68 The MINOS Experiment Absolute Track and Shower Energy

Once the detectors are all calibrated to give the same hit-to-hit response, the overall response to physics objects needs to be evaluated. These absolute track and shower energy scales were determined by measurements with CalDet while it was exposed to various test beams at CERN. Data was taken with electrons, pions, muons, and protons of both charge signs with momenta ranging from 200 MeV to 10 GeV, with other detectors in the beamline to identify the particles. Thus, the particle species¹³, charge, and momenta were all known a priori before the event was observed in the detector. The data were then compared to the GEANT3 detector simulation.

The predicted range of stopping muons was modeled to better than 3%, thus benchmarking the accuracy of the GEANT3 simulation and the GEANT3 swimmer used to reconstruct track energies. The detector response to electrons agreed to better than 2%. The response to pion and proton showers guided the choice of hadronic interaction model for the detector (GCALOR [134]) and showed that the Monte Carlo could reproduce the measured hadronic showers to better than 6% at all energies. The reconstruction of track and shower energy is discussed in greater detail in Section 3.4.

X (m)

-4 -3 -2 -1 0 1 2 3

Y (m)

-3 -2 -1 0 1 2 3

µsec) Hit Time (

0 1 2 3 4 5 6 7 8 9 10

secµHit Photoelectrons / 0.2

0 200 400 600 800 1000

Figure 3.15: One beam spill as observed in the Near Detector. For clarity a spill containing a smaller than average number of neutrino interactions was chosen. The left plot shows the horizontal and vertical position of track hits. The right plot shows the detector signal as a function of time, where the bin width is about ten times larger than the detector’s timing resolution. Image obtained from [83].

pulse-height hits observed in the data whose exact origin remains unknown. The solution is to remove most crosstalk hits by applying a pulse-height cut to the selection.

3.4.3 MINOS Reconstruction

Before being analyzed, both the data and the simulation are processed through the MINOS event reconstruction. The reconstruction is a C++ based framework whose goal is to estimate the visible energy of the different neutrino interactions and to provide a distinct set of quantities that describe each event. The input to the reconstruction is the digitized readout recorded during a beam spill or during a cosmic ray event. This information is referred to as a “snarl.”

A snarl can contain multiple events, especially if it is a Near Detector snarl. The first step in the reconstruction is to divide the activity in the detector into one or more events.

Figure 3.15 shows the example of a beam spill as observed in the Near Detector. Hits from a single interaction are identified using timing and spatial information. In the Far Detector the rate is much lower, and there is rarely more than one event per beam spill.

A track-finding algorithm is then applied to each event. The algorithm operates by finding small track-like segments and then, when possible, joining them to form a “seed track.” The seed track is then iteratively passed through a Kalman filter, which relies on Figure 3.22: An example of a Near Detector snarl with several neutrino event distributed in space (left) and time (right). Figure taken from [135].

neutral currents in the MINOS detectors. As described in Section 2.2.4, CCνµ and CC¯νµ events are characterized by long, curving muon tracks (µ⁺ for ¯νµ and µ⁻ for νµ) with a hadronic shower at the interaction vertex. CCνµ and CC¯νµ events can be distinguished by the direction the track curves in the detector magnetic field. While running with neutrino-mode beam, both detector fields are typically tuned to bendµ⁻ inwards andµ⁺ outwards, and vice versa during antineutrino-mode beam. The detector fields are chosen this way because tracks bent inwards are less likely to exit the detector, allowing the more accurate range momentum measurement to be used.

CCνeand NC interactions produce events without muon tracks, though they sometimes still have short reconstructed tracks. CCνeevents are characterized by compact electromagnetic showers and NC events are characterized by more diffuse hadronic showers, but distinguishing between them is not necessary for either antineutrino analysis. Specific analyses have been performed for both the CCνesample [136] and the NC sample [137], but in the analyses presented in this thesis the events without muon tracks are background. Given the predominance of NC events, the CCνeevents are wrapped into the NC sample. Figure 3.23 shows event displays from a CCνµ, a CC¯νµ, and an NC interaction.

3.4.2 Tracks

Once the snarl has been split up into events, a track finder searches for small track-like segments – several hits in an approximate line across several planes. The track finder then joins these segments together to produce a ‘seed track.’ The seed track is then fit using a multi-pass Kalman filter [138].

