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Results for 500 GeV CLIC optimized for concervative emittance A.Grudiev 03/03/2008.

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Presentation on theme: "Results for 500 GeV CLIC optimized for concervative emittance A.Grudiev 03/03/2008."— Presentation transcript:

1 Results for 500 GeV CLIC optimized for concervative emittance A.Grudiev 03/03/2008

2 Beam dynamics constraints at 500GeV and conservative emittance Short range wake limits bunch charge Long range wake amplitude on the second bunch limits the bunch spacing: W t (2) * N / < 20 V/pC/m/mm * 4x10 9 / 150 MV/m 10 V/pC/m/mm has been used for 3TeV ε x,y = 3μm, 40nm β x,y = 8mm, 0.1mm

3 Other constraints Rf constraints: –18 Wu –260 MV/m –56 K –Rf phase advance per cell: 120 or 150 degree No 3TeV constraints: –Structure length L s more than 200 mm; –Pulse length t p is free –Bunch spacing N s is free 3TeV constraints N s = 6: 1.L s = 230 mm; t p = 242 ns 2.L s = 480 mm; t p = 242 ns 3.L s = 480 mm; t p = 483 ns

4 Figure of Merit 9.1

5 Rf-to-beam efficiency

6 Average a/λ

7 L 1 per bx-ing over bunch charge 0.32

8 Beam power for L 1 = 2 [10 34 /s·cm 2 ] 14 MW/beam

9 Input power for L 1 = 2 [10 34 /s·cm 2 ] 50.4 MW/linac

10 If power loss per meter is limited to nominal (P l -P b )* = const

11 Repetition rate for L 1 = 2 [10 34 /s·cm 2 ] 50 Hz

12 If repetition rate is limited to 50 Hz 2 1 3

13 Parameters of the structures for 500 GeV Case 3TeV nominal 0123 StructureCLIC_G Average accelerating gradient: [MV/m] rf phase advance: φ[ o ] Average iris radius/wavelength: /λ Input/Output iris radii: a 1, 2 [mm]3.15, , , 3.1 Input/Output iris thickness: d 1, 2 [mm]1.67, , , 1.04 Group velocity: v g (1,2) /c [%]1.66, , , 1.21 N. of reg. cells, str. length: N c, l [mm]24, , 22943, 480 Bunch separation: N s [rf cycles]66666 Luminosity per bunch X-ing: L b× [m -2 ]1.22× × × × ×10 34 Bunch population: N3.72× × × × ×10 9 Number of bunches in a train: N b Filling time, rise time: τ f, τ r [ns]62.9, , , 13.9 Pulse length: τ p [ns] Input power: P in [MW] P in /Ct P p 1/3 [MW/mm ns 1/3 ] Max. surface field: E surf max [MV/m] Max. temperature rise: ΔT max [K] Efficiency: η [%] Figure of merit: ηL b× /N [a.u.]

14 Parameters of CLIC main linac in different cases case 3TeV nominal 0123 StructureCLIC_G Luminosity : L 1 [ cm -2 s -1 ] Repetition frequency: f rep [Hz]50.0 RF input power: P l [MW/linac] RF energy per pulse: P l /f rep [kJ/linac] Case 0: if we do not change anything then Luminosity reduction is ~6 Case 1: Changing the scheme but keeping CLIC_G. Reducing gradient to 67 MV/m but doubling pulse length results in Luminosity reduction only 4 or 3 depending on the repetition rate. It implies twice less PETS per meter as well as twice less turn-arounds. Case 2: Keeping the nominal scheme but changing the accelerating structure. Luminosity reduction ~2. Case 3: Both scheme and structure are changed. Reducing gradient by 2 and increasing structure length and pulse length by 2. No luminosity reduction. It implies twice less PETS and turn-arounds.

