Catching hadronic vector boson decays with a finer net

5th June 2018 | By

Figure 1: ATLAS event display showing two electroweak boson candidates with an invariant mass of 5 TeV, the highest observed in the analysis. Energy deposits in the ATLAS calorimeters are shown in green and yellow rectangles. The angular resolution limits the reconstruction of substructure of highly collimated jets. The view in the top left corner shows the higher angular resolution of the first calorimeter layer and the tracker (orange lines), revealing the striking two-prong substructure in the energy flow. (Image: ATLAS Collaboration/CERN)

ATLAS has been collecting increasing amounts of data at a centre-of-mass energy of 13 TeV to unravel some of the big mysteries in physics today. For instance, why is the mass of the Higgs boson so much lighter than one would expect? Why is gravity so weak?

Many theoretical models predict that new physics, which could provide answers to these questions, could manifest itself as yet-undiscovered massive particles. These include massive new particles that would decay to much lighter high-momentum electroweak bosons (W and Z). These in turn decay, and the most common signature would be pairs of highly collimated bundles of particles, known as jets. So far, no evidence of such new particles has been uncovered.

The ability to distinguish jets initiated by decays of W or Z bosons from those initiated by other processes is critical for the success of these searches. While the energy flow from the bosons exhibits a distinct two-prong structure from the two-body decay of the boson, no such feature exists for jets from a single quark or gluon – the latter being the most frequent scattering products when colliding protons.

Figure 2: Comparison between the current and previous limits on the cross section times branching ratio for a hypothetical particle (V') versus its mass. Lower vertical values represent higher sensitivity to new physics. Due to the improvements on the analysis techniques, the current result improves our reach for new physics far beyond what we get from only increasing the size of the data set (middle blue line). (Image: ATLAS Collaboration/CERN)

In the past, ATLAS identified this two-prong structure using its fine-grained calorimeter, which measures the energy of the particles inside jets with good resolution. However, in very energetic jets from decays of particles with masses of multiple TeV, the average separation of these prongs is comparable to the segmentation of the ATLAS calorimeter. This creates confusion within the algorithms responsible for identifying the bosons, limiting our sensitivity to new physics at high masses. In contrast to the calorimeter, the ATLAS inner tracking detector reconstructs charged particles with excellent angular resolution, but it lacks sufficient momentum resolution.

A new ATLAS analysis combines the angular information of charged particles reconstructed by the inner detector with the energy information from the calorimeter. This lets ATLAS physicists eliminate the limitations in identifying very energetic jets from bosons. Similar to increasing the magnification of a microscope, this improvement to the ATLAS event reconstruction software allows it to better resolve the energy flow in very energetic jets. This improved magnification allows physicists to also optimize the analyses techniques.

Making such improvements while collecting more data is necessary to maximize the potential for discovery when exploring new kinematic regimes. This time no new physics was seen, but the technique can be applied to many more searches – and still larger datasets.


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