Solid State Detectors

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Transcription:

Solid State Detectors Most material is taken from lectures by Michael Moll/CERN and Daniela Bortoletto/Purdue and the book Semiconductor Radiation Detectors by Gerhard Lutz. In gaseous detectors, a charged particle is liberating electrons from the atoms, which are freely bouncing between the gas atoms. An applied electric field makes the electrons and ions move, which induces signals on the metal readout electrodes. For individual gas atoms, the electron energy levels are discrete. In solids (crystals), the electron energy levels are in bands. Inner shell electrons, in the lower energy bands, are closely bound to the individual atoms and always stay with their atoms. In a crystal there are however energy bands that are still bound states of the crystal, but they belong to the entire crystal. Electrons in this bands and the holes in the lower band can freely move around the crystal, if an electric field is applied. W. Riegler/CERN 1

Solid State Detectors Free Electron Energy Unfilled Bands Conduction Band Band Gap Valance Band W. Riegler/CERN 2

Solid State Detectors In case the conduction band is filled the crystal is a conductor. In case the conduction band is empty and far away from the valence band, the crystal is an insulator. In case the conduction band is empty but the distance to the valence band is small, the crystal is a semiconductor. The energy gap between the last filled band the valence band and the conduction band is called band gap E g. The band gap of Diamond/Silicon/Germanium is 5.5, 1.12, 0.66 ev. The average energy to produce an electron/hole pair for Diamond/Silicon/Germanium is 13, 3.6, 2.9eV. In case an electron in the valence band gains energy by some process, it can be excited into the conduction band and a hole in the valence band is left behind. Such a process can be the passage of a charged particle, but also thermal excitation probability is proportional Exp(-E g /kt). The number of electrons in the conduction band is therefore increasing with temperature i.e. the conductivity of a semiconductor increases with temperature. W. Riegler/CERN 3

Solid State Detectors W. Riegler/CERN 4

Solid State Detectors It is possible to treat electrons in the conduction band and holes in the valence band similar to free particles, but with and effective mass different from elementary electrons not embedded in the lattice. This mass is furthermore dependent on other parameters such as the direction of movement with respect to the crystal axis. All this follows from the QM treatment of the crystal. If we want to use a semiconductor as a detector for charged particles, the number of charge carriers in the conduction band due to thermal excitation must be smaller than the number of charge carriers in the conduction band produced by the passage of a charged particle. Diamond (E g =5.5eV) can be used for particle detection at room temperature, Silicon (E g =1.12 ev) and Germanium (E g =0.66eV) must be cooled, or the free charge carriers must be eliminated by other tricks doping see later. W. Riegler/CERN 5

Solid State Detectors The average energy to produce an electron/hole pair for Diamond/Silicon/Germanium is 13, 3.6, 2.9eV. Comparing to gas detectors, the density of a solid is about a factor 1000 larger than that of a gas and the energy to produce and electron/hole pair e.g. for Si is a factor 7 smaller than the energy to produce an electron-ion pair in Argon. The number of primary charges in a Si detector is therefore about 10 4 times larger than the one in gas while gas detectors need internal charge amplification, solid state detectors don t need internal amplification. While in gaseous detectors, the velocity of electrons and ions differs by a factor 1000, the velocity of electrons and holes in many semiconductor detectors is quite similar. Diamond A solid state ionization chamber W. Riegler/CERN 6

Diamond Detector Typical thickness a few 100μm. <1000 charge carriers/cm 3 at room temperature due to large band gap. Velocity: μ e =1800 cm 2 /Vs, μ h =1600 cm 2 /Vs Velocity = μe, 10kV/cm v=180 μm/ns Very fast signals of only a few ns length! z E -q, v e I 2 q,v h Z=D Z=z 0 I 1 (t) A single e/h par produced in the center Z=0 I 1 T=2-3ns W. Riegler/CERN 7

Diamond Detector I 2 Z=D E -q, v e q,v h Z=z 0 Z=0 I 1 I 1 (t) However, charges are trapped along the track, only about 50% of produced primary charge is induced I 1 (t) T=2-3ns T=2-3ns W. Riegler/CERN 8

Silicon Detector Velocity: μ e =1450 cm 2 /Vs, μ h =505 cm 2 /Vs, 3.63eV per e-h pair. ~11000 e/h pairs in 100μm of silicon. However: Free charge carriers in Si: T=300 K: n/h = 1.45 x 10 10 / cm 3 but only 33000e- /h in 300 m produced by a high energy particle. Why can we use Si as a solid state detector??? W. Riegler/CERN 9

Doping of Silicon doping In a silicon crystal at a given temperature the number of electrons in the conduction band is equal to the number of holes in the valence band. p n Doping Silicon with Arsen (5) it becomes and n-type conductor (more electrons than holes). Doping Silicon with Boron (3) it becomes a p-type conductor (more holes than electrons). Bringing p and n in contact makes a diode. W. Riegler/CERN 10

Si-Diode used as a Particle Detector! At the p-n junction the charges are depleted and a zone free of charge carriers is established. By applying a voltage, the depletion zone can be extended to the entire diode highly insulating layer. An ionizing particle produces free charge carriers in the diode, which drift in the electric field and induce an electrical signal on the metal electrodes. As silicon is the most commonly used material in the electronics industry, it has one big advantage with respect to other materials, namely highly developed technology. W. Riegler/CERN 11

