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1 Simulation of RF background in MICE Rikard Sandström University of Geneva NuFact’04 Osaka.

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Presentation on theme: "1 Simulation of RF background in MICE Rikard Sandström University of Geneva NuFact’04 Osaka."— Presentation transcript:

1 1 Simulation of RF background in MICE Rikard Sandström University of Geneva NuFact’04 Osaka

2 2 Introduction Tracker

3 3 Assumptions Amount of background –MICE proposal says 3 GHz (3 per ns) of RF induced electrons hit one of the outer absorbers. –Good muon rate = 600 kHz (600 per ms) –(For technical reasons one event = 1 muon + 5000 e-) Position of emitters –The z-positions of the emitters are set to be at the beryllium windows z = -1849, -1379.72, -916.45, -394.76, 434.55, 900.8, 1367.3, 1833.55 [mm] –Transverse distribution is uniform over the beryllium windows. Cuts –0.5 mm maximum step length was used in absorbers and absorber windows for precision. –Energy cuts are Geant4 defaults, for example 1keV for discrete ionization. Simulation environment –G4MICE was used, which is based on GEANT4.5.2.p02 (October -03 release)

4 4 Two different methods Two different methods (A,B) have been used to simulate the RF background problem. Method A tries to simulate emission from the surface and acceleration in E&B fields. Close to physical reality, but some problems. Method B generates a spectrum of e- at the exit of cavities. More assumptions, but works.

5 5 Method A 1250 e- per mu+ were generated at 8 circular disks, corresponding to cavity boundaries. The electrons were given an initial direction towards closest tracker, and a random initial kinetic energy of 1-3 keV. The electrons were accelerated in the fields using Geant4 until they hit an object and interacted via other processes.

6 6 Method A Interesting issues: The spatial position of emitting sites on the cavities is nontrivial. The MICE proposal gives 3GHz of electrons reaching the absorber, (projected from 805 MHz measurements in lab G) but it does not say how many electrons are emitted from the surfaces. »Hence more knowledge of the physics of the emission is required. Trivial technical problem: the phase of the RF field in different cavities is hard to set correctly, so the electrons did not gain the maximum energy possible. –Hopefully this can be solved very soon.

7 7 Method B Two emitting disks where used, positioned inside the last cavity up- & downstream respectively. At each disk four energy peaks are used for setting the initial kinetic energy of the RF electrons. They correspond to the energy gain of an integer number of traversed cavities, given by the default value of G4MICE parameter. (E = 2.775, 5.55, 8.324, 11.1 [MeV], weighted equally.) –This is pessimistic, since the field is synchronized for muons, not electrons! The results presented later correspond to Method B, but only looking at the outermost upstream absorber window, and the upstream tracker. (worst case…) mu+ e-

8 8 Results - Introduction The resulting particles were categorized and colour coded according to their position of creation and destruction. ”Confined”: The particle was created inside the region of interest and was destroyed there as well. ”Emigrant”: The particle was created inside the region of interest and left the volume. ”Immigrant”: The particle was created outside the region of interest and was destroyed inside the region. ”Vagabond”: The particle was created outside the region of interest and left the volume.

9 9 Electrons leaving absorber 0.9% of 200 000 e- (40 mu+) Min E-loss for the 11.1 MeV peak ~ 8.7 MeV

10 10 Electrons in upstream TPG High energy electrons coming from RF Some are later scattered back into the tracker again High-E e- coming from the RF e- from conversions

11 11 Comment on results, electrons Running 20000 muons without RF background the following results were found: This should be compared with the RF background turned on: 102 kHz entered from target side Small contribution Dramatic change! ~20 MHz

12 12 Photons leaving the absorber

13 13 Photons in upstream TPG Photons entering with angle are mirrored against surrounding kapton

14 14 Comment on results, photons Without RF background: With RF background: Almost zero Dramatic change (again)! <19 MHz 8.0 MHz go through all volume side to side

15 15 Physics inside absorbers The computed efficiencies are 0.88% for e-, and 2.65% for photons. –This is for particles leaving the absorber window towards the tracker. The processes inside the absorbers were (per muon track, with background): –e-: ionization = 2931, bremsstrahlung = 267, multiple scattering = 0.1 –gamma:compton = 120.0, photoconv = 30.0 –mu+:ionization = 8.6 –This is inside the liquid hydrogen, not the windows. Behavior of Geant4 has been erratic and I can not say I fully trust electromagnetic processes in Geant4...

16 16 RF Background & TPG With an open gate of 60 microseconds and 3GHz of RF e- emitted, the electron efficiency rescales to 1458 high energy electrons per drift time, or a total of 6745 e- with energy higher than 1 keV. 1350 electrons traverses the entire active volume. –This is a serious problem. The corresponding number for photons is 1222. If the plans regarding shortening the TPG to 25 cm go through, these values should be scaled down to 1/4. The following slide contains a graphical illustration of a digitized typical event with the background turned on. Please note that both background and muon trajectory is for one muon at the given rates. In reality the situation will be worse due to overlapping tracks. The time information is not set, so they will not necessarily enter the tracker at the same time (as in the picture). Tracks like these should be fed into reconstruction written by Gabriella et al and the simplified reconstruction written by Olena Voloshyn.

17 17 Typical event with background, TPG Upstream, with BGDownstream, without BG BAD!

18 18 RF Background & SciFi –Assuming that the number of high energy (red) electrons and photons are identical for the upstream TPG and upstream SciFi: With a SciFi gate of 20 ns there will be 0.5 high energy electrons in the gate for each tracker. The corresponding number of photons is 0.4 in the gate per SciFi tracker and therefore will produce much fewer hits than the direct electrons. The dominant source of background are electrons directly produced from the absorber (and windows)

19 19 Energy dependence dE/dx due to ionization decreases with energy. –Hence the number of electrons that leaves the absorbers increases with energy. dE/dx due to bremsstrahlung increases with energy linearly. –This makes the number of photons leaving the absorbers increase linearly with energy. MICE will be very sensitive to how much energy the RF induced electrons gain in the cavities.

20 20 Energy dependence (plot) (x-axis not linear) easy hard E = ?

21 21 How realistic are the assumptions? Hand calculated phases (optimized for muons) gives lower energies to the RF electrons, if emitted at peak phase: –1.3, 2.8, 5.1, 7.8 [MeV] –Then we only need to deal with photons! But, electrons can still gain the energies I have simulated if emitted a bit off-peak. Bypassed some windows in this simulation. More realistic model of emission necessary for further study. Thanks Alain! Deceleration due to field mismatch

22 22 Open questions Can we improve these results by changing the design of absorbers? –Thickness –Different material (Z) To what level should we trust Geant4? –It is a high energy tool, with low-E extensions. RF radiation measurements with prototype 201 MHz cavity.

23 23 Summary Method A is preferable compared to method B, but it requires more of G4MICE. –The proper phases must be used to set the time of emission. –We would benefit from having an accurate description of spatial distribution of emitting sites. (=> Lower rates?) –More time consuming than method B. Physics and absorbers in G4MICE –Found discrepancies in how Geant4 performs electromagnetic interaction at low energy. Particle rates, upstream absorber and tracker: It still looks like the TPG will have problems with the RF induced background. SciFi? The problem is strongly depending on energy.

24 24 Extra slides

25 25 Electrons from 11.1 MeV peak, abs.

26 26 Photons from 11.1 MeV peak, abs.

27 27 Range of electrons in TPG (up)

28 28 Range of photons in TPG (up)


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