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Materials Considerations in Photoemission Detectors. S W McKnight C A DiMarzio. Energy Bands in Solids. Energy. Forbidden electron energies (Energy Gap). E g2. Allowed electron energies (Energy Band). E g1. Energy Bands and Gaps.
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Materials Considerations in Photoemission Detectors S W McKnight C A DiMarzio
Energy Bands in Solids Energy Forbidden electron energies (Energy Gap) Eg2 Allowed electron energies (Energy Band) Eg1
Energy Bands and Gaps • Metals, insulators, and semiconductors all have energy bands and gaps • Difference is due to electron filling of bands • Metals: highest band with electrons in it is part-filled. • Insulators: highest band with electron in it is completely filled. (Filled band carries no net current.)
Electron Fermi Energy • Pauli Exclusion Principle (“fermions”): each electron state can be occupied by no more than one electron per spin state • Fermi Energy (Ef) separates occupied states from unoccupied states at T=0K • Ef is halfway between highest filled state and lowest empty state
Metal/Insulator Band Structure Energy Ef Ef Metal Insulator
Semiconductor Band Structure Ef Ef Ef Eg electrons “holes” Extrinsic Semiconductor (n-type) Extrinsic Semiconductor (p-type) Intrinsic Semiconductor (Eg≤ ~100 kT)
Surface Energies Vacuum Level (Evac) Ea Ec Vacuum Level (Evac) Фo Ef Ea = electron affinity = Evac - Ec Фo= work function = Evac - Ef Metal Insulator
Photomultiplier Tubes • Vacuum photoemissive device • Window • End-on, side-looking • Photocathode • Insulator/semiconductor materials (better η than metals) • Spectral response from UV to Near IR • Moderate quantum efficiency (< 0.3) • Dynode chain • Gain ~106 through secondary electron emission
Photocathode • Quantum efficiency (ηq) • ηq= (# emitted photoelectrons/# of incident photons) • Photon absorbed • Photoelectron created • Photoelectron escapes surface • Wavelength limits • hν > Eg + Ea • UV tubes: CsI, CsTe “solar blind” (<300-200 nm) • IR tubes: multi-alkali materials (Sb-Na-K-Cs)
Photocathode Quantum Efficiency η = PA Pν Pt Ps PA = Probability that photon will be absorbed by material = (1-R) Pν = Probability that light absorption will excite electron above vacuum level Pt = Probability that electron will reach surface PS = Probability that electron reaching surface will be released into vacuum
Probability of absorption between x and x+dx and electron escaping to surface = P(x) = k e-kx dx e-x/L P(x) = k e –(kx + x/L) dx Total probability of absorption and electron escaping to surface = P(x1) + P(x2) + P(x3) + …
Photocathode Quantum Efficiency Pν = Probability that light absorption will excite electron above vacuum level PS = Probability that electron reaching surface will be released into vacuum R= Surface reflectivity k= photon absorption coefficient L= mean escape length of electrons
Photocathode Materials • Cs-Te: UV “solar blind” • Sb-Cs: UV-Vis • Bialkali (Sb-Rb-Cs, Sb-K-Cs): UV-Vis • Multialkali (Sb-Na-K-Cs): UV-IR • Ag-O-Cs: Vis-IR • GaAs(Cs), InGaAs(Cs): UV-IR
Bialkali Cs-Te Sb-Cs
Dynode Chain • Amplification of photoelectrons by secondary electron emission • δ = (# of secondary electrons) / (# of primary electrons) • Gain: G~(δ)n (for n-stage dynode chain)
Secondary Electron Emission E Primary Electron Collision Process x Secondary Electrons Ea Vacuum Level Ec Eg Electron-Hole Pairs Valence Band Surface Insulator/Semiconductor
Secondary Electron Emission • Primary electron loses energy to electrons in solid • Metals: electron-electron interactions • Insulators: electron-hole creation • Penetration depth proportional to primary electron energy • Secondary electrons travel to surface • Electron-electron or electron-phonon collisions reduce energy and facilitate recombination • Greater chance of collision if created deeper • More electron-electron collisions in metals than insulators • Secondary electrons emitted into vacuum • Requires kinetic energy > electron affinity (Ea) • Secondary emission coefficient (σ) = (# of secondaries)/ (number of primaries)
Electron-Electron Scattering Vacuum Level (Evac) Vacuum Level (Evac) Ea Ec Фo Ef Electrons Ea = electron affinity = Evac - Ec Фo= work function = Evac - Ef Holes Metal Insulator Many final states available Few final states available
Secondary Emission Coefficients From Handbook of Physics and Chemistry
MCP-PMT • High gain/compact size • 2D detection with high spatial resolution • Fast time response • Stable in high magnetic fields • Low power consumption and light weight
Photomultiplier Limitations • Dark current • Drift • Response time • Saturation: space charge limit • Tube damage at high illumination (anode current limit)
Anode/Cathode Sensitivity • Radiant Sensitivity: photocurrent per incident radiant flux at given wavelength (A/W) • Luminous Sensitivity: photocurrent per incident luminous flux from tungsten lamp at 2856K (A/lm)