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Muon Collider Design Workshop, Jefferson Lab 112/09/2008 Muons, Inc. Loaded Pillbox Cavity Milorad Popovic (with Mike, Chuck, Katsuya, Al and Rol)

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Presentation on theme: "Muon Collider Design Workshop, Jefferson Lab 112/09/2008 Muons, Inc. Loaded Pillbox Cavity Milorad Popovic (with Mike, Chuck, Katsuya, Al and Rol)"— Presentation transcript:

1 Muon Collider Design Workshop, Jefferson Lab 112/09/2008 Muons, Inc. Loaded Pillbox Cavity Milorad Popovic (with Mike, Chuck, Katsuya, Al and Rol)

2 Motivation Muon Collider Design Workshop, Jefferson Lab 212/09/2008 Muons, Inc. To fit pressurized cavities in HCC, size of cavity has to be reduced 800 MHz (from Katsuya) Maximum RF cavity radius = 0.08 m, (pillbox cavity 0.143) Radius of effective electric field (95 % from peak) = 0.03 m 400 MHz: Maximum RF radius = 0.16 m (pillbox cavity 0.286) Radius of effective electric field = 0.06 m Optimum electric field gradient = 16 MV/m For Pill Box Cavity, resonant frequency is

3 Dielectric Loaded RF Cavities New type of cavity is suggested. The idea came from conversation with Chuck and Yonehara. I was told that Al suggested something like this. 12/09/20083Muon Collider Design Workshop, Jefferson Lab Muons, Inc. Cu/Steel ceramics Vaccum/H/He

4 SuperFish Model Muon Collider Design Workshop, Jefferson Lab412/09/2008 Muons, Inc.

5 400MHz Cavity Muon Collider Design Workshop, Jefferson Lab512/09/2008 Muons, Inc.

6 400MHz Cavity Muon Collider Design Workshop, Jefferson Lab612/09/2008 Muons, Inc. Ez at center of cavity R(cm)

7 361MHz Cavity Muon Collider Design Workshop, Jefferson Lab712/09/2008 Muons, Inc.

8 HCC Concept Muon Collider Design Workshop, Jefferson Lab812/09/2008 Muons, Inc. Central Orbit and Beam EnvelopeSet of Coils Basic Building Block can be Cavity + Coil

9 MANX + RF ? Muon Collider Design Workshop, Jefferson Lab912/09/2008 Muons, Inc. Detector s Cavity + Coil Cryostat Vessel Feedthrough s Power in Signals out MICE will have ~?MV @200MHz

10 Other Applications Muon Collider Design Workshop, Jefferson Lab1012/09/2008 Muons, Inc. May be we can use this type of cavity for Neuffer’s Phase Rotation Canal. This was Cary Yoshikawa suggestion. The canal needs many cavities in range from ~300 to 200MHz. We can use, let say two sizes of Pill Box Cavity (same size different dielectric!) and adjust frequency in between using different iner radius, re-entrant nose cones!

11 Cavities for Neutrino Factory Muon Collider Design Workshop, Jefferson Lab1112/09/2008 Muons, Inc. Schematic of the Neutrino Factory front-end transport system. Initial drift (56.4 m), the varying frequency buncher (31.5m), The phase-energy (  -  E) rotator (36m), a cooling section. (A 75m cooling length may be optimal.) ParameterDriftBuncherRotatorCooler Length (m)56.431.53675 Focusing (T)2222.5 (ASOL) Rf frequency (MHz)360 to 240240 to 202201.25 Rf gradient (MV/m)0 to 151516 Total rf voltage (MV)126360800

12 Muon Collider Design Workshop, Jefferson Lab1212/09/2008 Muons, Inc. What is Next FIRM NAME: Muons, Inc. RESEARCH INSTITUTION: Fermi National Accelerator Laboratory Milorad Popovic, subgrant PI ADDRESS: 552 N. Batavia Ave. Batavia, IL 60510 ADDRESS: Phase I-SBIR/STTR Fiscal Year 2009 (All information provided on this page is subject to release to the public.) NAME of PRINCIPAL INVESTIGATOR: Michael Neubauer PHONE NUMBER: (707) 360-5038 PROJECT TITLE: 46a Dielectric Loaded RF Cavities Loss tangent tan d = 1/Q dielectric -1/Q air Loss tangents of specially formulated alumina with TiO 2 have been reported to be close to sapphire at 1e-5. So it is easy to see that today’s ceramics may be used in this novel idea without suffering a great deal in cavity Q at low frequencies. The other problem with ceramics in vacuum with beams is that of surface charging of the ceramic. And again, much work has been done in coatings, from Chromium Oxide to TiN to, more recently, ion implantation Air gap between the dielectric and metal plates will be one of the issues that must be tested experimentally SBIR Main Issues

13 Muon Collider Design Workshop, Jefferson Lab1312/09/2008 Muons, Inc. May be ceramics can play additional role, making volume of Hydrogen smaller and making cavity stronger so the walls do not have to be as thick as without ceramics. RF power can be fed using loop between two rings. Cavities can be put next each other so the side wall can be made thin May be we should do experiment in the MTA, with solenoid!

14 Test Cavity 12/09/200814 Muon Collider Design Workshop, Jefferson Lab Muons, Inc.

15 Cavity + Coil Compact, Tunable RF Cavities1512/09/2008 Muons, Inc.

16 Model Cavity Muon Collider Design Workshop, Jefferson Lab1612/09/2008 Muons, Inc. 15cm 6.7cm Copper 9cm

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