15 Parameters of structures for case 2 and case 3 Case 2 Case 3

16 L 1 /N for different disruption parameter limit, δ δ < 20 δ < 10

17 Figure of merit

18 Appendix1: some other parameters for conservative emittance

19 Peak input power per structure 64 MW

20 Pulse length 242ns

21 Bunch spacing 6

22 Structure length 230mm

23 Appendix 3:Detailed parameters 120 o

24 φ =120 o, no 3TeV-constraints : =50MV/m Ea = 50 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Es (0.05;0.100,0.100) Es (0.16;0.100,0.100) dT (0.26;0.100,0.100) dT (0.25;0.100,0.100) dT (0.24;0.100,0.100) dT (0.27;0.100,0.100) dT (0.26;0.100,0.100) dT (0.23;0.120,0.120) Es (0.25;0.100,0.200) Es (0.24;0.100,0.280) Ef (0.38;0.100,0.120) Ef (0.39;0.100,0.160) Ef (0.37;0.140,0.220) Ef (0.38;0.100,0.240) Ef (0.39;0.120,0.260) Ef (0.37;0.140,0.320) Ef (0.36;0.100,0.380) Ef (0.38;0.100,0.400) Ef (0.52;0.120,0.340) Es (0.27;0.100,0.400) Es (0.23;0.100,0.400) Es (0.60;0.160,0.320) Es (0.60;0.180,0.320) Pa (0.60;0.260,0.300) Pa (0.60;0.280,0.320) 93

25 φ =120 o, no 3TeV-constraints : =60MV/m Ea = 60 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Es (0.05;0.100,0.100) Es (0.04;0.100,0.120) Es (0.32;0.100,0.100) dT (0.27;0.100,0.100) dT (0.19;0.100,0.140) dT (0.27;0.140,0.100) Es (0.22;0.100,0.220) Ef (0.38;0.100,0.100) Ef (0.36;0.100,0.140) Pa (0.52;0.160,0.100) Ef (0.45;0.220,0.140) Ef (0.43;0.140,0.180) Ef (0.42;0.180,0.220) Ef (0.40;0.140,0.260) Ef (0.41;0.100,0.280) Ef (0.43;0.120,0.300) Pa (0.59;0.100,0.200) Pa (0.58;0.120,0.220) Pa (0.53;0.120,0.260) Pa (0.53;0.100,0.280) Pa (0.52;0.100,0.300) Pa (0.60;0.280,0.280) Pa (0.60;0.300,0.300) Pa (0.60;0.340,0.320) Pa (0.60;0.340,0.340) 84

26 φ =120 o, no 3TeV-constraints : =70MV/m Ea = 70 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Es (0.10;0.100,0.100) Es (0.05;0.100,0.120) dT (0.24;0.100,0.100) dT (0.15;0.120,0.180) Es (0.22;0.140,0.160) dT (0.34;0.240,0.140) dT (0.42;0.280,0.100) Ef (0.43;0.180,0.100) Ef (0.48;0.180,0.100) Pa (0.42;0.100,0.120) Ef (0.44;0.260,0.160) Pa (0.46;0.160,0.160) Pa (0.42;0.100,0.200) Pa (0.42;0.140,0.220) Pa (0.39;0.100,0.260) Pa (0.59;0.380,0.180) Pa (0.59;0.380,0.200) Pa (0.60;0.360,0.220) Pa (0.34;0.100,0.380) Pa (0.31;0.100,0.400) Pa (0.42;0.120,0.380) Pa (0.55;0.380,0.320) Pa (0.55;0.380,0.340) Pa (0.59;0.380,0.340) Pa (0.59;0.400,0.360) 76

27 φ =120 o, no 3TeV-constraints : =80MV/m Ea = 80 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Es (0.23;0.100,0.100) Es (0.21;0.100,0.120) Es (0.26;0.140,0.120) Es (0.20;0.160,0.160) dT (0.25;0.200,0.160) Ef (0.30;0.240,0.140) dT (0.40;0.300,0.120) Ef (0.44;0.300,0.120) Pa (0.29;0.320,0.200) Ef (0.52;0.380,0.120) Ef (0.43;0.280,0.180) Pa (0.43;0.280,0.180) Pa (0.38;0.220,0.220) Pa (0.38;0.240,0.240) Pa (0.38;0.200,0.280) Pa (0.39;0.180,0.280) Pa (0.33;0.140,0.340) Pa (0.32;0.100,0.380) Pa (0.32;0.140,0.400) Pa (0.31;0.120,0.400) Pa (0.49;0.380,0.340) Pa (0.49;0.400,0.360) Pa (0.43;0.380,0.400) Pa (0.40;0.400,0.400) Pa (0.35;0.400,0.380) 50

