Pulsed- and DC-Charged PCSS-Based Trigger Generators
Prior to this research, we have developed high-gain GaAs photoconductive semiconductor switches (PCSSs) to trigger 50-300 kV high-voltage switches (HVSs). We have demonstrated that PCSSs can trigger a variety of pulsed-power switches operating at 50-300 kV by locating the trigger generator (TG) dire...
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| Published in: | IEEE transactions on plasma science Vol. 38; no. 10; pp. 2701 - 2707 |
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| Main Authors: | , , , , , , |
| Format: | Journal Article |
| Language: | English |
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| Abstract | Prior to this research, we have developed high-gain GaAs photoconductive semiconductor switches (PCSSs) to trigger 50-300 kV high-voltage switches (HVSs). We have demonstrated that PCSSs can trigger a variety of pulsed-power switches operating at 50-300 kV by locating the trigger generator (TG) directly at the HVS. This was demonstrated for two types of dc-charged trigatrons and two types of field distortion midplane switches, including a ±100 kVDC switch produced by the High Current Electronics Institute used in the linear transformer driver. The lowest rms jitter obtained from triggering an HVS with a PCSS was 100 ps from a 300 kV pulse-charged trigatron. PCSSs are the key component in these independently timed fiber-optically controlled low jitter TGs for HVSs. TGs are critical subsystems for reliable and efficient pulsed-power facilities because they control the timing synchronization and amplitude variation of multiple pulse-forming lines that combine to produce the total system output. Future facility-scale pulsed-power systems are even more dependent on triggering, as they are composed of many more triggered HVSs, and they produce shaped pulses by independent timing of the HVSs. As pulsed-power systems become more complex, the complexity of the associated trigger systems also increases. One of the means to reduce this complexity is to allow the trigger system to be charged directly from the voltage appearing across the HVS. However, for slow or dc-charged pulsed-power systems, this can be particularly challenging as the dc hold-off of the PCSS dramatically declines. This paper presents results that are seeking to address HVS performance requirements over large operating ranges by triggering using a pulsed-charged PCSS-based TG. Switch operating conditions that are as low as 45% of the self-break were achieved. A dc-charged PCSS-based TG is also introduced and demonstrated over a 39-61 kV operating range. DC-charged PCSS allows the TG to be directly charged from slow or dc-charged pulsed-power systems. GaAs and neutron-irradiated GaAs (n-GaAs) PCSSs were used to investigate the dc-charged operation. |
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| AbstractList | Prior to this research, we have developed high-gain GaAs photoconductive semiconductor switches (PCSSs) to trigger 50-300 kV high-voltage switches (HVSs). We have demonstrated that PCSSs can trigger a variety of pulsed-power switches operating at 50-300 kV by locating the trigger generator (TG) directly at the HVS. This was demonstrated for two types of dc-charged trigatrons and two types of field distortion midplane switches, including a ±100 kVDC switch produced by the High Current Electronics Institute used in the linear transformer driver. The lowest rms jitter obtained from triggering an HVS with a PCSS was 100 ps from a 300 kV pulse-charged trigatron. PCSSs are the key component in these independently timed fiber-optically controlled low jitter TGs for HVSs. TGs are critical subsystems for reliable and efficient pulsed-power facilities because they control the timing synchronization and amplitude variation of multiple pulse-forming lines that combine to produce the total system output. Future facility-scale pulsed-power systems are even more dependent on triggering, as they are composed of many more triggered HVSs, and they produce shaped pulses by independent timing of the HVSs. As pulsed-power systems become more complex, the complexity of the associated trigger systems also increases. One of the means to reduce this complexity is to allow the trigger system to be charged directly from the voltage appearing across the HVS. However, for slow or dc-charged pulsed-power systems, this can be particularly challenging as the dc hold-off of the PCSS dramatically declines. This paper presents results that are seeking to address HVS performance requirements over large operating ranges by triggering using a pulsed-charged PCSS-based TG. Switch operating conditions that are as low as 45% of the self-break were