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1.1 |
\section{Additional Information for Model Testing}
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\label{sec:outreach}
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1.3 |
{\bf SOME OF THE NUMBERS BELOW WILL BE UPDATED SHORTLY}
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benhoob |
1.1 |
Other models of new physics in the dilepton final state can be confronted in an approximate way by simple
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benhoob |
1.3 |
generator-level studies that compare the expected number of events in \lumifinal\
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benhoob |
1.1 |
with the upper limits from Section~\ref{sec:limit}.
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The key ingredients of such studies are the kinematic requirements described
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benhoob |
1.3 |
in this note, the lepton efficiencies, and the detector responses for \HT\ and \MET.
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benhoob |
1.1 |
%
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benhoob |
1.4 |
The muon identification efficiency is $\approx 96\%$;
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the electron identification efficiency varies approximately linearly from $\approx$ 60\% at
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$\pt = 10\GeVc$ to 90\% for $\pt > 30\GeVc$.
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benhoob |
1.1 |
%
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The lepton isolation efficiency depends on the lepton momentum, as well as on the jet activity in the
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event.
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benhoob |
1.4 |
In $t\bar{t}$ events, it varies approximately linearly from $\approx X\%$ (muons)
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and $\approx X\%$ (electrons) at $\pt=10\GeVc$ to $\approx X\%$ for $\pt>60\GeVc$.
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In LM1 events, this efficiency is decreased by $\approx X$\% over the whole momentum spectrum.
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Electrons and muons from LM3 events have the same isolation efficiency as in $t\bar{t}$ events
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at low \pt\ and $\approx X$\% efficiency for $\pt>60\GeVc$.
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benhoob |
1.1 |
%
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The average detector responses (the reconstructed quantity divided by the generated quantity)
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benhoob |
1.3 |
for \HT\ and \MET\ are consistent with 1 within the 5\% jet energy scale uncertainty.
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benhoob |
1.4 |
The experimental resolutions on these quantities are 9\% and 12\%, respectively.
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benhoob |
1.1 |
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