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THE CSU ADVANCED BEAM LABORATORY (ABL) Sandra Biedron 1.

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Presentation on theme: "THE CSU ADVANCED BEAM LABORATORY (ABL) Sandra Biedron 1."— Presentation transcript:

1 THE CSU ADVANCED BEAM LABORATORY (ABL) Sandra Biedron 1

2 ABL: Two Primary Focus Area Accelerator Science and Technology Leads: Sandra Biedron and Stephen Milton Lasers Jorge Rocca, Menoni, Mario Marconi Main Concept Merge Accelerator Technologies with Laser Technologies to create new technologies with performance capabilities not possible with only one. 2

3 The Advanced Beam Laboratory CSU Board of Governors approved construction and expenditure of the money needed to build of the new building. CSU President has chosen to move forward with the construction and has developed a funding plan. 3

4 ABL Timeline Accelerated Delivery Made possible by an existing construction contract to build what is called Engineering II. We are using the same Architect and General Contractor Timeline (Abbreviated) 12 November 2012 – Fence off construction yard 19 November 2012 – Begin site preparation work February 2013 – Walls go up 31 July 2013 – Building ready for move in 4

5 ABL: Current Status Footings and Slab Complete 5 Iron work going up

6 ABL Basic Layout and Initial Capabilities 6 Laser Lab 1 Laser Lab 2 Accelerator Lab Drive Laser Laboratory Accelerator Control Room 100-150 Terawatt Ti:Sapphire laser system. Wavelength: 0.8 micrometers, Energy before compression: 13 Joules. Repetition rate: up to 5 Hz. Plans to scale to 0.5 Petawatt 1 J, 5 picosecond, 100 Hz repetition rate diode-pumped laser (100 W average power) Wavelength: 1.03 micrometers. Highest repetition rate diode-pumped chirped-pulse- amplification laser in the world. Can be scaled in repetition rate and pulse energy, future parameters depend on funding. 6 MeV Photocathode Driven Electron Linac L- Band (1.3 GHz) Two Klystrons Available (One needed for PC Gun) 15 us pulse durations at 10 Hz Up to 81.25 MHz pulse rates available

7 High energy femtosecond Ti:Sapphire laser (> 100 TW, up to 5 Hz repetition rate) Profs. Jorge Rocca, Carmen Menoni

8 Energy Pre-compression= 13 J Std div. = 1.5 % High repetition rate Titanium-Sapphire laser

9 Unique high power diode-pumped solid state lasers pump table-top soft x-ray lasers at 100 Hz repetition rate Laser Diode Drivers Soft X-Ray Plasma Amplifier Solid State Ultrashort Pulse High Power Laser Ag +19 13.9 nm laser e B. Reagan et al., Optics Letters, 37, 3624, ( 2012)

10 Compact high power diode-pumped CPA laser generates 1 J, 5 ps, pulses at 100 Hz repetition rate B. Reagan et al., Optics Letters, 37, 3624, ( 2012) 1 J, 5 ps, 100 Hz

11 Laser Pumped SXRL λ= 8.8– 32.6 nm Discharge Pumped SXRL λ=46.9 nm 100 nm lines 82 nm holes Chemical spectroscopies Microscopy Nanomachining Interferometry Compact plasma-based soft x-ray lasers for application (J.J. Rocca, C.S Menoni. M. Marconi) Plasma diagnostics 58 nm pillars Nanopatterning High pulse energy (µJ-mJ) High monochromaticity (λ/Δλ < 10 -4 ) High peak spectral brightness

12 Gain-saturated table-top SXRLs cover 8.8 nm - 47 nm wavelength region Pr Saturated Seeded  D. Alessi et al. Phys. Rev X, 1, 021023, (2011)

13 CSU Accelerator Laboratory 13 Donated by the Univ. of Twente Donated by the Boeing Corp.

14 Linac Performance Parameters 14 Linac Characteristics Energy6 MeV Number of Cells5 ½ RF Frequency1.3 GHz Shunt Impedance 50 M  /m Q-Value18,000 Axial Electric Field Cell no. 126 MV/m Cell No. 214.4 MV/m Cell No. 3 – 610.6 MV/m Solenoid Field Strength1,200 G

15 System Performance Parameters 15 Major System Parameters Linac Frequency1.3 GHz Repetition Rate10 Hz Mircopulse Rep. Rate81.25 MHz (max.) Klystron TypeTH 2022C (Thales) Power20 MW Modulator TypePFN Pulse Duration 15  sec Undulator TypeHybrid: NdFeB K1 (at 8 mm gap) Period25 mm Periods50

16 Cathode Preparation Chamber A Variety of Cathodes Can be Used Cathode preparation chamber Used in the past CeK 2 Sb, K 3 Sb, and Copper The choice is dependent on what the experiment demanded A Variety of Cathodes Can be Used Cathode preparation chamber Used in the past CeK 2 Sb, K 3 Sb, and Copper The choice is dependent on what the experiment demanded 16

17 ABL Initial Capabilities/Explorations Laser Laboratories: Initial and Historical Functions Soft x-ray lasers (driven by the optical lasers in previous slide) Wavelength range: 8.8 nm to 47 nm. Picosecond pulse duration. Pulse energy = 2-10 microjoule. Average power: up to 0.15 mW (world highest average power table top soft x-ray lasers) Side Note: These soft x-ray lasers are made possible by the generation of very uniform, high density plasmas. Ancillary Capabilities of Group Laser design and fabrication High power optics development and production Nano patterning 17

18 ABL Initial Capabilities/Explorations Accelerator Laboratories: Initial and Historical Functions Compact, High-power THz FEL Tunable between 200-800 microns About 1 MW peak power from 900 MW available peak beam power (6 MeV, 150 A peak current) Average: a few mW (81.25 MHz rep rate, 15 microsecond macropulse,25-ps micropulse) Specialized beam diagnostics Electro Optical Sampling System System intended for tests at JLab FEL If JLab not ready then we will test it at CSU Laser/Plasma/e- Beam Interaction Studies Continuation of an experiment started at University of Twente 18

19 A Smattering of Current Projects Soft X-ray compact laser development High-Power THz FEL Neural Network Control of Accelerators X-band Technologies High Power Optics Development Nanopatterning High Density Plasma Theory, Simulation, and Production Electro-Optical Sampling Diagnostic for High-Power Beams Photocathode studies Laser/Plasma/e- Beam interactions Compact source design and development Study of LSC/CSR and the Microbunching Instability Medical Applications of Accelerator System Two-Beam Systems FEL Harmonic Control 19 Blue indicates areas potentially relevant to HEP programs

20 Other Intriguing Areas We Are Beginning to Pursue Capillary Discharge 20 Electron Density Profile Near Field Far Field The potential to use this technology for high-gradients is tremendous and CSU IS the world leader in this.

21 Summary The CSU Advanced Beam Laboratory The Coupling of Accelerator Expertise and Existing Accelerator System 6 MeV photocathode linac system with state-of-the-art drive laser Laser/Plasma Expertise and Existing Laser, Plasma and Ancillary Systems/Areas Unique state-of-the-art laser systems Plasma Sources EUV/Soft x-ray Microscopy/Spectroscopy expertise Multilayer Optics expertise Will be used for Basic beam (Laser, particle and combined beam) research and development Purpose-Built Building Ready for move in 31 July 2012 21

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