28 φ =120 o, no 3TeV-constraints : =90MV/m Ea = 90 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Es (0.23;0.100,0.100) Ef (0.30;0.120,0.100) Es (0.28;0.160,0.100) Es (0.25;0.180,0.140) dT (0.35;0.240,0.120) dT (0.41;0.280,0.100) dT (0.40;0.320,0.120) Ef (0.37;0.340,0.160) dT (0.39;0.380,0.160) dT (0.34;0.400,0.200) Pa (0.32;0.280,0.220) Pa (0.37;0.400,0.220) Pa (0.33;0.340,0.260) Pa (0.33;0.340,0.280) Pa (0.35;0.320,0.260) Pa (0.34;0.320,0.300) Pa (0.38;0.360,0.300) Pa (0.38;0.400,0.320) Pa (0.39;0.400,0.320) Pa (0.38;0.400,0.340) Pa (0.33;0.400,0.380) Pa (0.29;0.400,0.360) Pa (0.28;0.400,0.400) Pa (0.24;0.400,0.380) Es NaN (0.00;0.000,0.000) 0

29 φ =120 o, no 3TeV-constraints : =100MV/m Ea = 100 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es (0.20;0.140,0.180) dT (0.34;0.220,0.120) dT (0.30;0.240,0.140) dT (0.29;0.260,0.180) Ef (0.28;0.280,0.200) dT (0.28;0.320,0.200) dT (0.28;0.360,0.240) Pa (0.28;0.360,0.260) Pa (0.30;0.400,0.260) Pa (0.29;0.400,0.280) Pa (0.27;0.400,0.300) Pa (0.28;0.400,0.280) Pa (0.27;0.380,0.280) Pa (0.25;0.360,0.320) Pa (0.22;0.340,0.360) Pa (0.21;0.320,0.360) Pa (0.20;0.340,0.380) Pa (0.25;0.400,0.340) Pa (0.24;0.380,0.320) Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) 0

30 φ =120 o, Ls=230mm, tp=242 ns : =50MV/m Ea = 50 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.120,0.120) Nc (0.17;0.180,0.100) Nc (0.27;0.200,0.100) Nc (0.27;0.220,0.140) Nc (0.33;0.160,0.160) Nc (0.43;0.220,0.180) Nc (0.40;0.140,0.220) Nc (0.43;0.100,0.260) Nc (0.50;0.100,0.320) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) 0

31 φ =120 o, Ls=230mm, tp=242 ns : =57MV/m Ea = 57 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.120,0.120) Nc (0.01;0.140,0.140) Nc (0.17;0.200,0.120) Nc (0.27;0.220,0.120) Nc (0.26;0.240,0.140) Nc (0.34;0.180,0.180) Nc (0.43;0.240,0.180) Nc (0.41;0.160,0.240) Nc (0.44;0.120,0.280) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) 0

32 φ =120 o, Ls=230mm, tp=242 ns : =67MV/m Ea = 67 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.120,0.120) Nc (0.01;0.140,0.140) Nc (0.17;0.200,0.120) Nc (0.25;0.240,0.120) Nc (0.24;0.240,0.160) Nc (0.31;0.180,0.180) Nc (0.43;0.280,0.180) Nc (0.40;0.180,0.240) Nc (0.41;0.120,0.200) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) 0

33 φ =120 o, Ls=230mm, tp=242 ns : =80MV/m Ea = 80 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.120,0.120) Nc (0.01;0.140,0.140) Nc (0.11;0.180,0.120) Nc (0.22;0.240,0.120) Nc (0.22;0.260,0.160) Nc (0.31;0.200,0.200) Nc (0.43;0.300,0.160) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) 0

34 φ =120 o, Ls=230mm, tp=242 ns : =100MV/m Ea = 100 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Nc NaN (0.00;0.000,0.000) Nc (0.24;0.100,0.100) Nc (0.23;0.100,0.100) Nc (0.30;0.160,0.100) Nc (0.33;0.240,0.120) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) 0

35 φ =120 o, Ls=480mm, tp=242 ns : =50MV/m Ea = 50 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Nc NaN (0.00;0.000,0.000) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.02;0.100,0.100) Nc (0.13;0.100,0.100) Nc (0.19;0.100,0.100) Nc (0.11;0.100,0.100) Nc (0.23;0.100,0.100) Nc (0.36;0.100,0.100) Nc (0.38;0.100,0.120) Nc (0.47;0.100,0.260) Nc (0.55;0.100,0.340) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) 0

