Survey
* Your assessment is very important for improving the work of artificial intelligence, which forms the content of this project
Download Plenary presentation
Document related concepts
no text concepts found
Transcript
Photocathode based Electron Sources for Particle Accelerators – Yesterday, Today and Tomorrow B.L. Militsyn STFC ASTeC, UK European Workshop on Photocathodes for Particle Accelerator Applications, 6-8 June 2016, Daresbury, UK Outline • Days before yesterday – discovery of the photoeffect • Yesterday – first photocathode based electron sources – DC photocathode guns – RF photocathode guns • Today – evolution of photoelectron sources – DC – RF (SRF) – VHF • Tomorrow – what do we expect from the future photocathodes B.L. Militsyn, EWPPAA, Daresbury, UK 6 June 2016 Days before yesterday. Discovery of the Photoeffect. The Nobel Prize in Physics 1921 was awarded to Albert Einstein "for his services to Theoretical Physics, and especially for his discovery of the law of the photoelectric effect". Heinrich Rudolf Hertz (1847-1894) Philipp Eduard Anton von Lenard (1862-1947) Albert Einstein (1879-1955) B.L. Militsyn, EWPPAA, Daresbury, UK 6 June 2016 Yesterday. SLAC DC photocathode gun Photocathode used, Maximum polarization B.L. Militsyn, EWPPAA, Daresbury, UK 6 June 2016 GaAs 40% Yesterday. Los Alamos Photocathode RF gun Operation Frequency Photocathode used Peak surface field Bunch charge Peak beam current Beam emittance B.L. Militsyn, EWPPAA, Daresbury, UK 6 June 2016 1.3 GHz Cs3Sb 60 MV/m 12 nC 100-150 A 32 mm·mrad Yesterday. BNL RF Gun Photoctahode used Beam emittance Cu 3 mm·mrad B.L. Militsyn, EWPPAA, Daresbury, UK 6 June 2016 Today: Very general classification of the photoelectron sources • Out of the gun photocathode preparation and exchange with a Load-Lock system • Electron emission – Photocathodes • Metal • Amorphous semiconductor • Crystalline semiconductors • Electron acceleration – DC high voltage – Radiofrequency acceleration • Normal conductive acceleration • Superconductive acceleration – VHF field acceleration • Normal conductive acceleration • Superconductive acceleration B.L. Militsyn, EWPPAA, Daresbury, UK 6 June 2016 Today: Modern DC gun designed for ERL • Maximum voltage achieved – 500 kV • Maximum design current – 10 mA • Photocathode – GaAs/Sb • Photocathode preparation system (not shown) integrated with the gun • For protection of the ceramic insulator from field emission and scattered electrons it is made segmented B.L. Militsyn, EWPPAA, Daresbury, UK 6 June 2016 Today: NC RF CLARA Gun-400 H shape coupler RF probe* Cathode plug and spring retaining plate. B.L. Militsyn, EWPPAA, Daresbury, UK 6 June 2016 Cooling channels Gun Cavity Today. Design parameters of the Gun-400 Units Beam Repetition Rate Operating mode 100 Hz 400 Hz Frequency GHz 2.9985 RF peak power MW <10 RF average power kW 10 Gun electric field MV/m Bunch charge pC Operating mode RF feedback B.L. Militsyn, EWPPAA, Daresbury, UK 6 June 2016 120 100/80 20-250 250 Pulsed/Train pulsed Pulsed Required Today: The LBNL VHF photocathode gun Photocathode used Metal/Te/Sb B.L. Militsyn, EWPPAA, Daresbury, UK 6 June 2016 Today: ELBE SRF Photocathode gun RF frequency RF scheme Operation mode Photocathode used B.L. Militsyn, EWPPAA, Daresbury, UK 6 June 2016 1.3 GHz 3.5 cells CW Cs2Te/Metal Today: Photocathode Materials Class Mate rial QE Response time Intrinsic Energy Wave Length Gun Application Normally conducting metals Cu, Mg 10-510-4 10’s fs 100’s mV – 1’s V UV NC-RF, VHF Low rep rate FELs Super conducting metals Nb,Pb 10-510-4 10’s fs 100’s mV – 1’s V UV SC-RF High rep rate FELs Positive eaffinity Tebased Cs2Te 0.10.2 ps’s 100’s mV UV NC-RF, SC-RF VHF DC High rep rate FELs Positive eaffinity Sbbased Cs3Sb etc 0.10.2 ps’s 100’s mV Visible DC VHF, SCRF(?) NCRF(???) ERLs, High rep rate FELs Negative eaffinity semiconductor GaAs, etc 0.10.35 1’s ps – 100’s ps 10’s mV – 100’s mV IR- Visible DC (XHV) Polarized sources, ERLs B.L. Militsyn, EWPPAA, Daresbury, UK 6 June 2016 Tomorrow: general requirements for electron accelerators: • Beam energy – 100’s keV – GeV’s • Bunch peak current – Amps – kA’s – Bunch charge – fC’s – nC’s – Bunch duration – fs’s – ns’s • Beam average current – nA’s –A’s – Bunch charge – fC’s – nC’s – Bunch repetition rate – Hz – 100’s MHz • Beam energy spread – 0.1 %’s • Beam emittance – sub µm’s • Beam synchronisation – less than10’s of fs B.L. Militsyn, EWPPAA, Daresbury, UK 6 June 2016 Compact Linear Accelerator for Research and Applications CLARA FEL OUTPUT STUDIED VELA RF Photoinjector Test Facility Notes: 1. CLARA uses European RF frequencies 2. X-band cavity is used for phase space linearisation CLARA Phase I Commissioning starts September 2016 B.L. Militsyn, EWPPAA, Daresbury, UK 6 June 2016 Tomorrow: Requirements to the photocathodes for the future accelerator • • • • High Quantum efficiency High Robustness Low intrinsic emittance Fast response time We are waiting your new ideas! B.L. Militsyn, EWPPAA, Daresbury, UK 6 June 2016 Thank you for your attention!
Related documents