Master student Projects
Projects for Master students in the Nikhef B-physics (LHCb) group
date: May 2014
This is an overview with all available Master student projects in the Nikhef B-physics (LHCb) group.
If you have your own research proposal, need more detailed information on the
(availability) of individual proposals or would like to discuss about other available
projects in the group you are always welcome to contact
either the contact person for the project and/or the Nikhef B-physics group leader:
Marcel Merk [e-mail: i93_at_nikhef.nl, Tel 020-5925107, Nikhef room N2xx]
For an overview of the theses written in the Nikhef B-physics group you can look at the Nikhef LHCb theses page
Master projects in the Nikhef B-physics group
| 1) Study of long-living particles |
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Supervisors: Wouter Hulsbergen (staf) and Veerle Heijne (PhD)
Research description:
Supersymmetry is potentially the key to understand the Dark Matter in the Universe. Within the SUSY framework, long-living supersymmetric particles can exist, which can be detected by the LHCb detector. The search for these particles will be performed on the recent data set recorded in 2012, and some work is also needed on the trigger selection, to prepare for data taking in 2015, when the LHC will be running at a higher center-of-mass energy.
For this project computer skills are needed. The ROOT programme and C++ and/or Python macros are used. You become part of our research group (~5 persons); we have weekly video meetings with colleagues at CERN.
Relevant information:
Master thesis Suzanne Klaver (2013): A Search for Long-lived Neutralinos in LHCb
| 2) Searching for Lorentz Invariance Violation with Bs -> J/psi phi decays |
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Supervisors: Gerhard Raven (staf), Jeroen van Tilburg (Postdoc)
Research description:
The measurement of CP violation occurring in decays of the type Bs-->J/psi phi is a flagship analysis in the LHCb experiment. However, no-one in LHCb has tested whether CPT symmetry is violated. CPT symmetry is tightly connected to the principle of Lorentz invariance. Lorentz invariantz violation would become visible if the decay rate would show any dependency to a fixed direction in space. In this project the CP violation analysis is extended to test for Lorentz Invariance violation.
For this project computer skills are needed. The ROOT programme and C++ and/or Python macros are used. This is a project that is closely related to the larger effort at Nikhef (~5 people) of measuring phi_s with Bs->J/psiPhi decays. Weekly video meetings with CERN coordinate the efforts within the LHCb collaboration.
Relevant information:
Belle Collaboration: arXiv:1203.0930v2, Search for Time-Dependent CPT Violation in Hadronic and Semileptonic B Decays
| 3) Detector Electronics & Data acquisition for the LHCb Scintillating Fiber Tracker |
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Supervisors: Antonio Pellegrino (physicist), Wilco Vink (engineer)
Research description:
The large-acceptance tracker of LHCb will be replaced by a detector with increased rate capabilities during next LHC long shutdown in 2019. The new detector will be based on arrays of scintillating fibers (SciFi) with 0.25 mm diameters, read out by silicon photo-multipliers (SiPMs). The processing of the SiPM signals (the whole detector will consist of 589824 SiPM channels) in the on-detector electronics will proceed in two stages: first an application-specific integrated circuit will amplify and shape the signal and a set of comparators will digitize a two-bits information per channel; then dedicated FPGAs will reduce the data size and suppress noise through a data-clustering algorithm.
The Nikhef group is responsible for this second stage, namely for the implementation of the clusterization algorithm and for the design, production and testing of the on-detector PCBs hosting the FPGAs running the algorithm. This master project would contribute to this R&D, in two main ways. On the one hand, supporting the Nikhef electronics department in the development of the VHDL code for the clusterization FPGA, providing a computer emulation of the algorithm based on C++ code and a test bench capable of processing the same data processed by the FPGA and of comparing the results. On the other, partecipating to the design of an automated test system to diagnose and characterize the SciFi on-detector electronics through the injection of SiPM-like current pulses, in particular writing control software and ROOT software to analyze the test data and diagnose faults.
For this project computing skills are needed (C++ and ROOT); an interest for digital electronics is welcome (with the option of learning the basic of VHDL programming). The student will perform his research in a group consisting of two seniors, one Ph.D. student and an electronics engineer.
Relevant information:
Belle Collaboration: arXiv:1203.0930v2, Search for Time-Dependent CPT Violation in Hadronic and Semileptonic B Decays