36 φ =120 o, Ls=480mm, tp=242 ns : =57MV/m Ea = 57 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Nc NaN (0.00;0.000,0.000) Nc (0.03;0.100,0.100) Nc (0.02;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.02;0.100,0.100) Nc (0.06;0.100,0.100) Nc (0.16;0.100,0.100) Nc (0.06;0.100,0.100) Nc (0.21;0.100,0.100) Nc (0.32;0.100,0.100) Nc (0.35;0.100,0.100) Nc (0.46;0.100,0.220) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) 0

37 φ =120 o, Ls=480mm, tp=242 ns : =67MV/m Ea = 67 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Nc NaN (0.00;0.000,0.000) Nc (0.20;0.100,0.100) Nc (0.14;0.100,0.100) Nc (0.09;0.100,0.100) Nc (0.07;0.100,0.100) Nc (0.17;0.100,0.100) Nc (0.25;0.100,0.100) Nc (0.34;0.100,0.100) Nc (0.42;0.100,0.100) Nc (0.49;0.120,0.100) Nc (0.55;0.180,0.100) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) 0

38 φ =120 o, Ls=480mm, tp=242 ns : =80MV/m Ea = 80 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc (0.35;0.100,0.100) Nc (0.40;0.100,0.100) Nc (0.46;0.100,0.100) Nc (0.53;0.100,0.100) Nc (0.59;0.180,0.100) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) 0

39 φ =120 o, Ls=480mm, tp=483 ns : =50MV/m Ea = 50 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Nc (0.03;0.100,0.140) Nc (0.03;0.100,0.100) Nc (0.04;0.100,0.100) Nc (0.06;0.100,0.100) Nc (0.08;0.100,0.100) Nc (0.09;0.100,0.100) Nc (0.13;0.100,0.100) Nc (0.19;0.100,0.100) Nc (0.11;0.100,0.100) Nc (0.25;0.100,0.120) Nc (0.35;0.100,0.140) Nc (0.38;0.100,0.180) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) 0

40 φ =120 o, Ls=480mm, tp=483 ns : =57MV/m Ea = 57 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc (0.05;0.100,0.100) Nc (0.08;0.100,0.100) Nc (0.13;0.100,0.100) Nc (0.20;0.100,0.100) Nc (0.27;0.100,0.100) Nc (0.35;0.100,0.100) Nc (0.41;0.100,0.120) Nc (0.48;0.100,0.120) Nc (0.52;0.140,0.140) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) 0

41 φ =120 o, Ls=480mm, tp=483 ns : =67MV/m Ea = 67 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc (0.47;0.100,0.100) Nc (0.50;0.100,0.100) Nc (0.56;0.100,0.100) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) 0

42 Appendix 3:Detailed parameters 150 o

43 φ =150 o, no 3TeV-constraints : =50MV/m Ea = 50 [MV/m], f = 12 [GHz], dphi = 150 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es (0.06;0.100,0.100) Es (0.10;0.100,0.100) Es (0.06;0.100,0.100) Es (0.06;0.100,0.100) Es (0.29;0.120,0.100) dT (0.24;0.100,0.100) dT (0.23;0.100,0.100) Es (0.29;0.120,0.120) dT (0.35;0.200,0.100) dT (0.35;0.220,0.100) dT (0.28;0.200,0.120) dT (0.37;0.260,0.100) dT (0.31;0.260,0.140) Ef (0.33;0.180,0.120) Es (0.18;0.220,0.260) Ef (0.25;0.100,0.220) Ef (0.23;0.140,0.260) Ef (0.22;0.160,0.300) Pa (0.56;0.300,0.100) Pa (0.59;0.280,0.100) Pa (0.53;0.320,0.140) Pa (0.52;0.340,0.160) Ef (0.51;0.360,0.200) 48

