Abstract
There are many outstanding problems in nuclear physics which require input and guidance from lattice QCD calculations of few baryons systems. However, these calculations suffer from an exponentially bad signal-to-noise problem which has prevented a controlled extrapolation to the physical point. The variational method has been applied very successfully to two-meson systems, allowing for the extraction of the two-meson states very early in Euclidean time through the use of improved single hadron operators. The sheer numerical cost of using the same techniques in two-baryon systems has so far been prohibitive. We present an alternate strategy which offers some of the same advantages as the variational method while being significantly less numerically expensive. We first use the Matrix Prony method to form an optimal linear combination of single baryon interpolating fields generated from the same source and different sink interpolating fields. Very early in Euclidean time this optimal linear combination is numerically free of excited state contamination, so we coin it a calm baryon. This calm baryon operator is then used in the construction of the two-baryon correlation functions.To test this method, we perform calculations on the WM/JLab iso-clover gauge configurations at the SU(3) flavor symmetric point with mπ∼ 800 MeV - the same configurations we have previously used for the calculation of two-nucleon correlation functions. We observe the calm baryon significantly removes the excited state contamination from the two-nucleon correlation function to as early a time as the single-nucleon is improved, provided non-local (displaced nucleon) sources are used. For the local two-nucleon correlation function (where both nucleons are created from the same space-time location) there is still improvement, but there is significant excited state contamination in the region the single calm baryon displays no excited state contamination.
Original language | English |
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Article number | 05029 |
Journal | EPJ Web of Conferences |
Volume | 175 |
DOIs | |
State | Published - Mar 26 2018 |
Externally published | Yes |
Event | 35th International Symposium on Lattice Field Theory, Lattice 2017 - Granada, Spain Duration: Jun 18 2017 → Jun 24 2017 |
Funding
We thank W. Detmold, R. Edwards, K. Orginos and D. Richards for use of the WM/JLab configurations used for this work. The calculations were performed with Chroma [32] linked against Quda [33, 34] and managed with METAQ [35]. We thank R. Briceno and D. Wilson for useful conversations. E.B. thanks M. Savage for further useful conversations regarding the prior development of similar techniques. Numerical results were made possible through computing at Lawrence Livermore National Laboratory through the Multiprogrammatic and Institutional Computing and Grand Challenge programs, and through an ERCAP allocation at NERSC and an award of the Innovative and Novel Computational Impact on Theory and Experiment (INCITE) program on Titan to CalLat (2016). This work was supported in part by the Department of Energy, Office of Science, the RIKEN Special Postdoctoral Researcher Program and by the DFG and the NSFC Sino-German CRC110.
Funders | Funder number |
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U.S. Department of Energy | |
Office of Science | |
Deutsche Forschungsgemeinschaft | |
National Natural Science Foundation of China | |
RIKEN |