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TDI impedance and power loss O. Aberle, F. Caspers, A. Grudiev, E. Metral, N. Mounet, B. Salvant.

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Presentation on theme: "TDI impedance and power loss O. Aberle, F. Caspers, A. Grudiev, E. Metral, N. Mounet, B. Salvant."— Presentation transcript:

1 TDI impedance and power loss O. Aberle, F. Caspers, A. Grudiev, E. Metral, N. Mounet, B. Salvant

2 Context TDI power loss Follow up of E. Metral’s talk at LCE meeting 11/06/2004 for Flat chamber with large aspect ratio  Form factor for longitudinal = 1 Formula for multilayer round pipe without approximation inner radius=4.6 mm for  y =43 m Inner radius=7.7 mm for  y =118 m 1 st Block (2.8 m) Vacuum hBN (54 mm) Ti 3  m 2 nd Block (0.6 m) Vacuum Al (54 mm) Cu 10  m 3 rd Block (0.7 m) Vacuum Cu (54 mm)

3 Material properties Copper  DC = 17 10^-9 Ω.m  rel = 1  rel = 1  H 1 = 0 relaxationTime= 27 10^-15 s Titanium  DC = 58 10^-8 Ω.m  rel = 1  rel = 1  H 1 = 0 relaxationTime= 0 Hexagonal Boron Nitride (hBN)  DC = 4 10^12 Ω.m  rel = 5  rel = 1  H 1 = 0 relaxationTime= 0 Aluminum  DC = 28 10^-9 Ω.m  rel = 1  rel = 1  H 1 = 0 relaxationTime= 0

4 Total longitudinal impedance (  y =43 m) Linear scale Log scale Losses occur mainly in the first block Ztotal 1 st block (Ti+hBN+vacuum) 2 nd block (Cu+Al+vacuum) 3 rd block (Cu+vacuum) Z(2 nd block)~Z(3 rd block) Ztotal~Z(1 st block) P loss (1 st block) ~ 162 W P loss (2 nd block) ~ 0.6 W P loss (3 rd block) ~ 0.7 W P loss (total) ~ 163 W

5 Total longitudinal impedance (  y =118 m) Linear scale Log scale Losses occur mainly in the first layer Ztotal 1 st block (Ti+hBN+vacuum) 2 nd block (Cu+Al+vacuum) 3 rd block (Cu+vacuum) Z(2 nd block)~Z(3 rd block) Ztotal~Z(1 st block) P loss (1 st block) ~97 W P loss (2 nd block) <1 W P loss (total) ~ 98 W

6 1st block (Ti-hBN-Vacuum)  Z 1 layer (Ti) 2 layers (Ti+hBN) 3 layers (Ti+hBN+vacuum) Infinite thick wall (Ti)

7 Power loss in the first block From F. Ruggiero, Single-beam collective effects in the LHC CERN-SL-95-09-AP (1995) Formula assumes a gaussian bunch for P loss = 163 W P loss ~ 98 Wfor 1 layer (Ti) 2 layers (Ti+hBN) 3 layers (Ti+hBN+vacuum) Infinite thick wall (Ti) Significant losses in the hBN?

8 Losses in the hBN 1 layer (Ti) 2 layers (Ti+hBN) 3 layers (Ti+hBN+vacuum) Infinite thick wall (Ti) 2 layers (Ti+vacuum) At f=10 10 Hz, the skin depth in titanium is ~ 3  m… A single layer of titanium surrounded with vacuum leads to P loss ~ 0.04 W This 3  m layer surrounded with 54 mm of hBN leads to P loss ~ 162 W This means that all the power (162 W) is lost in the hBN.

9 Effect of hBN conductivity on impedance of the 1 st block  (hBN)=8 10 12 Ω.m  (hBN)=4 10 12 Ω.m  (hBN)=2 10 12 Ω.m  No effect of hBN conductivity on the power loss (in this 10 12 Ω.m range…)

10 Effect of hBN permittivity on impedance of the 1 st block  r (hBN)=1  r (hBN)=1.1  r (hBN)=2  r (hBN)=5  strong effect of hBN permittivity on the power loss, but only if  r ~ 1. If  r >2, the effect is small, as Alexej already observed

11 Conclusion Significant power loss dissipated in the hBN (162 W)  r = 1 leads to suppressing almost all the losses in the hBN (and therefore everywhere). However  r >2 for instance f leads to very small changes (P=160W instead of 163W) for P loss ~ 163 W P loss ~ 98 Wfor In surprising agreement with previous estimates (Ploss ~ 165 W and Ploss ~ 100 W )

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