Electric Field Under-Depleted Silicon Detector - - - -- - p n Zone without free charge carriers positively charged. Sensitive Detector Volume. Zone with free electrons. Conductive. Insensitive to particles. W. Riegler/CERN 12

Electric Field Fully-Depleted Silicon Detector - - - -- - p Zone without free charge carriers positively charged. Sensitive Detector Volume. n W. Riegler/CERN 13

Electric Field Over-Depleted Silicon Detector - - - -- - p Zone without free charge carriers positively charged. Sensitive Detector Volume. n In contrast to the (un-doped) diamond detector where the bulk is neutral and the electric field is therefore constant, the sensitive volume of a doped silicon detector is charged (space charge region) and the field is therefore changing along the detector. Velocity of electrons and holes is not constant along the detector. W. Riegler/CERN 14

Depletion Voltage - - - -- - p n The capacitance of the detector decreases as the depletion zone increases. Full depletion W. Riegler/CERN 15

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Silicon Detector Fully depleted zone readout capacitances ca. 50-150 m SiO 2 passivation 300 m N (e-h) = 11 000/100μm Position Resolution down to ~ 5μm! W. Riegler/CERN 18

x What is the Signal induced on the p layer? -V d x h hole x e electron x 0 p n- n E What is the signal induced on the p electrode for a single e/h pair created at x 0 =d/2 for a 300um Si detector? W. Riegler/CERN 19

x What is the Signal induced on the p layer? -V d x h hole electron x e x 0 p n- E n W. Riegler/CERN 20

x What is the Signal induced on the p layer? -V d x h hole x e electron x 0 p n- n What is the signal induced on the p electrode for a single e/h pair created at x 0 =d/2 for a 300um Si detector? Electron Hole Total To calculate the signal from a track one has to sum up all the e/h pair signal for different positions x 0. Si Signals are fast T<10-15ns. In case the amplifier peaking time is >20-30ns, the induced current signal shape doesn t matter at all. The entire signal is integrated and the output of the electronics has always the same shape (delta response) with a pulse height proportional to the total deposited charge. W. Riegler/CERN 21

Biasing, AC coupling

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Picture of an CMS Si-Tracker Module Outer Barrel Module W. Riegler/CERN 27

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2,4 m CMS Tracker Layout Inner Barrel & Disks TIB & TID - Outer Barrel -- TOB- End Caps TEC 1&2- Total Area : 200m 2 Channels : 9 300 000 W. Riegler/CERN 29

W. Riegler/CERN 30

CMS Tracker W. Riegler/CERN 31

Silicon Drift Detector (like gas TPC!) bias HV divider Collection drift cathodes ionizing particle pull-up cathode W. Riegler/CERN 32

Resolution ( m) Silicon Drift Detector (like gas TPC!) Anode axis (Z) Drift time axis (R-F) Drift distance (mm) W. Riegler/CERN 33

Pixel-Detectors Problem: 2-dimensional readout of strip detectors results in Ghost Tracks at high particle multiplicities i.e. many particles at the same time. Solution: Si detectors with 2 dimensional chessboard readout. Typical size 50 x 200 μm. Problem: Coupling of readout electronics to the detector. Solution: Bump bonding. W. Riegler/CERN 34

Bump Bonding of each Pixel Sensor to the Readout Electronics ATLAS: 1.4x10 8 pixels W. Riegler/CERN 35

Radiation Effects Aging W. Riegler/CERN 36

Increase in leakage current Increase in depletion voltage Radiation Effects Aging Decrease in charge collection efficiency due to underdepletion and charge trapping. W. Riegler/CERN 37

Radiation Effects Aging Type inversion! An n-tyle Si detector becomes a p-type Si detector! W. Riegler/CERN 38

Silicon Detectors: towards higher Radiation Resistance Typical limits of Si Detectors are at 10 14-10 15 Hadrons/cm 2 R&D Strategy: Defect Engineering Oxygen enriched Si New Materials Diamonds Czochralski Si New Geometries Low Temperature Operation VCI 2004 summary 39

New Materials: Polycrystalline Diamond VCI 2004 summary 40

New Material: Czochralski Silicon 1.25x10 14 p/cm 2 4.25x10 14 p/cm 2 7x10 14 p/cm 2 Due to 1000 times higher Oxygenation levels compared to standard Si: expect improved Radiation Resistance VCI 2004 summary 41

New Geometries: 3D Si Detectors Good Performance after 10 15 p/cm 2 VCI 2004 summary 42

High Resolution Low Mass Silicon Trackers, Monolithic Detectors Linear Collider Physics requirement: Large variety of monolithic pixel Detectors explored, mostly adapted to low collision rates of LC. VCI 2004 summary 43

Summary on Solid State Detectors Solid state detectors provide very high precision tracking in particle physics experiments (down to 5um) for vertex measurement but also for momentum spectroscopy over large areas (CMS). Technology is improving rapidly due to rapis Silicon development for electronics industry. Typical number where detectors start to strongly degrade are 10 14-10 15 hadron/cm 2. Diamond, engineered Silicon and novel geometries provide higher radiation resistance. Clearly, monolithic solid state detectors are the ultimate goal. Current developments along these lines are useful for low rate applications. ar W. Riegler/CERN 44

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