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Beam Loss in the Extraction Line for 14 mrad Crossing Angle A.Drozhdin, N.Mokhov, X.Yang

Beam Loss in the Extraction Line for 14 mrad Crossing Angle A.Drozhdin, N.Mokhov, X.Yang. February 28, 2006 A.Drozhdin, N.Mokhov, X.Yang. Beta and vertical dispersion (top) in the extraction beam

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Beam Loss in the Extraction Line for 14 mrad Crossing Angle A.Drozhdin, N.Mokhov, X.Yang

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  1. Beam Loss in the Extraction Line for 14 mrad Crossing AngleA.Drozhdin, N.Mokhov, X.Yang

  2. February 28, 2006 A.Drozhdin, N.Mokhov, X.Yang Beta and vertical dispersion (top) in the extraction beam line for 1000 GeV CM, and aperture for photon angle 1.25 mrad (middle) and 0.75 mrad (bottom).

  3. February 28, 2006 A.Drozhdin, N.Mokhov, X.Yang In the case of 0.75 mrad photon aperture, disrupted beam (file beam1 and 2 from cs21_dy100_hs) with vertical offset at IP of 100 nm (green), 3 sigma beam (blue) and beamstrahlung photon (file photon.dat from cs21_dy100_hs) beam (red) are printed out at DEXQ1B, DEXQ2D, BENDS, CBVEX4E, CBVEX8E, CBVEX1P, CBVEX2P, and CBVEX4P in the order of top to bottom and left to right.

  4. February 28, 2006 A.Drozhdin, N.Mokhov, X.Yang In the case of 1.25 mrad photon aperture, disrupted beam (file beam1 and 2 from cs21_dy100_hs) with vertical offset at IP of 100 nm (green), 3 sigma beam (blue) and beamstrahlung photon (file photon.dat from cs21_dy100_hs) beam (red) are printed out at DEXQ1B, DEXQ2D, BENDS, CBVEX4E, CBVEX8E, CBVEX1P, CBVEX2P, and CBVEX4P in the order of top to bottom and left to right.

  5. February 28, 2006 A.Drozhdin, N.Mokhov, X.Yang In the case of 0.75 mrad photon aperture, disrupted beam (file beam1 and 2 from cs21_dy100_hs) with vertical offset at IP of 100 nm (green) and synchrotron radiated photons (red) from the disrupted beam are printed out at DEXQ1B, DEXQ2D, BENDS, CBVEX4E, CBVEX8E, CBVEX1P, CBVEX2P, and CBVEX4P in the order of top to bottom and left to right.

  6. February 28, 2006 A.Drozhdin, N.Mokhov, X.Yang In the case of 1.25 mrad photon aperture, disrupted beam (file beam1 and 2 from cs21_dy100_hs) with vertical offset at IP of 100 nm (green) and synchrotron radiated photons (red) from the disrupted beam are printed out at DEXQ1B, DEXQ2D, BENDS, CBVEX4E, CBVEX8E, CBVEX1P, CBVEX2P, and CBVEX4P in the order of top to bottom and left to right.

  7. February 28, 2006 A.Drozhdin, N.Mokhov, X.Yang The electron and photon loss at the “artificial” collimators located at the entrance and exit to chicane bends shown in Figs. 8-13 are not exist in reality. These collimators were included to allow calculation of loss in bends using DIMAD.

  8. February 28, 2006 A.Drozhdin, N.Mokhov, X.Yang Primary beam loss distribution along the extraction line prior to collimators. Top: for beam without vertical offset at IP (file tail1 and 2 from cs15_hs) for 0.75 mrad (left) and 1.25 mrad (right) photon aperture, and bottom: for beam with vertical offset at IP of 120 nm (file beam1 and 2 from cs15_dy120_hs) for 0.75 mrad (left) and 1.25 mrad (right) photon aperture. Beam losses at the collimators are calculated using beam1 and 2. All elements of beam line downstream of IP, including collimators, have round or elliptical aperture.

  9. February 28, 2006 A.Drozhdin, N.Mokhov, X.Yang Primary beam loss distribution along the extraction line prior to collimators. Top: for beam without vertical offset at IP (file tail1 and 2 from cs21_hs) for 0.75 mrad (left) and 1.25 mrad (right) photon aperture, and bottom: for beam with vertical offset at IP of 100 nm (file tail1 and 2 from cs21_dy100_hs) for 0.75 mrad (left) and 1.25 mrad (right) photon aperture. Beam losses at the collimators are calculated using beam1 and 2. All elements of beam line downstream of IP, including collimators, have round or elliptical aperture.

  10. February 28, 2006 A.Drozhdin, N.Mokhov, X.Yang Primary beam loss distribution along the extraction line prior to collimators. Top: for beam without vertical offset at IP (file tail1 and 2 from cs25_hs) for 0.75 mrad (left) and 1.25 mrad (right) photon aperture, and bottom: for beam with vertical offset at IP of 80 nm (file tail1 and 2 from cs25_dy80_hs) for 0.75 mrad (left) and 1.25 mrad (right) photon aperture. Beam losses at the collimators are calculated using beam1 and 2. All elements of beam line downstream of IP, including collimators, have round or elliptical aperture.

  11. February 28, 2006 A.Drozhdin, N.Mokhov, X.Yang Synchrotron radiation loss distribution along the extraction line prior to collimators. Top: for beam without vertical offset at IP (file beam1 and 2 from cs15_hs) for 0.75 mrad (left) and 1.25 mrad (right) photon aperture, and bottom: for beam with vertical offset at IP of 120 nm (file beam1 and 2 from cs15_dy120_hs) for 0.75 mrad (left) and 1.25 mrad (right) photon aperture. All elements of beam line downstream of IP, including collimators, have round or elliptical aperture.

