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CLIC structure optimization results (all data) 28/08/07 A. Grudiev.

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1 CLIC structure optimization results (all data) 28/08/07 A. Grudiev

2 New input from Daniel for d/h=0.1 f[GHz] /l N[10 9 ] σ z [μm] da/a L total [1/m2] L 1 [1/m2] e e e e e e e e e e e e e e e e e e e e e e e e e e e e e e e e e e e e e e e e e e e e e e e e e e e e+33

3 /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] (0.08;0.120,0.120) (0.15;0.140,0.140) (0.27;0.140,0.140) (0.36;0.120,0.120) (0.29;0.180,0.180) (0.33;0.200,0.200) (0.36;0.180,0.180) (0.33;0.240,0.240) (0.33;0.260,0.260) (0.37;0.260,0.260) (0.42;0.280,0.280) (0.35;0.320,0.320) (0.42;0.300,0.300) 30 Ls= mm; 21 str. d1=d2 Ns = free Wt = 10V/pC Esurf<300MV/m; no tp dependence dT<60K Max(L/P) L1 = 3.3e38; [Hz/m^2] 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] Inv. Cost = [a.u.], 10-years El. Cost = [a.u.]

4 /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] (0.04;0.100,0.100) (0.11;0.100,0.100) (0.19;0.100,0.100) (0.32;0.100,0.100) (0.38;0.120,0.120) (0.31;0.160,0.160) (0.36;0.180,0.180) (0.40;0.200,0.200) (0.39;0.240,0.240) (0.40;0.240,0.240) (0.43;0.300,0.300) (0.39;0.280,0.280) (0.42;0.300,0.300) 30 Ls= mm; 21 str. d1=d2 Ns = free Wt = 10V/pC Esurf<300MV/m; no tp dependence dT<60K Min(Cost) L1 = 3.3e38; [Hz/m^2] Ea = 100 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+039 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] Inv. Cost = [a.u.], 10-years El. Cost = [a.u.]

5 Ls= mm; 21 str. Ns = free Wt = 10V/pC Esurf<300MV/m; no t p dependence dT<60K Max(L/P) L1 = 3.3e38; [Hz/m^2] /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] (0.08;0.120,0.120) (0.14;0.160,0.140) (0.32;0.220,0.120) (0.43;0.260,0.100) (0.43;0.320,0.100) (0.51;0.400,0.100) (0.47;0.400,0.140) (0.52;0.400,0.140) (0.54;0.400,0.160) (0.53;0.380,0.200) (0.48;0.360,0.220) (0.36;0.320,0.340) (0.35;0.260,0.340) 27 Ea = 100 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+039 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] Inv. Cost = [a.u.], 10-years El. Cost = [a.u.]

6 Ls= mm; 21 str. Ns = free Wt = 10V/pC Esurf<300MV/m; no t p dependence dT<60K Min(Cost) L 1 = 3.3e38; [Hz/m^2] /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] (0.04;0.100,0.100) (0.11;0.100,0.100) (0.19;0.120,0.100) (0.34;0.120,0.100) (0.37;0.140,0.100) (0.42;0.200,0.100) (0.47;0.260,0.100) (0.51;0.320,0.100) (0.40;0.260,0.180) (0.52;0.400,0.120) (0.50;0.400,0.160) (0.37;0.260,0.300) (0.35;0.260,0.340) 27 Ea = 100 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = , frep = [Hz], Ltotal = e+039 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] Inv. Cost = [a.u.], 10-years El. Cost = [a.u.]

7 Ls= mm; 4 str. Ns = free Wt = 10V/pC Esurf<300MV/m; no t p dependence dT<60K Max(L/P) L1 = 3.3e38; [Hz/m^2] 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] Inv. Cost = [a.u.], 10-years El. Cost = [a.u.] /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] Ef (0.05;0.100,0.120) dT (0.20;0.140,0.140) dT (0.30;0.200,0.120) Ef (0.42;0.240,0.100) dT (0.45;0.320,0.100) dT (0.52;0.400,0.100) dT (0.41;0.400,0.160) Ef (0.56;0.400,0.140) Ef (0.57;0.400,0.160) Ef (0.54;0.400,0.220) Pa (0.43;0.360,0.200) Pa (0.36;0.300,0.280) Pa (0.32;0.260,0.340) 18

8 Ls= mm; 4 str. Ns = free Wt = 10V/pC Esurf<300MV/m; no t p dependence dT<60K Min(Cost) L1 = 3.3e38; [Hz/m^2] Ea = 100 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+039 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] Inv. Cost = [a.u.], 10-years El. Cost = [a.u.] /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] dT (0.23;0.100,0.100) dT (0.22;0.100,0.100) dT (0.19;0.100,0.100) Ef (0.32;0.100,0.100) Ef (0.37;0.140,0.100) Ef (0.41;0.220,0.100) Ef (0.47;0.260,0.100) Ef (0.52;0.320,0.100) Ef (0.58;0.400,0.100) Ef (0.52;0.380,0.160) dT (0.45;0.400,0.100) Pa (0.44;0.380,0.160) Pa (0.43;0.360,0.200) 28