44 φ =150 o, no 3TeV-constraints : =60MV/m Ea = 60 [MV/m], f = 12 [GHz], dphi = 150 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es (0.06;0.100,0.100) Es (0.15;0.100,0.100) Es (0.15;0.100,0.100) Es (0.12;0.100,0.100) dT (0.23;0.120,0.100) dT (0.24;0.100,0.100) dT (0.21;0.120,0.120) dT (0.27;0.160,0.100) dT (0.31;0.200,0.100) dT (0.35;0.240,0.100) dT (0.32;0.240,0.120) dT (0.35;0.280,0.120) Ef (0.38;0.200,0.100) Ef (0.34;0.200,0.140) Ef (0.20;0.300,0.240) Ef (0.19;0.260,0.280) Ef (0.22;0.180,0.300) Pa (0.51;0.280,0.120) Pa (0.51;0.300,0.140) Pa (0.50;0.340,0.140) Pa (0.46;0.380,0.180) Pa (0.47;0.380,0.200) Pa (0.48;0.400,0.220) 41

45 φ =150 o, no 3TeV-constraints : =70MV/m Ea = 70 [MV/m], f = 12 [GHz], dphi = 150 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es (0.23;0.100,0.100) Es (0.20;0.100,0.100) Es (0.17;0.100,0.100) dT (0.16;0.100,0.120) Ef (0.10;0.100,0.140) dT (0.22;0.160,0.120) dT (0.29;0.200,0.100) dT (0.35;0.260,0.100) dT (0.32;0.260,0.120) dT (0.35;0.300,0.120) Ef (0.35;0.320,0.140) Ef (0.28;0.300,0.200) Ef (0.21;0.320,0.260) dT (0.20;0.360,0.280) Es (0.17;0.360,0.320) Pa (0.43;0.320,0.160) Pa (0.42;0.300,0.180) Pa (0.44;0.380,0.180) Pa (0.44;0.400,0.200) Pa (0.40;0.400,0.240) Pa (0.41;0.400,0.260) 33

46 φ =150 o, no 3TeV-constraints : =80MV/m Ea = 80 [MV/m], f = 12 [GHz], dphi = 150 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es (0.30;0.160,0.100) Es (0.16;0.140,0.180) Es (0.20;0.120,0.100) Es (0.18;0.140,0.120) Es (0.17;0.160,0.140) Es (0.11;0.160,0.180) dT (0.24;0.220,0.140) dT (0.27;0.280,0.160) dT (0.26;0.280,0.160) dT (0.29;0.320,0.160) dT (0.30;0.340,0.160) dT (0.18;0.340,0.260) dT (0.20;0.380,0.280) Es (0.16;0.380,0.320) Pa (0.21;0.260,0.280) Pa (0.35;0.380,0.220) Pa (0.35;0.400,0.220) Pa (0.35;0.400,0.260) Pa (0.36;0.400,0.280) Pa (0.33;0.380,0.320) 26

47 φ =150 o, no 3TeV-constraints : =90MV/m Ea = 90 [MV/m], f = 12 [GHz], dphi = 150 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es (0.33;0.340,0.180) Es (0.17;0.220,0.260) Es (0.17;0.220,0.200) Es (0.13;0.200,0.200) Es (0.12;0.220,0.220) dT (0.18;0.260,0.200) dT (0.20;0.300,0.200) dT (0.22;0.340,0.220) Pa (0.21;0.360,0.240) Pa (0.20;0.320,0.260) Pa (0.17;0.340,0.300) Pa (0.19;0.260,0.300) Pa (0.22;0.300,0.300) Pa (0.25;0.360,0.300) Pa (0.26;0.400,0.300) Pa (0.21;0.400,0.380) Pa (0.21;0.400,0.360) 19

48 φ =150 o, no 3TeV-constraints : =100MV/m Ea = 100 [MV/m], f = 12 [GHz], dphi = 150 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es NaN (0.00;0.000,0.000) Es (0.16;0.300,0.340) Es (0.15;0.280,0.260) Es (0.11;0.260,0.280) dT (0.13;0.280,0.260) dT (0.16;0.320,0.260) Pa (0.13;0.320,0.300) dT (0.16;0.380,0.300) Pa (0.18;0.400,0.300) Pa (0.17;0.380,0.320) Pa (0.18;0.400,0.340) Pa (0.16;0.380,0.340) Pa (0.15;0.400,0.340) Pa (0.15;0.400,0.320) Pa (0.13;0.400,0.340) 19

