Los Alamos National Laboratory

Los Alamos National Laboratory

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Theoretical Physics Quarterly Progress Reports

Investigating the field of high energy physics through experiments that strengthen our fundamental understanding of matter, energy, space, and time.

Los Alamos HEP Theory Quarterly Report FY2018-Q4

Daniele Alves, Tanmoy Bhattacharya, Michael L. Graesser, Rajan Gupta

The primary areas of activity of the theory group are in physics beyond the Standard Model, cosmology, dark matter, lattice quantum chromodynamics, neutrinos, the fundamentals of quantum field theory and gravity, and particle astrophysics. The questions pursued by this group relate to deep mysteries in our understanding of Nature at the level of the the Standard Model and beyond. The main tools we use are quantum field theory and General Relativity.

Lattice QCD

The Los Alamos Lattice QCD team and their collaborators are carrying out precision studies investigating signatures of new physics at the TeV scale, Novel CP violating operator's contribution to nEDM, elucidating the structure of the nucleon, and neutrino-nucleon interactions. Progress during this quarter on these projects is described below. The team is also actively working on Quantum Information and Computing under the DOE call "Quantum Information Science Enabled Discovery For High Energy Physics".

Nucleon charges and form-factors

The analysis of isovector charges gA, gS and gT from the 2+1+1-flavor clover-on-HISQ calculations was completed and a paper describing the results was prepared and published in PRD. The final analysis of flavor diagonal axial and tensor charges was completed. A paper describing the contribution of quark spin to the proton spin was prepared and submitted for publication. A second paper describing the calculation of the flavor diagonal tensor charges was completed and submitted for publication. The analysis of electric, magnetic and axial vector form factors using up to 3-state fits for both the 2+1+1-flavor clover-on-HISQ and 2+1-flavor clover on clover lattice QCD formulations was carried out and manuscripts describing the results were worked on. Results were presented by Rajan Gupta and Yong-Chull Jang at Lattice 2018.

Relevant References:
arXiv:1808.07597
arXiv:1806.10604
Physical Review D98 (2018) 034503 arXiv:1806.09006
arXiv:1806.10604
Physical Review D96 (2017) 114503 arXiv:1705.06834
Physical Review D95:5 (2017) 074508
Physical Review D94:5 (2016) 054508
Physical Review D93:11 (2016) 114506
arXiv:1601.01730
Physical Review D92:9 (2015) 094511
Physical Review D89:9 (2014) 094502
Physical Review D85:5 (2012) 054512.

Matrix elements of novel CP violating operators and nEDM

Calculations of the matrix elements of the quark chromo electric dipole moment operator (cEDM) and mixing with the pseudoscalar operator are ongoing. Investigations of gradient flow method to deal with the divergent renormalization and mixing problem of the cEDM operator are continuing. Analysis of data generated so far was carried out and results presented at Lattice 2018 by Tanmoy Bhattacharya.

Relevant References:
arXiv:1712.08557
arXiv:1701.04132
arXiv:1612.08438
arXiv:1601.02264
Physical Review D92:9 (2015) 114026
Physical Review Letters 112:21 (2015) 212002
arXiv:1502.07325
arXiv:1403.2445
arXiv:1212.4918

Contributions from Disconnected diagrams

The matrix elements of flavor diagonal operators are needed for the analysis of a number of interesting qualities such as the nucleon electric dipole moment, the quark contribution to the nucleon spin, the nucleon sigma term and the strangeness content of the proton, and the interaction of dark matter with nucleons. These matrix elements also get contributions from disconnected diagrams, that are computationally challenging to compute with high precision. Bhattacharya, Gupta and Yoon submitted two manuscript describing the results of extensive simulations carried out over the last three years for publication. These analyses included chiral and continuum extrapolation for the disconnected contribution of the flavor diagonal charges for the first time.

Relevant References:
arXiv:1808.07597
arXiv:1806.10604
arXiv:1611.01193

Transverse Momentum Distribution Functions

New simulations, in collaboration with the Regensburg group, are being done.

Relevant References:
Physical Review D96 (2017) 094508 arXiv:1706.03406
arXiv:1611.01193
arXiv:1601.05717

Dark Matter and LHC Physics

Graesser and University of New Mexico graduate student Jacek Osinski explored topological dark matter, in the form of hidden sector magnetic monopoles, produced in the early Universe during a second order phase transition. They generalized results in the prior literature by considering the impact of a non-standard cosmological history on the relic abundance of the monopoles. They found a monopole mass of order (1-100) PeV to be generic for the cosmological histories they considered, if monopoles are to entirely reproduce the current abundance of dark matter. Their results verify the robustness of the O(PeV) scale for the monopole mass that is needed if the early Universe is radiation-dominated around the time of production. A draft is in preparation.

Relevant References:
Physics Letters B749 (2014) 293
arXiv:1311.2028
Physical Review Letters111 (2013) 121802
JHEP 1302(2013) 046
JHEP 1210(2012) 025
Physics Letters B714 (2012) 267
Physics Review D85 (2012) 054512
arXiv:1107.2666
JHEP 1110(2011) 110

Michael Graesser: Neutrinoless double beta decay

Graesser, in collaboration with V. Cirigliano, W. Dekens, J. de Vries, and E. Mereghetti, developed an effective field theory for lepton number violation (LNV) by 2 units, covering the large class of theories in which LNV mediators lie above the GeV scale. The new master formula for 0νββ decay supersedes all previous “master formulas” since it uses a minimal basis of operators and correct QCD RG equations; performs careful and systematic matching of quark operators onto the chiral theory of pions and nucleons; identifies all the needed LECs and includes their values where they are known; includes the leading effect dimension-5, dimension-7, and dimension-9 operators — including their interference terms — and includes non-perturbative renormalization of contact operators, a feature completely missed by all previous analyses. The team applied their master formula to obtain constraints on single LNV operators, and a number of benchmark points for the left-right symmetric model. For instance, in a particular bench mark set of mass parameters (mWR ~ 4.5 TeV, mνRi=1,2,3 ~ 10 GeV) – consistent with current LHC limits – they found that the induced dim-9 operators dominate over the active Majorana neutrino mass contributions and that this benchmark point is excluded by existing 0νββ decay limits, demonstrating the complementarily between LHC searches for LNV and neutrinoless double beta decay experiments. This work appeared as arXiv:1806.02780 and was submitted to JHEP.

Relevant References:
arXiv:1806.02780
Physical Review Letters 120:20 (2018) 202001 arXiv:1802.10097
Journal of High Energy Physics12 (2017) 82 arXiv:1708.09390
Journal of High Energy Physics (2017)99
Physics Letters B769 (2017) 460

Daniel S. M. Alves

During the past quarter, Daniele Alves has made progress on two projects: (1) models of sterile neutrinos with BSM interactions with matter via light mediators, specifically, on how these models are constrained by solar neutrinos, and how they could potentially address the distortion of the 8B solar neutrino spectrum, if confirmed; (2) generalizing Tensor Networks and Entanglement Renormalization to continuous effective field theories, specifically, using the Sine-Gordon/Thirring model as a testing ground for these methods.

Relevant References:
Journal of High Energy Physics 07 (2018) 92 arXiv:1710.03764