9 Ls=229mm; 1 str.; Nc=26 Ns = free Wt = 10V/pC Esurf<300MV/m; no t p dependence dT<60K Max(L/P) L1 = 3.3e38; [Hz/m^2] 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] Inv. Cost = [a.u.], 10-years El. Cost = [a.u.] /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 (0.23;0.100,0.100) Nc (0.33;0.100,0.100) Nc (0.41;0.160,0.100) Nc (0.48;0.200,0.100) Nc (0.55;0.260,0.100) Nc (0.59;0.360,0.100) Nc (0.58;0.380,0.120) Nc (0.55;0.380,0.140) Nc (0.41;0.260,0.220) Nc (0.52;0.400,0.180) Nc (0.45;0.340,0.240) Nc (0.36;0.260,0.320) Nc (0.35;0.260,0.360) 26

10 Ls=229mm; 1 str.; Nc=26 Ns >=6 Wt = 10V/pC Esurf<300MV/m; no t p dependence dT<60K Max(L/P) L1 = 3.3e38; [Hz/m^2] 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] Inv. Cost = [a.u.], 10-years El. Cost = [a.u.] /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 (0.23;0.100,0.100) Nc (0.33;0.120,0.100) Nc (0.41;0.180,0.100) Nc (0.48;0.220,0.100) Nc (0.55;0.280,0.100) Nc (0.58;0.320,0.100) Nc (0.58;0.380,0.120) Nc (0.55;0.380,0.140) Nc (0.41;0.260,0.220) Nc (0.52;0.400,0.180) Nc (0.45;0.340,0.240) Nc (0.36;0.260,0.320) Nc (0.35;0.260,0.360) 26

11 Ls=229mm; 1 str.; Nc=26 Ns >=8 Wt = 10V/pC Esurf<300MV/m; no t p dependence dT<60K Max(L/P) L1 = 3.3e38; [Hz/m^2] Ea = 100 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+039 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] Inv. Cost = [a.u.], 10-years El. Cost = [a.u.] /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 (0.23;0.100,0.100) Nc (0.33;0.160,0.100) Nc (0.41;0.200,0.100) Nc (0.48;0.240,0.100) Nc (0.55;0.300,0.100) Nc (0.54;0.340,0.120) Nc (0.56;0.360,0.120) Nc (0.58;0.380,0.120) Nc (0.54;0.400,0.160) Nc (0.52;0.400,0.180) Nc (0.45;0.340,0.240) Nc (0.36;0.260,0.320) Nc (0.35;0.260,0.360) 26

12 Ls=180mm; 1 str.; Nc=20 Ns >=6 Wt = 10V/pC Esurf<300MV/m; no t p dependence dT<60K Max(L/P) L1 = 3.3e38; [Hz/m^2] Ea = 100 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+039 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] Inv. Cost = [a.u.], 10-years El. Cost = [a.u.] /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 (0.17;0.120,0.120) Nc (0.22;0.160,0.140) Nc (0.29;0.220,0.140) Nc (0.34;0.260,0.160) Nc (0.44;0.320,0.120) Nc (0.44;0.360,0.140) Nc (0.47;0.400,0.140) Nc (0.42;0.400,0.180) Nc (0.33;0.280,0.240) Nc (0.31;0.280,0.280) Nc (0.43;0.360,0.220) Nc (0.35;0.320,0.300) Nc (0.34;0.280,0.340) 20

13 Ls=180mm; 1 str.; Nc=20 Ns >=8 Wt = 10V/pC Esurf<300MV/m; no t p dependence dT<60K Max(L/P) L1 = 3.3e38; [Hz/m^2] Ea = 100 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+039 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] Inv. Cost = [a.u.], 10-years El. Cost = [a.u.] /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 (0.23;0.140,0.100) Nc (0.22;0.160,0.140) Nc (0.26;0.200,0.160) Nc (0.28;0.240,0.180) Nc (0.31;0.280,0.180) Nc (0.32;0.320,0.200) Nc (0.39;0.380,0.180) Nc (0.38;0.380,0.200) Nc (0.38;0.400,0.220) Nc (0.31;0.280,0.280) Nc (0.43;0.360,0.220) Nc (0.35;0.320,0.300) Nc (0.34;0.280,0.340) 20