  12. February 28, 2006 A.Drozhdin, N.Mokhov, X.Yang Synchrotron radiation loss distribution along the extraction line prior to collimators. Top: for beam without vertical offset at IP (file beam1 and 2 from cs21_hs) for 0.75 mrad (left) and 1.25 mrad (right) photon aperture, and bottom: for beam with vertical offset at IP of 100 nm (file beam1 and 2 from cs21_dy100_hs) for 0.75 mrad (left) and 1.25 mrad (right) photon aperture. All elements of beam line downstream of IP, including collimators, have round or elliptical aperture.

  13. February 28, 2006 A.Drozhdin, N.Mokhov, X.Yang Synchrotron radiation loss distribution along the extraction line prior to collimators. Top: for beam without vertical offset at IP (file beam1 and 2 from cs25_hs) for 0.75 mrad (left) and 1.25 mrad (right) photon aperture, and bottom: for beam with vertical offset at IP of 80 nm (file beam1 and 2 from cs25_dy80_hs) for 0.75 mrad (left) and 1.25 mrad (right) photon aperture. All elements of beam line downstream of IP, including collimators, have round or elliptical aperture.

  14. February 28, 2006 A.Drozhdin, N.Mokhov, X.Yang Energy spectrum of synchrotron radiation photons lost in the region of prior to collimators in the extraction line for 0.75 mrad photon aperture in two cases of beam1 and beam2 from cs15 (top) and c25 (bottom).

  15. February 28, 2006 A.Drozhdin, N.Mokhov, X.Yang Energy (top) and angular spectrum of initial particles of beam 1 and 2, for files from c25_hs (left) and c25_dy80_hs (right).

  16. February 28, 2006 A.Drozhdin, N.Mokhov, X.Yang Lost particles' (including loss on final collimators) energy (top) and angular (middle and bottom) spectrum at IP for 14 mrad crossing angle extraction line with 0.75 mrad photon aperture. Initial particles are: beam 1 and 2, for files from c21_hs, c21_dy100_hs, c25_hs, and c25_dy80_hs.

  17. February 28, 2006 A.Drozhdin, N.Mokhov, X.Yang Initial particles of beam 1 and 2 for files from c25_hs (red). In the left, particles lost from IP to beam dump for extraction line with 0.75 mrad aperture (green), P vs. XS (top), P vs. YS (middle), and XS vs. YS (bottom); and in the right, lost particles from IP to upstream of collimator 1 (green), P vs. XS (top), P vs. YS (middle), and XS vs. YS (bottom).

  18. February 28, 2006 A.Drozhdin, N.Mokhov, X.Yang Initial particles of beam 1 and 2 for files from c25_dy80_hs (red). In the left, particles lost from IP to beam dump for extraction line with 0.75 mrad photon aperture (green), P vs. XS (top), P vs. YS (middle), and XS vs. YS (bottom); in the right, lost particles from IP to upstream of collimator 1 (green), P vs. XS (top), P vs. YS (middle), and XS vs. YS (bottom).

  19. February 28, 2006 A.Drozhdin, N.Mokhov, X.Yang For extraction line with 0.75 mrad photon aperture, initial 100,000 particles at IP are randomly distributed in P (0-500GeV), XS, and YS. σXS is a constant of 0.2 mrad, and σYS is varied among 0.0333 mrad (red), 0.167 mrad (green), 0.333 mrad (blue), and 0.667 mrad (magenta). Histograms of normalized lost-particle density, including loss on final collimators, (probability for particle getting lost) in P, XS, and YS are at the top, middle, and the bottom correspon-dingly.

  20. February 28, 2006 A.Drozhdin, N.Mokhov, X.Yang For extraction line with 0.75 mrad photon aperture, initial 100,000 particles are randomly distributed in P (0-500GeV), XS and YS. σXS is a constant of 0.167 mrad, and σYS is varied among 0.2 mrad (red), 0.333 mrad (green), and 0.667 mrad (blue). Histogram of normalized lost-particle density , including loss on final collimators, (probability for particle getting lost) in P, XS, and YS are at the top, the middle, and the bottom correspondingly.

  21. February 28, 2006 A.Drozhdin, N.Mokhov, X.Yang Initial 100,000 particles being randomly distributed in P (0-500GeV), XS (σXS=0.333mrad), and YS (σXS=0.333mrad) (red). In the left, particles lost from IP to beam dumpfor extraction line with 0.75 mrad photon aperture (green), P vs. XS (top), P vs. YS (middle), and XS vs. YS (bottom); in the right, lost particles from IP to upstream of collimator 1 (green), P vs. XS (top), P vs. YS (middle), and XS vs. YS (bottom).

  22. February 28, 2006 A.Drozhdin, N.Mokhov, X.Yang Number of lost particles vs. vertical angular kick at IP to both beam 1 and 2 (red), positive vertical kick only applied to beam 1 (green), and vertical kick applied to both beam 1 and 2 in different directions (positive kick to beam 1, negative kick to beam 2), for extraction line with 0.75 mrad photon aperture. Initial particles are: beam 1 and 2, for files from c25_dy80_hs.

  23. February 28, 2006 A.Drozhdin, N.Mokhov, X.Yang Disrupted beam power loss in the extraction line for 0.75 mrad photon aperture model. All elements of beam line downstream of IP, including collimators, have round or elliptical aperture.

  24. February 28, 2006 A.Drozhdin, N.Mokhov, X.Yang Disrupted beam power loss in the extraction line for 1.25 mrad photon aperture model. All elements of beam line downstream of IP, including collimators, have round or elliptical aperture.

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