The filter moves forwards and backwards along the track, attempting to estimate the state (e.g.

momentum) of the underlying muon at each point along the track, including the effects of noise and multiple scattering in addition to the expected curvature in the magnetic field. It makes the final decision on whether or not a particular hit is part of the track.

70 The MINOS Experiment

+

ν_µ CC Event ν_µ CC Event NC Event

Coil Coil

µ

^-

µ

⁺

Simulated Events

ν

Figure 3.23: The three event topologies relevant to the antineutrino analysis: CCνµ(left), CC¯νµ (center), and NC (right). The top row shows the Feynman diagram and the bottom row shows a representative simulated event in one view (i.e. only U planes). CC events are characterized by long muon tracks which curve in opposite directions for CCνµ and CC¯νµ. NC events do not have true muon tracks, but can have fake tracks which make them a background at low energy. The green points are hits with light levels below two photo-electrons and are not included in the analysis.

After two passes with the filter, the fitted momentum state (or more precisely, charge-to- momentum ratio) of the particle’s first hit is curvature-based estimate of the track’s initial mo- mentum when created in the detector. Other properties of the track fitting, for example how well the track’s curvature (momentum) was measured, are also recorded. The curvature of the track is proportional to the ratio of its charge to its momentum, q/p. At 3 GeV the resolution of this measurement is 11%.

If the track ends in the detector, a second, more accurate measurement of the momentum is made using the range of the track through the plastic and steel. At 3 GeV, the momentum measurement by range has a resolution of 4.6%. It is used for all tracks that do not exit the detector or end in the uninstrumented coil hole. Muons with energies between 10 MeV and 10 GeV lose energy almost exclusively through ionization (see Figure 27.1 on page 286 in [35]) and are well described by the Bethe-Bloch equation [35, 139]. This is precisely the energy regime relevant to oscillations in MINOS. In practice, the energy is measured by swimming a muon backwards along the track using the GEANT3 simulation package [140] and progressively adding back in the energy that would have been lost in each steel and scintillator plane.

CalDet confirmed the accuracy of the Bethe-Bloch equation as tabulated by Groom [139] with

material-specific density effects tabulated by Sternheimer [141, 142]. Modifying the GEANT3 sim- ulation to use the Groom tabulation produced data-MC agreement at better than 2% [131, 143].

The remaining 2% is taken as a systematic uncertainty in the analysis. Since 95% of the energy loss occurs in the steel planes, each of which is nominally 1.46 radiation lengths thick, the amount of steel the muon passes through must also be known precisely. The density of the steel was measured to an accuracy of 0.3% and the Near and Far Detector plane thicknesses were measured to 0.1%¹⁴ and 0.2%¹⁵respectively.

The curvature-based measurement of the track momentum was calibrated by comparison with the range-based measurement. The two energy measurements were compared for stopping tracks, and it was found that the curvature-based measurement generally agreed with the range-based measurement to within 1%. This 1% is conservatively added linearly to the 2% uncertainty from the range measurement, leading to a total uncertainty of 3%.

3.4.3 Showers

Once the tracks have been identified, the remaining hits in proximity to one another are grouped together into showers. Hits that are part of a track, but with more energy than the muon would have deposited, have the track portion of the energy subtracted before being included in a shower. Unlike the muon, whose energy is measured topologically, the shower energy is measured calorimetrically.

The MINOS detectors are too coarse (each ‘pixel’ is 4 cm across and separated longitudinally by 5 cm of steel and air) to reliably distinguish the component particles in the shower. Instead, the energy of the shower is reconstructed calorimetrically: it is estimated based on the total energy deposited by all of its constituent hits.

The absolute shower energy scale is also calibrated using the test beams at the calibration detector. This detector provided the opportunity to measure the detector response to hadronic particles of known energy. The electron shower data agreed with the GEANT3 simulation to less than 2%. The hadronic shower measurements showed data-MC agreement of 6% and helped guide the choice of GCALOR [134] as the hadronic interaction model in the simulation.

The hadronic and electromagnetic shower energy resolutions can be adequately modeled by the simulation, and they are parameterized as 56%/√

E⊕2% for hadrons and 21.4%/√

E⊕4% for electrons, whereE is the particle’s energy in GeV.

14Measured by ultrasound

15Measured by weight

72 The MINOS Experiment