QGT Topical Collaboration Meeting

Sep 19, 2025, 8:00 AM → Sep 20, 2025, 5:00 PM US/Central

Physics Division Auditorium (Argonne National Laboratory)

The 2025 meeting of the Quark-Gluon Tomography collaboration will be hosted at Argonne National Laboratory from September 19 to 20, 2025.

The meeting will be hybrid. Remote participants can join via Zoom.

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The majority of the visible matter in the universe is built from protons and neutrons, and the nuclei they compose. The proton and neutron are not elementary particles but are themselves composed of fundamental particles called quarks and gluons. Understanding how quarks and gluons build the visible universe is one of the grand challenges of modern science. Over the last several decades, tremendous progress has been made in mapping one-dimensional projections of the quarks and gluons inside protons and neutrons. However, to address this grand challenge, a three-dimensional mapping of the motion and spatial location of these quarks and gluons inside protons and neutrons is needed. This endeavor can help address essential questions that currently remain unanswered: How do the spin and orbital degrees of freedom of quarks and gluons within the nucleon combine to make up its total spin? What is the origin of the mass of the nucleon and other hadrons? Do gravitational form factors inform us about the origin of mass, and can they be extracted from measurements? Where are the quarks and gluons located within the nucleon? How does the quark-gluon structure of the nucleon change when it is bound in the nucleus? All these urgent questions are stimulating considerable theoretical and experimental investigations, and major facilities have been and will be built to explore them.

It is now well established that the three-dimensional generalized parton distributions (GPDs) of quarks and gluons hold the key to answering many of these questions. GPDs detail how the quarks and gluons respond to probes that change the nucleon’s momentum and hold the key to understanding many aspects of quark and gluon dynamics. Extracting GPDs from experimental measurements is one of the major research areas in various hadron physics facilities, including HERMES and COMPASS in Europe, and Jefferson Lab in the US. With ongoing experimental efforts at the 12 GeV upgrade of Jefferson Lab and endeavors at a forthcoming Electron-Ion Collider (EIC), it is critical to build the theoretical framework to interpret this experimental data. It is, therefore, timely to organize a theoretical topical collaboration focusing on proton, neutron, and nuclear GPDs.

To achieve this, we have established the Quark-Gluon Tomography (QGT) Collaboration to address the “3D quark-gluon structure of hadrons: mass, spin, and tomography.” This collaboration has three pillars – theory, lattice QCD, and phenomenology – which will develop a strong synergy between them and thereby deliver new insights into the grand challenge questions outlined above.

Fri, September 19

Welcome and opening remarks

Session A

1 Extraction of GPDs from available DVCS data

Speaker: Eric Moffat (Argonne National Laboratory)

2 Progress on GPD global analysis with GUMP

Speaker: Yuxun Guo (Lawrence Berkeley National Laboratory)

3 Extracting x-Dependent GPDs with Normalizing Flow

Speaker: Zhite Yu (Jefferson Lab)

4 Nucleon PDFs from Boosted Correlations in the Coulomb Gauge

Speaker: Jinchen He

Coffee Break

Session B

5 Impact Study of Dihadron Production Processes at JLab and the EIC

Speaker: Yorgo Sawaya

6 Four-point function calculations and applications

Speaker: Christian Zimmermann

7 Quark and Gluon GPD Global Analysis with DVCS and DVMP at NLO

Speaker: Fatma Aslan

8 Tensor Twist-3 GPDs from Lattice QCD

Speaker: Joshua Miller

12:20 PM Lunch Break

Session C

9 Gravitational form factors from Gradient-Flow-Based Renormalization of the QCD EMT

Speaker: Xiang Gao

10 Accessing the Nucleon Gluon Momentum Fraction using the Gradient Flow

Speaker: Alexandru Sturzu

11 Mass and Trace Anomaly Form Factors from Lattice QCD

Speaker: Bigeng Wang

12 The Relation of the Non-Local Vector Current and the Trace Anomaly

Speaker: Ignacio Castelli

13 Down With the Breit-Frame Interpretation of Nucleon Form Factors

Speaker: Gerald Miller

Coffee Break

Session D

14 Energy and momentum densities

Speaker: Adam Freese

15 Perturbative Accuracy for Calculating Parton Distributions under Large Momentum Effective Theory

Speaker: Yushan Su (University of Maryland)

16 String-based approach to GPDs

Speaker: Ismail Zahed

17 Tensor network simulations of quasi-GPDs in the Schwinger model

Speaker: Jake Montgomery (Stony Brook University)

18 QGT Database

Speaker: Marjorie Romero

Business Meeting

6:30 PM Dinner

Sat, September 20

Session E

19 Relativistic corrections to exclusive photoproduction of quarkonia near threshold

Speaker: Sarah Blask

20 Photoproduction of heavy meson near threshold: QCD vacuum perspective

Speaker: Wei-Yang Liu

21 TMD quark distribution factorization at small-x

Speaker: Marcos Morales

Coffee Break

Session F

22 Baryon transition GPDs

Speaker: Christian Weiss

23 Pions and Kaons in the Covariant Parton Model

Speaker: Thomas Tarutin

24 D(t) form factor of the nucleon, electric forces, and the comparison to Lattice QCD

Speaker: Andrea Mejia

25 Diquark Currents and Form Factors in the NJL Model

Speaker: Brean Maynard

Closing remarks