achieved. A dc-charged PCSS-based TG is also introduced and demonstrated over a 39-61 kV operating range. DC-charged PCSS allows the TG to be directly charged from slow or dc-charged pulsed-power systems. GaAs and neutron-irradiated GaAs (n-GaAs) PCSSs were used to investigate the dc-charged operation. Prior to this research, we have developed high-gain GaAs photoconductive semiconductor switches (PCSSs) to trigger 50-300 kV high-voltage switches (HVSs). We have demonstrated that PCSSs can trigger a variety of pulsed-power switches operating at 50-300 kV by locating the trigger generator (TG) directly at the HVS. This was demonstrated for two types of dc-charged trigatrons and two types of field distortion midplane switches, including a plus or minus 100 kVDC switch produced by the High Current Electronics Institute used in the linear transformer driver. The lowest rms jitter obtained from triggering an HVS with a PCSS was 100 ps from a 300 kV pulse-charged trigatron. PCSSs are the key component in these independently timed fiber-optically controlled low jitter TGs for HVSs. TGs are critical subsystems for reliable and efficient pulsed-power facilities because they control the timing synchronization and amplitude variation of multiple pulse-forming lines that combine to produce the total system output. Future facility-scale pulsed-power systems are even more dependent on triggering, as they are composed of many more triggered HVSs, and they produce shaped pulses by independent timing of the HVSs. As pulsed-power systems become more complex, the complexity of the associated trigger systems also increases. One of the means to reduce this complexity is to allow the trigger system to be charged directly from the voltage appearing across the HVS. However, for slow or dc-charged pulsed-power systems, this can be particularly challenging as the dc hold-off of the PCSS dramatically declines. This paper presents results that are seeking to address HVS performance requirements over large operating ranges by triggering using a pulsed-charged PCSS-based TG. Switch operating conditions that are as low as 45% of the self-break were achieved. A dc-charged PCSS-based TG is also introduced and demonstrated over a 39-61 kV operating range. DC-charged PCSS allows the TG to be directly charged from slow or dc-charged pulsed-power systems. GaAs and neutron-irradiated GaAs (n-GaAs) PCSSs were used to investigate the dc-charged operation. Prior to this research, we have developed high-gain GaAs photoconductive semiconductor switches (PCSSs) to trigger 50 - 300 kV high-voltage switches (HVSs). We have demonstrated that PCSSs can trigger a variety of pulsed-power switches operating at 50 - 300 kV by locating the trigger generator (TG) directly at the HVS. This was demonstrated for two types of dc-charged trigatrons and two types of field distortion midplane switches, including a $pm$100 kVDC switch produced by the High Current Electronics Institute used in the linear transformer driver. The lowest rms jitter obtained from triggering an HVS with a PCSS was 100 ps from a 300 kV pulse-charged trigatron. PCSSs are the key component in these independently timed fiber-optically controlled low jitter TGs for HVSs. TGs are critical subsystems for reliable and efficient pulsed-power facilities because they control the timing synchronization and amplitude variation of multiple pulse-forming lines that combine to produce the total system output. Future facility-scale pulsed-power systems are even more dependent on triggering, as they are composed of many more triggered HVSs, and they produce shaped pulses by independent timing of the HVSs. As pulsed-power systems become more complex, the complexity of the associated trigger systems also increases. One of the means to reduce this complexity is to allow the trigger system to be charged directly from the voltage appearing across the HVS. However, for slow or dc-charged pulsed-power systems, this can be particularly challenging as the dc hold-off of the PCSS dramatically declines. This paper presents results that are seeking to address HVS performance requirements over large operating ranges by triggering using a pulsed-charged PCSS-based TG. Switch operating conditions that are as low as 45% of the self-break were achieved. A dc-charged PCSS-based TG is also introduced and demonstrated ov- - er a 39 - 61 kV operating range. DC-charged PCSS allows the TG to be directly charged from slow or dc-charged pulsed-power systems. GaAs and neutron-irradiated GaAs (n-GaAs) PCSSs were used to investigate the dc-charged operation. [PUBLICATION ABSTRACT] |
| Author | Glover, Steven F Cich, Michael J Loubriel, Guillermo M Swalby, Michael E White, Forest E Zutavern, Fred J Mar, A |
