Summary
The representation of the nucleus as an aggregate of protons and neutrons has been quite successful to describe nuclear properties in the past. However, it is now the time to understand the nuclear structure in terms of quarks and gluons (i.e. the partons). We have known for more than 30 years that the quark distribution deviates by up to 20% from the standard model of nuclear physics. With time, most explanations of this phenomenon have come to fail and this major nuclear effect remains today a mystery, but clearly tells us that a description of the nucleus in which protons and neutrons are not affected by their surrounding medium is incomplete. I propose here to use several recent developments in detection technologies and in hadron physics theory to perform new experiments that will unravel the deeper structure of the atomic nucleus. The first measurement will give the 3D tomography of the nucleus in terms of quarks and gluons. Second, I lay out a strategy to measure transverse momentum dependent parton distribution functions in cold nuclear matter and show how
it can help understand the gluon saturation scale, i.e. the onset of non linear behavior in the nuclear gluon structure. Third, I propose to measure reactions, in which we detect nuclear remnants, to link the nucleon and quark dynamics of the nucleus together. The proposed measurements necessitate the development of a dedicated nuclear low energy recoil tracker (ALERT), that I propose to develop and build in the IPN Orsay laboratory at the Paris-Saclay University (France). This detector will be used at the recently upgraded electron accelerator of Jefferson Lab (USA). This facility offers a unique setup with the most intense multi-GeV electron beam in the world. Together, these three unique measurements form a comprehensive program to decisively advance our understanding of the nuclear structure in terms of quarks and gluons.
it can help understand the gluon saturation scale, i.e. the onset of non linear behavior in the nuclear gluon structure. Third, I propose to measure reactions, in which we detect nuclear remnants, to link the nucleon and quark dynamics of the nucleus together. The proposed measurements necessitate the development of a dedicated nuclear low energy recoil tracker (ALERT), that I propose to develop and build in the IPN Orsay laboratory at the Paris-Saclay University (France). This detector will be used at the recently upgraded electron accelerator of Jefferson Lab (USA). This facility offers a unique setup with the most intense multi-GeV electron beam in the world. Together, these three unique measurements form a comprehensive program to decisively advance our understanding of the nuclear structure in terms of quarks and gluons.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/804480 |
| Start date: | 01-10-2018 |
| End date: | 30-09-2024 |
| Total budget - Public funding: | 1 405 881,00 Euro - 1 405 881,00 Euro |
Cordis data
Original description
The representation of the nucleus as an aggregate of protons and neutrons has been quite successful to describe nuclear properties in the past. However, it is now the time to understand the nuclear structure in terms of quarks and gluons (i.e. the partons). We have known for more than 30 years that the quark distribution deviates by up to 20% from the standard model of nuclear physics. With time, most explanations of this phenomenon have come to fail and this major nuclear effect remains today a mystery, but clearly tells us that a description of the nucleus in which protons and neutrons are not affected by their surrounding medium is incomplete. I propose here to use several recent developments in detection technologies and in hadron physics theory to perform new experiments that will unravel the deeper structure of the atomic nucleus. The first measurement will give the 3D tomography of the nucleus in terms of quarks and gluons. Second, I lay out a strategy to measure transverse momentum dependent parton distribution functions in cold nuclear matter and show howit can help understand the gluon saturation scale, i.e. the onset of non linear behavior in the nuclear gluon structure. Third, I propose to measure reactions, in which we detect nuclear remnants, to link the nucleon and quark dynamics of the nucleus together. The proposed measurements necessitate the development of a dedicated nuclear low energy recoil tracker (ALERT), that I propose to develop and build in the IPN Orsay laboratory at the Paris-Saclay University (France). This detector will be used at the recently upgraded electron accelerator of Jefferson Lab (USA). This facility offers a unique setup with the most intense multi-GeV electron beam in the world. Together, these three unique measurements form a comprehensive program to decisively advance our understanding of the nuclear structure in terms of quarks and gluons.
Status
SIGNEDCall topic
ERC-2018-STGUpdate Date
27-04-2024
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