49 φ =150 o, Ls=230mm, tp=242 ns : =50MV/m Ea = 50 [MV/m], f = 12 [GHz], dphi = 150 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.06;0.140,0.100) Nc (0.15;0.180,0.100) Nc (0.23;0.220,0.100) Nc (0.27;0.260,0.100) Nc (0.33;0.280,0.100) Nc (0.38;0.140,0.180) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) 0

50 φ =150 o, Ls=230mm, tp=242 ns : =57MV/m Ea = 57 [MV/m], f = 12 [GHz], dphi = 150 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.120,0.120) Nc (0.15;0.180,0.100) Nc (0.21;0.220,0.100) Nc (0.27;0.260,0.100) Nc (0.32;0.280,0.100) Nc (0.38;0.180,0.140) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) 0

51 φ =150 o, Ls=230mm, tp=242 ns : =67MV/m Ea = 67 [MV/m], f = 12 [GHz], dphi = 150 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc (0.04;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.100,0.100) Nc (0.01;0.120,0.120) Nc (0.06;0.180,0.140) Nc (0.21;0.240,0.100) Nc (0.27;0.280,0.100) Nc (0.30;0.300,0.100) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) 0

52 φ =150 o, Ls=230mm, tp=242 ns : =80MV/m Ea = 80 [MV/m], f = 12 [GHz], dphi = 150 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc (0.22;0.100,0.100) Nc (0.20;0.100,0.100) Nc (0.20;0.100,0.100) Nc (0.19;0.120,0.100) Nc (0.16;0.160,0.100) Nc (0.15;0.160,0.100) Nc (0.16;0.180,0.120) Nc (0.19;0.200,0.160) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) 0

53 φ =150 o, Ls=480mm, tp=242 ns : =50MV/m Ea = 50 [MV/m], f = 12 [GHz], dphi = 150 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc (0.19;0.100,0.100) Nc (0.18;0.140,0.100) Nc (0.11;0.100,0.160) Nc (0.06;0.100,0.100) Nc (0.04;0.100,0.100) Nc (0.11;0.100,0.100) Nc (0.20;0.100,0.100) Nc (0.26;0.100,0.100) Nc (0.27;0.100,0.100) Nc (0.32;0.100,0.100) Nc (0.36;0.100,0.100) Nc NaN (0.00;0.000,0.000) Nc (0.57;0.340,0.140) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) 0

54 φ =150 o, Ls=480mm, tp=242 ns : =57MV/m Ea = 57 [MV/m], f = 12 [GHz], dphi = 150 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc (0.32;0.200,0.100) Nc (0.29;0.220,0.120) Nc (0.18;0.100,0.100) Nc (0.16;0.100,0.100) Nc (0.18;0.100,0.100) Nc (0.24;0.100,0.100) Nc (0.27;0.100,0.100) Nc (0.31;0.100,0.100) Nc (0.38;0.100,0.100) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) 0

55 φ =150 o, Ls=480mm, tp=242 ns : =67MV/m Ea = 67 [MV/m], f = 12 [GHz], dphi = 150 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc (0.46;0.100,0.100) Nc (0.42;0.100,0.100) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) 0

56 φ =150 o, Ls=480mm, tp=483 ns : =50MV/m Ea = 50 [MV/m], f = 12 [GHz], dphi = 150 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc (0.21;0.100,0.100) Nc (0.17;0.100,0.140) Nc (0.19;0.100,0.160) Nc (0.26;0.140,0.160) Nc (0.18;0.100,0.100) Nc (0.18;0.100,0.100) Nc (0.22;0.100,0.100) Nc (0.27;0.100,0.100) Nc (0.33;0.100,0.100) Nc (0.39;0.100,0.100) Nc (0.45;0.100,0.100) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) 0

57 φ =150 o, Ls=480mm, tp=483 ns : =57MV/m Ea = 57 [MV/m], f = 12 [GHz], dphi = 150 [deg], /lambda = frep = [Hz], Ltotal = e+038 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] /l Type Eff Lbx*10^34 N*10^9 L/N*Eff In.Cost Es_max dT_max Pin tp tr Nb Ns (da/a; d1/h, d2/h) Nc [%] [1/m^2] [a.u.] [a.u.] [MV/m] [K] [MW] [ns] [ns] Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc (0.50;0.100,0.100) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) 0


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