by electrons to probe gluon distributions inside protons and nuclei, and to study the force that holds protons and neutrons together to make up nuclei.
Funding
Brookhaven Lab’s role in this work and RHIC operations are funded by the Department of Energy Office of Science, Nuclear Physics program. Additional funding came from the U.S. National Science Foundation and a range of international funding agencies.
Credit: Image courtesy of Brookhaven National Laboratory
DOE/US DEPARTMENT OF ENERGY
The Science
Scientists have found a way to “see” inside deuterons, the simplest atomic nuclei, to better understand the “glue” that holds the building blocks of matter together. The new results come from collisions of photons (particles of light) with deuterons, which are made of just one proton bound to one neutron. In these collisions, the photons act like an X-ray beam to provide the first glimpse of how particles called gluons are arranged within the deuteron. These collisions can also break the deuteron apart, giving insights into what holds the proton and neutron together.
The Impact
By studying the deuteron, the simplest nucleus in nature, scientists gain an understanding of the more complex atomic nuclei that make up essentially all visible matter in the universe. This research on deuterons helps explain how nuclei emerge from quarks and gluons, and how the masses of nuclei are dynamically generated by gluons. Deuterons also play an important role in the energy production inside the sun, which starts with two protons fusing into a deuteron. Studying deuterons may help scientists better understand fusion reactions. This could lead to strategies for harnessing fusion power to make electricity on Earth.
Summary
In this work, scientists from the STAR Collaboration looked at existing data from deuteron-gold collisions at the Relativistic Heavy Ion Collider (RHIC), a Department of Energy (DOE) user facility. At RHIC, researchers can use photons surrounding fast-moving gold ions to examine the role of gluons. By studying gluon dynamics in the deuteron, the simplest atomic nucleus, scientists gain understanding of how the distribution and behavior of gluons, as force-carrier particles, change as nuclei become more complex. In the RHIC collisions studied in this work, scientists used the STAR detector to track how much momentum was transferred from gluons within the deuteron to particles created in these interactions. Since that momentum transfer relates to where the gluons are located inside the nucleus, the scientists used the data to map out the gluon distribution in the deuteron. In addition, each photon-gluon interaction also deflects the deuteron—and sometimes breaks it apart. STAR tracked “spectator neutrons” that came from this breakup to learn more about how gluons hold these nuclei together.
Understanding the role of gluons in nuclear matter will be a focus of the Electron-Ion Collider (EIC), a new facility that is in the planning stages at Brookhaven National Laboratory. EIC will use photons generated by electrons to probe gluon distributions inside protons and nuclei, and to study the force that holds protons and neutrons together to make up nuclei.
Funding
Brookhaven Lab’s role in this work and RHIC operations are funded by the Department of Energy Office of Science, Nuclear Physics program. Additional funding came from the U.S. National Science Foundation and a range of international funding agencies.
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