Diagnostics at the MAX IV 3 GeV storage ring during commissioning. PPT-mall 2. Åke Andersson On behalf of the MAX IV team

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Diagnostics at the MAX IV 3 GeV storage ring during commissioning PPT-mall 2 Åke Andersson On behalf of the MAX IV team IBIC Med 2016, linje Barcelona

Outline MAX IV facility overview Linac injector mode diagnostics 3 GeV ring diagnostics

The MAX IV facility: Concept Different machines for different uses: A high energy ring with ultra-low emittance for hard X-ray users. A low emittance low energy ring for soft radiation users A LINAC based source for generating short pulses and allowing for future development of FEL source.

Inauguration was June 21, 2016

3 GeV ring design parameters MAX IV 3 GeV storage ring parameters. Operating energy 3 GeV Circulating current 500 ma Circumference 528 m Horizontal emittance (bare lattice) 330 pm rad Horizontal emittance (incl. IDs) 180 pm rad Vertical emittance 2 8 pm rad Total beam lifetime at 500 ma >10 h Qx, Qy 42.20, 16.28 Chromx, Cromy (natural) -50.0, -50.2 Momentum compaction factor 3.06 10-4 Required momentum acceptance >4.5 %

Inside the Linac building Linear accelerator Klystron gallery Photo Annika Nyberg Photo Annika Nyberg

Inside the 3 GeV building Photo Simon Leemann

Outline MAX IV facility overview Linac injector mode diagnostics 3 GeV ring diagnostics

Linac injector mode Injector linac design parameter values. End energy 3 GeV RF 2.9985 GHz Field gradient 17 MV/m Acc cell length 5.2 m No of structures 39 Norm emittance 6 mm*mrad

Linac injector mode Thermionic RF gun Extraction 1.5 GeV L2A L2B L3A L9B L19B Extraction 3 GeV SPF Kicker & septum BC2 @ 3 GeV Photo cathode RF gun BC1 @ 260 MeV Current Transformer signals (Z=1 Ω) after thermionic gun (blue), chopper system (green) and energy filter (orange). Slide by S.Thorin

Linac injector mode YAG- Screen measurements

Outline MAX IV facility overview Linac injector mode diagnostics 3 GeV ring diagnostics

Beam Position Monitors

MAX IV 3 GeV ring DC magnets Each cell is realized as one mechanical unit containing all magnet elements. Each unit consists of a bottom and a top yoke half, machined out of one solid iron block, 2.3-3.4 m long. Slide by Martin Johansson

Strong, 25 mm bore, sextupoles & achromatic octupoles for nonlinear optics. All those carry auxiliary windings that can be used as: Additional H/V correctors Auxiliary sextupoles Skew quadrupoles (coupling & vertical dispersion correction) Upright quadrupoles (calibrate BPMs to the center of adjacent sextupole/octupole) Non-linear magnets

BPMs first turns

Offset [mm] Once beam is stored: BPM offsets 1.0 Horizontal Vertical 0.5 0.0-0.5-1.0 100 200 300 400 500 S[m]

DX [mm] DY[mm] Once beam is stored: Tune integers 1.0 0.5 Model Experiment M1-COAY-01 changed by 0.1 mrad 0.0-0.5-1.0 100 200 300 400 500 S[m] 2 1 Model Experiment M1-COAX-01 changed by 0.1 mrad 0-1 -2 100 200 300 400 500 S[m]

Fractional Tunes Horizontal Tune from TBT data Excitation by Kicker&Pinger Tunes on Spectrum Analyzer Excitation by Stripline qy=0.22 qx=0.32

Monitoring the machine functions Two ways: 1. LOCO orbit response measurements. 2. Induced tune-shifts from quadrupole strength variations. 2. Is with our 24 trim coils per achromat probing densly the beta-functions Bad news: So far we get way too large discrepancies!!!

Bunch-by-bunch feedback system Processors by: http://www.dimtel.com/ This is a powerful diagnostics system! Presently, we measure growth rates of CBIs driven by long. cavity HOMs. Guides nicely the cavity temp tuning. Long stability up to 120 ma, using a weak long. common mode excitation at one strip-line pair.

Emittance measurements

Emitt. Meas.: Extraction in S1

Emitt. Meas.: Extraction SiC mirror The extraction mirror (lowest black piece) is prisma shaped in order to come as close as possible to the electron beam. 15 to 18 horizontal mrads of the SR fan is extracted. Fringe field radiation is extracted as well for improved diagnostics.

Emitt. Meas.: Vertical beam size

Emitt. Meas.: Horizontal beam size Measured horizontal profile: 8.2 mrad H less pronounced fringes At 930 nm Theorethical horizontal profiles: 15 mrad H Wavelength is 930 nm Future DLSR, using visible SR A few micron rms beam sizes might be resolvable

Longitudinal bunch profiles Not yet observed the flat potential case at MAX IV. We still need to further temperature tune the cavities to avoid longitudinal CBIs, when Landaus are engaged. Optical sampling oscilloscope

Summary Still a lot of commissioning to be done! We believe we have the necessary diagnostics! We just need to carefully observe them!

Thank You for your attention!

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