Panel | ||||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|
| ||||||||||||
|
An example for Track3P multipacting computation on a single field level. Field gradient: 97e+06
Code Block |
---|
// If you don't give this block, it will use default value ParticlesTrajectories: // record particles' trajectory, only for running single //field case { ParticleFile: p // file name Skip: 10 // write file each 10 steps Start: 10 // start time step for writing file Stop: 100000 // stop time step for writing file } FieldScales: { Type: FieldGradient // Three types, FieldGradient (v/m); InputPortPower (W); StoreEnergy ScanToken: 0 // 1: scan, 0: no scan Scale: 97e+06 //field scale for particle trajectory } //Normalize field, only for closed waveguide case NormalizedField: { StartPoint: 0 0 0.0486225 //start point of the line for field integral calculation EndPoint: 0 0 0.2061 //end point of the line for field integral calculation } // Primary particles emission Emitter: { x0: -0.001 x1: 0.001 y0: 0.09 y1: 0.12 z0: -0.068 z1: 0.068 BoundaryID: 6 } Material:{ Type: Primary BoundarySurfaceID: 6 //Boundary surface ID } Material:{ Type: Secondary BoundarySurfaceID: 6 //Boundary surface ID } Material:{ Type: Absorber BoundarySurfaceID: 3 4 7 8 //Boundary surface ID } Material:{ Type: SymmetryPlane BoundarySurfaceID: 1 2 //Boundary surface ID } OutputImpacts: on // Field information container Domain: { PostprocessFile: ./vector1/postprocess.in Bins: 250 } Postprocess: // multipacting postprocess { Toggle: on // on: postprocess, off: no postprocess ResonantParticles: // postprocess for resonant particles { Token: on // on: analysis resonant particles, no: no analysis is done for resonant particles } } |
An example of multipacting simulation on a field level scan case
Code Block |
---|
// Field level(V/m) / Port power(W) FieldScales: { Type: FieldGradient ScanToken: 1 // 1: scan, 0: no scan Minimum: 1e+06 Maximum: 100e+06 } //Normalize field, only for closed waveguide case NormalizedField: { StartPoint: 0 0 0.0486225 //start point of the line for field integral calculation EndPoint: 0 0 0.2061 //end point of the line for field integral calculation } // Primary particles emission Emitter: { x0: -0.001 x1: 0.001 y0: 0.09 y1: 0.12 z0: -0.068 z1: 0.068 BoundaryID: 6 } Material:{ Type: Primary BoundarySurfaceID: 6 //Boundary surface ID } Material:{ Type: Secondary BoundarySurfaceID: 6 //Boundary surface ID } Material:{ Type: Absorber BoundarySurfaceID: 3 4 7 8 //Boundary surface ID } Material:{ Type: SymmetryPlane BoundarySurfaceID: 1 2 //Boundary surface ID } OutputImpacts: on // Field information container Domain: { PostprocessFile: ./vector1/postprocess.in Bins: 360 } Postprocess: // multipacting postprocess { Toggle: on // on: postprocess, off: no postprocess ResonantParticles: // postprocess for resonant particles { Token: on // on: analysis resonant particles, no: no analysis is done for resonant particles } } |
An example of tracking particles simulation with only one impact information
Code Block |
---|
TotalTime: 3 //total running time in RF cycles, default: 20 RF cycle // Field level(V/m) / Port power(W) FieldScales: { Type: FieldGradient ScanToken: 0 // 1: scan, 0: no scan Scale: 97e+06 //field scale for particle trajectory } //Normalize field, only for closed waveguide case NormalizedField: { StartPoint: 0 0 0.0486225 //start point of the line for field integral calculation EndPoint: 0 0 0.2061 //end point of the line for field integral calculation } // Primary particles emission Emitter: { t0: 0 //time(in RF cycle) for start emission t1: 1 //time(in RF cycle) for end emission Type: 4 Position: 4.0388e-4 4.63728e-3 6.49586e-2 BoundaryID: 6 } Material:{ Type: Primary BoundarySurfaceID: 6 //Boundary surface ID } Material:{ Type: Secondary BoundarySurfaceID: 6 //Boundary surface ID } Material:{ Type: Absorber BoundarySurfaceID: 3 4 7 8 //Boundary surface ID } Material:{ Type: SymmetryPlane BoundarySurfaceID: 1 2 //Boundary surface ID } OutputImpacts: on // Field information container Domain: { dt: 0.5 PostprocessFile: ./vector1/postprocess.in MaxImpacts: 1 Bins: 300 } Postprocess: // multipacting postprocess { Toggle: on // on: postprocess, off: no postprocess ResonantParticles: // postprocess for resonant particles { Token: off // on: analysis resonant particles, no: no analysis is done for resonant particles InitialImpacts: 4 // particles with impacts number greater than initial impacts are considered, default is 4 EnergyRange: 10 10000 //particles with impact energy fall in this region is considered, default value: >10ev, <10000ev } DKSingleEmit: { Token: on FileName: DKSingleEmit SymmetryBoundaryIDs: 1 2 } } |
An example for Track3P dark current simulation for 90 degree square bend structure
Code Block |
---|
TotalTime: 20 ParticlesTrajectories: { ParticleFile: p Skip: 10 // Start: 500 // Stop: 2500 } FieldScales: { Type: InputPortPower ScanToken: 1 // 1: scan, 0: no scan Minimum: 72e+06 Maximum: 72e+06 Interval: 1e+06 Scale: 213e+06 //field scale for particle trajectory } Emitter: { t0: 0 t1: 20.0 Type: 7 //dark current type (field emission) BoundaryID: 6 N: 3 // number of unit particles in the macroparticle M: 9.108e-31 // real mass of a unit particle Q: -1.602e-19 d: .000001 WorkFunction: 4.4 Beta: 120 SuppressionFactor: 2.0 //WriteToFile: 1 // x y z directions limitation x0: 0.0 x1: 0.025 y0: -0.1 y1: 0.2 z0: -0.2 z1: 0.1 } OutputImpacts: on // write out impact energy infor. Material: { Type: 3 //second partticle following SEY curve BoundarySurfaceID: 6 // WriteToFile: 1 N: 100 M: 9.108e-31 // real mass of a unit particle Model: 2 N: 3 Sigma0: 0.0 0.25 0.47 0.66 0.83 0.97 1.08 1.17 1.25 1.3 1.34 1.4 1.37 1.31 1.24 1.19 1.14 1.09 1.06 1.03 1.0 0.97 0.95 0.93 0.91 0.89 0.87 0.85 0.84 0.83 0.81 0.79 0.77 0.75 0.73 Einit: 0.0 50 100 150 200 250 300 350 400 450 500 700 900 1100 1300 1500 1700 1900 2100 2300 2500 2700 2900 3100 3300 3500 3700 3900 4100 4300 4500 4900 5300 5700 6100 } |