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| CitedBy_id | crossref_primary_10_1109_TED_2021_3120974 crossref_primary_10_1109_TPS_2023_3285107 crossref_primary_10_1109_LED_2015_2416188 crossref_primary_10_1063_5_0009453 crossref_primary_10_1063_5_0153498 crossref_primary_10_1063_1_5018356 crossref_primary_10_1109_TIM_2021_3075434 crossref_primary_10_1109_TPS_2012_2185071 crossref_primary_10_1109_JEDS_2017_2718519 crossref_primary_10_1063_1_4991408 crossref_primary_10_1016_j_mre_2017_12_006 crossref_primary_10_1364_OL_38_002330 crossref_primary_10_3390_photonics8090385 |
| Cites_doi | 10.1109/TPS.2005.860110 10.1103/PhysRevSTAB.10.030401 10.1109/PPC.2003.1277780 10.1109/27.901223 10.1109/TPS.2008.2004367 10.1109/PPC.1997.674517 10.1109/PPC.2009.5386357 10.1103/PhysRevSTAB.12.050401 10.1109/PPPS.2007.4345495 10.1109/PPPS.2001.1001907 10.1109/TPS.2008.925637 10.1063/1.1871954 10.1109/MODSYM.1996.564477 10.1109/PPC.2009.5386398 10.1103/PhysRevSTAB.12.030402 |
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| References | ref15 (ref20) 0 ref14 glover (ref12) 2007 stygar (ref1) 2007; 10 ref11 ref2 cich (ref16) 2007 ref18 davis (ref4) 2005; 12 glover (ref13) 2008 ref24 ref23 ref22 (ref10) 1985 glover (ref9) 2008 (ref19) 0 ref8 ref7 ref3 mar (ref17) 2002 ref6 ref5 gruner (ref21) 0 (ref25) 0 |
| References_xml | – ident: ref3 doi: 10.1109/TPS.2005.860110 – volume: 10 start-page: 30401-1 year: 2007 ident: ref1 article-title: Architecture of petawatt-class <tex Notation="TeX">$Z$</tex>-pinch accelerators publication-title: Phys Rev ST Accel Beams doi: 10.1103/PhysRevSTAB.10.030401 contributor: fullname: stygar – ident: ref11 doi: 10.1109/PPC.2003.1277780 – ident: ref14 doi: 10.1109/27.901223 – ident: ref8 doi: 10.1109/TPS.2008.2004367 – year: 0 ident: ref19 publication-title: Minilite II Laser – year: 2008 ident: ref13 publication-title: Fiber-optically controlled PCSS based trigger generators for pulsed power switches contributor: fullname: glover – ident: ref7 doi: 10.1109/PPC.1997.674517 – start-page: 236 year: 2007 ident: ref16 article-title: gaas pcss fabrication for improved reliability publication-title: Proc Pulsed Power Plasma Sci Conf contributor: fullname: cich – ident: ref5 doi: 10.1109/PPC.2009.5386357 – ident: ref22 doi: 10.1103/PhysRevSTAB.12.050401 – ident: ref15 doi: 10.1109/PPPS.2007.4345495 – year: 2002 ident: ref17 publication-title: An optically-triggered semiconductor switch for firing systems contributor: fullname: mar – start-page: 240 year: 2007 ident: ref12 article-title: laser triggering of spark gap switches with less than 100 <tex notation="tex">$\mu\hbox{j}$</tex> 's of energy publication-title: Proc Pulsed Power Plasma Sci Conf contributor: fullname: glover – year: 0 ident: ref21 publication-title: Radial Pin Switch contributor: fullname: gruner – ident: ref23 doi: 10.1109/PPPS.2001.1001907 – ident: ref2 doi: 10.1109/TPS.2008.925637 – volume: 12 start-page: 56310-1 year: 2005 ident: ref4 article-title: Magnetically driven isentropic compression to multimegabar pressures using shaped current pulses on the Z accelerator publication-title: Phys Plasmas doi: 10.1063/1.1871954 contributor: fullname: davis – ident: ref24 doi: 10.1109/MODSYM.1996.564477 – year: 0 ident: ref20 publication-title: Ocean Optics 600 Fiber P600-5-UV-VIS – year: 0 ident: ref25 publication-title: PerkinElmer GP-81B Triggered Spark Gap – year: 1985 ident: ref10 publication-title: Proc IEEE Int Pulsed Power Conf Power Modulator Symposia – year: 2008 ident: ref9 publication-title: Neutron-irradiated GaAs for dc charged PCSS based trigger systems contributor: fullname: glover – ident: ref18 doi: 10.1109/PPC.2009.5386398 – ident: ref6 doi: 10.1103/PhysRevSTAB.12.030402 |
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| Snippet | Prior to this research, we have developed high-gain GaAs photoconductive semiconductor switches (PCSSs) to trigger 50-300 kV high-voltage switches (HVSs). We... Prior to this research, we have developed high-gain GaAs photoconductive semiconductor switches (PCSSs) to trigger 50 - 300 kV high-voltage switches (HVSs). We... |
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| SubjectTerms | Charging Control systems Driver circuits Electric currents Fiber-optic triggers Gallium arsenide Gallium arsenides Generators high-voltage triggers Jitter low jitter triggers Photoconducting devices photoconductive semiconductor switches (PCSSs) Pulse generation Pulse shaping methods Pulse transformers pulsed-power trigger generators (TGs) Semiconductors Switches Switching Time measurements Timing Trigatrons triggering pulsed-power switches |
| Title | Pulsed- and DC-Charged PCSS-Based Trigger Generators |
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