1. High-Current Carbon-Epoxy Multi-Capillary Cathode
Tal Queller, Jozeph Z. Gleizer and Yakov E. Krasik
Plasma and Pulsed Power Laboratory
Physics Department, Technion, Haifa, Israel
Vladimir Bernshtam
Department of Physics, Weizmann Institute of science, Rehovot, Israel

2. Outline
A brief review of research of plasma cathodes for generation of high-current relativistic electron beam in our lab in the last 12 years
Active plasma cathodes – Plasma is produced prior to the accelerating pulse application
[Ferroelectric Plasma Source (FPS, Hollow Anode with incorporated FPS]
Passive plasma cathodes – Plasma is produced by the accelerating pulse
(metal-ceramic, velvet, carbon fibers, multi-capillary dielectric)
The recent carbon epoxy multi-capillary cathode
Experimental setup and cathode configurations
Diode and plasma parameters
Electron beam parameters
Conclusions

3. Expectations from an ideal Pulsed Electron Source
Instantaneous turn-on (low threshold electric field for electron emission initiation) Ethresh<10 kV/cm
Low sensitivity to electric field rise time dE/dt<1011 V/(cms)
Long electron beam duration t> 10-6 s
High electron beam current density jbeam = 10 – 1000 A/cm2
Quasi-constant perveance of the diode
Electron beam cross-sectional current density uniformity
Electron beam arbitrary cross-sectional
Repetition rate compatibility
compatibility with vacuum P =10-4 – 10-5 Torr
long lifetime # of pulses >107

4. Diagnostic techniques
Fast framing light imaging – plasma initiation time and spatial distribution
Time– & space-resolved plasma composition, density, temp.
spectral measurements – & expansion velocity
Thomson scattering – plasma electron energy distribution
Microwave cut-off – plasma electron density
Laser Induced Fluorescence – plasma ion temperature
X-Ray imaging – electron beam cross-sectional uniformity
Electrical measurements – Integrated & collimated arrays of FCs VDs & self- integrated RCs-CVR
Single & Double floating probes – plasma density, electron temp and plasma potential
Retarding spectrometer – plasma electron & ion energy
Fast Penning probe – background pressure dynamics
Pin-hole cameras – electron beam macro- and micro-divergence

5. Active Cathodes Ferroelectric Plasma Source
Light emission
10ns
rear
electrode
ceramic
front
Mechanism – Incomplete surface discharge along the surface of the ferroelectric, initiated by the driving pulse in the metal-ceramic-vacuum triple point
grid
120mm
Diode & Electron beam parameters
X-Ray
20ns
Plasma
parameters
5mm
Advantages
Arbitrary cross-section
Uniform electron beam cross-sectional density
Instantaneous electron beam formation
E, 106 V/m 5
Metal
Dielectric
Vacuum 10
Drawbacks
Requires an additional driving pulse system
Duration ≤510-7s
Deterioration of vacuum
Current density ≤100 A/cm2

6. Active Cathodes FPS-assisted HA Diode & Electron beam parameters
FPS igniter
Mechanism – Electrons from the plasma formed by the FPS are accelerated and ionize background and desorbed from FPS gas inside the anode.
Depending on the discharge current
Light
120mm
20ns
Plasma
parameters
X-ray
10ns
Diode & Electron beam parameters
Advantages
Arbitrary cross-section area
Instantaneous electron emission
Long (10-6 – 10-5 s) pulse duration
Drawbacks
Electron current density <50 A/cm2
Additional plasma source
Plasma penetrates into the accelerating gap
Early and Sharp current rise because of the plasma pre-filling of the hollow anode space

7. Passive Cathodes Metal-Ceramic Diode & Electron beam parameters Light
120mm
Light
20ns
Plasma
parameters
X-ray
10ns
Diode & Electron beam parameters
Mechanism - Incomplete surface discharge initiated in triple points
Dielectric constant of ~5
Drawbacks
High plasma expansion velocity (5106 cm/s)
High transverse electron beam velocity – beam divergence (120)
High E ≥ 105 V/cm & dE/dt≥ 1013 V/(cm∙s) are required for uniform and fast plasma ignition
Advantages
Instantaneous plasma generation – a few ns (E ≥ 105 V/cm, dE/dt≥ 1013 V/cm∙s)
Long lifetime shots
Repetition rate compatibility for short pulses (tens of ns)

8. Passive Cathodes Velvet \ Carbon fiber
80mm
Mechanism – a surface flashover along the fibers creates plasma
70mm
Plasma
parameters
Light
20ns
Diode & Electron beam parameters
X-Ray
10ns
Advantages
Low electric field threshold – E < 104 V/cm (large field enhancement)
Cross-sectional electron beam uniformity
Quasi-constant impedance behavior due to slow (106 cm/s) plasma expansion velocity
Long pulse duration (1µs)
Drawbacks
Short cathode lifetime < 10
shots at je>100A/cm2
Repetition rate incapability (relatively large outgassing due to the surface flashover mechanism)