14 Ls=229mm; 1 str.; Nc=26 Ns >=6 Wt = 5V/pC Esurf<300MV/m; no t p dependence dT<60K Max(L/P) L1 = 3.3e38; [Hz/m^2] 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] Inv. Cost = [a.u.], 10-years El. Cost = [a.u.] /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 (0.23;0.100,0.100) Nc (0.33;0.120,0.100) Nc (0.41;0.180,0.100) Nc (0.48;0.220,0.100) Nc (0.55;0.280,0.100) Nc (0.47;0.220,0.100) Nc (0.47;0.280,0.160) Nc (0.42;0.280,0.200) Nc (0.37;0.180,0.240) Nc (0.35;0.180,0.280) Nc (0.32;0.140,0.340) Nc (0.35;0.240,0.360) Nc (0.34;0.220,0.360) 26

15 Ls=229mm; 1 str.; Nc=26 Ns >=6 Wt = 10V/pC Esurf<220MV/m; no t p dependence dT<60K Max(L/P) L1 = 3.3e38; [Hz/m^2] Ea = 100 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+039 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] Inv. Cost = [a.u.], 10-years El. Cost = [a.u.] /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 NaN (0.00;0.000,0.000) Nc NaN (0.00;0.000,0.000) Nc (0.13;0.340,0.320) Nc (0.15;0.380,0.300) 26

16 Ls=229mm; 1 str.; Nc=26 Ns >=6 Wt = 10V/pC Esurf<260MV/m; no t p dependence dT<60K Max(L/P) L1 = 3.3e38; [Hz/m^2] 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] Inv. Cost = [a.u.], 10-years El. Cost = [a.u.] /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 (0.33;0.120,0.100) Nc (0.41;0.180,0.100) Nc (0.46;0.260,0.100) Nc (0.48;0.340,0.100) Nc (0.40;0.340,0.120) Nc (0.36;0.360,0.140) Nc (0.33;0.340,0.200) Nc (0.34;0.360,0.220) Nc (0.32;0.360,0.280) Nc (0.30;0.340,0.280) Nc (0.27;0.320,0.320) Nc (0.28;0.360,0.300) 26

17 Ls=229mm; 1 str.; Nc=26 Ns >=6 Wt = 10V/pC Esurf<260MV/m; no t p dependence dT<36K Max(L/P) L1 = 3.3e38; [Hz/m^2] Ea = 100 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+039 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] Inv. Cost = [a.u.], 10-years El. Cost = [a.u.] /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 (0.25;0.100,0.100) Nc (0.28;0.140,0.100) Nc (0.32;0.180,0.100) Nc (0.29;0.200,0.120) Nc (0.29;0.240,0.140) Nc (0.29;0.260,0.160) Nc (0.29;0.300,0.160) Nc (0.29;0.320,0.200) Nc (0.32;0.360,0.200) Nc (0.28;0.360,0.240) Nc (0.26;0.320,0.280) Nc (0.28;0.360,0.280) 26

18 Ls= mm; 4 str. Ns = free Wt = 10V/pC Esurf<260MV/m; no t p dependence dT<36K Max(L/P) L1 = 3.3e38; [Hz/m^2] /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] dT (0.19;0.100,0.100) dT (0.16;0.100,0.100) dT (0.19;0.120,0.100) dT (0.25;0.160,0.100) dT (0.23;0.180,0.120) dT (0.26;0.220,0.140) dT (0.22;0.240,0.180) dT (0.27;0.280,0.180) dT (0.28;0.320,0.200) dT (0.31;0.360,0.200) dT (0.25;0.380,0.260) dT (0.33;0.400,0.200) dT (0.27;0.400,0.220) 26 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] Inv. Cost = [a.u.], 10-years El. Cost = [a.u.]

19 Ls= mm; 4 str. Ns = free Wt = 10V/pC Esurf<260MV/m; no t p dependence dT<36K Min(Cost) L1 = 3.3e38; [Hz/m^2] Ea = 100 [MV/m], f = 12 [GHz], dphi = 120 [deg], /lambda = frep = [Hz], Ltotal = e+039 [Hz/m^2], sigma_z = [um] Pbeam = [MW/beam], Pin = [MW/linac], Ep = [kJ/linac] Inv. Cost = [a.u.], 10-years El. Cost = [a.u.] /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] dT (0.23;0.100,0.100) dT (0.26;0.120,0.100) Es (0.25;0.120,0.100) dT (0.29;0.160,0.100) Ef (0.29;0.200,0.100) Ef (0.28;0.240,0.100) dT (0.30;0.260,0.160) Ef (0.31;0.300,0.180) dT (0.30;0.320,0.200) dT (0.33;0.360,0.200) dT (0.28;0.360,0.220) dT (0.33;0.400,0.200) dT (0.30;0.400,0.200) 28


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