9. Passive Cathodes Multi-Capillary Diode & Electron beam parameters
Mechanism – Surface flashover plasma
inside the cylindrical dielectric capillaries
90mm
Plasma
parameters
Light
20ns
X-Ray
10ns
Diode & Electron beam parameters
Drawbacks
Fast plasma expansion >3106cm/s
at je≥50 A/cm2
Outgassing
Advantages
Satisfactory uniform cross-sectional beam
current density
Long life-time
Low-voltage threshold

10. Multi-Capillary Carbon-Epoxy
Passive Cathodes
The Recent :
Multi-Capillary Carbon-Epoxy

11. Passive Cathodes
Multi-Capillary
Carbon-Epoxy
Experimental Setup

12. Passive Cathodes Multi-Capillary Carbon-Epoxy Cathode geometries
1.2mm
30mm
25mm
7mm
0.7mm
75 capillaries
9 capillaries
single capillary
Voltage  300 kV
Current  20 kA
jav  600 A/cm2
jcap  17 kA/cm2
Beam duration 700ns
Planar 70mm
Voltage  150 kV
Current  3 kA
jav  400 A/cm2
jcap  10 kA/cm2
Beam duration 500ns
Planar 30mm
Strip 70mm
Voltage  250 kV
Current  6 kA
jav  12 kA/cm2
jcap  170 kA/cm2
Beam duration 1s
Voltage  40 kV
Current  50 A
jav  3 kA/cm2
jcap  13 kA/cm2
Beam duration 100ns
Single Capillary
Cathode geometries
X-ray image
Frame
Duration
20ns

13. Passive Cathodes Multi-Capillary Carbon-Epoxy
Typical diode voltage, current and impedance
Plasma expansion velocity across the gap is slow (≤1.5∙106 cm/s)
Long pulse duration
Low electric field and dE/dt threshold for electron emission beginning
Plasma Light Images Front view
Time
Frame
Duration
20ns
50 ns
80 ns
130 ns
180 ns
Plasma originates in almost all individual capillaries

14. Passive Cathodes Multi-Capillary Carbon-Epoxy
Spectral emission intensity
Light emission – side view
Dense plasma remains in the cathode vicinity throughout the entire HV pulse
Current density  650A/cm2
Frame Duration: 20ns

15. Passive Cathodes Cathode plasma expansion velocity
Multi-Capillary Carbon-Epoxy
Cathode plasma expansion velocity
Hydrogen
expansion velocity
Carbon ions

16. Passive Cathodes Plasma density and ion temperature
Multi-Capillary Carbon-Epoxy
Plasma density and ion temperature
(Stark and Doppler analysis)
Spatial distributions (HV generator #2: 650 A/cm2)
Hydrogen temperature
Plasma electron density
Plasma density in the vicinity of the cathode does not exceed 71014 cm-3
Relatively low plasma density indicates strongly on its flashover origin, e.g., inside the capillary (explosive emission plasma is characterized by n ≥ 1016cm-3)

17. Passive Cathodes Plasma parameters - Temporal distributions
Multi-Capillary Carbon-Epoxy
Plasma parameters - Temporal distributions
B = 0.86 Tesla
B=0
H atoms
CII ions
There is no significant change in the temperature during the accelerating pulse, and with\wo a magnetic field
Electron temperature
LINES – Time dependent CR Model simulation
DOTS – Experimental data
CR modeling indicates of high electron temperature : 11 eV.

18. Passive Cathodes Multi-Capillary Carbon-Epoxy Single capillary
Frame duration : 20ns
Single capillary
Generator #3: I = 50 A ; je = 3 kA/cm2
Time
Planar 30mm
Generator #2 : I = 3 kA ; je = 400 kA/cm2
Anode plasma
Plasma
parameters
The plasma is formed as a result of flashover inside the capillary !

19. Passive Cathodes Conclusions Multi-Capillary Carbon-Epoxy
The source of electrons is a low-density and slow
expanding plasma, typical of flashover process
Plasma is formed as result of flashover inside the capillaries
Long life time (>104 shots – no damages)
This type of cathode could be used for applications
requiring simultaneously:
Long duration beam (10-7 – 10-6s)
High-current density beam (102 – 104 A/cm2)
Large total beam current (103 – 104 A)
High energy beam electrons (>100 keV)
Long lifetime
Specific cross-sectional area of the beam

20. Acknowledgements Prof. Yakov Krasik Prof. Joshua Felsteiner
Prof. Victor
Gurovitch
Dr. Anatoli
Shlapakovski
Dr. Joseph
Gleizer
Dr. Arkadi
Sayapin
Dr. Yoav
Hadas
Dr. Vlad
Vekselman
Dr. Dima
Yarmolich
Dr. Kostantin
Chirko
Dr. Vladimir
Bernshtam
Dr. Alexander
Krohkmal
Dr. Yuri
Bliokh
Dr. Alexander
Dunaevskii
Shurik
Yatom
Vladi
Raikhlin
Andrei
Levin
Kalman
Gruzinski
Hila Sagi
Or Peleg
Galina Bazalitski
Svetlana Gleizer