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Trace: david_bentley_hart passive-components
topic:engineering:cryogenics:electronics:passive-components

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topic:engineering:cryogenics:electronics:passive-components [2021/03/22 21:40] – [Capacitor] samueltopic:engineering:cryogenics:electronics:passive-components [2026/02/13 14:36] (current) samuel
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 ===== Resistor ===== ===== Resistor =====
-^ Susumu, RR1220P-104-D | 100kOhm | \cite{Cahall.Gauthier.ea:2018}, \cite{Lamb:2014} | +Metal Thin Film resistors are very temperature stable. {[Homulle:2019]} 
-^ Susumu, RR1220P-101-D | 100 Ohm | \cite{Cahall.Gauthier.ea:2018}, \cite{Lamb:2014} |+ 
 +^ Susumu, RR1220P-104-D | 100kOhm | {[Cahall.Gauthier.ea:2018]}, {[Lamb:2014]} | 
 +^ Susumu, RR1220P-101-D | 100 Ohm | {[Cahall.Gauthier.ea:2018]}, {[Lamb:2014]} | 
 +^ Vishay, FC0603E50R0BST1 | 50 Ohm | {[Homulle:2019]} | 
 +^ Panasonic ERA-3AEB4990V | 499 Ohm | {[Homulle:2019]} |
  
 Literature: Literature:
-  * Table of characterized components: \cite{Lamb:2014}+  * Table of characterized components: {[Lamb:2014]}
  
 ===== Inductor ===== ===== Inductor =====
-^ Epcos, B82496C3221J000 | 220nH | \cite{Cahall.Gauthier.ea:2018} | +^ Epcos, B82496C3221J000 | 220nH | {[Cahall.Gauthier.ea:2018]} | 
-^ Taiyo Yuden chip inductor (0402) | 2.28uH (1.37uH, 1 Ohm @ 4K) | \cite{Buchanan.Benford.ea:2012} |+^ Taiyo Yuden chip inductor (0402) | 2.28uH (1.37uH, 1 Ohm @ 4K) | {[Buchanan.Benford.ea:2012]} |
 ===== Capacitor ===== ===== Capacitor =====
-Foil capacitors (e.g. ECPU, ECHU and PPS) reduced their capacitance significantly at cryogenic temperatures. NP0 capacitors show little change of capacitance during cooling. \cite{Pan:2005}+Foil capacitors (e.g. ECPU, ECHU and PPS) reduced their capacitance significantly at cryogenic temperatures. NP0 capacitors show little change of capacitance during cooling. {[Pan:2005]}
  
-^ Kemet, C0805C473J3GACTU | 0.047uF, Ceramic capacitor, used as decoupling capacitor, cold they have $\approx 11pF$ | \cite{PaqueletWuetz.Bavdaz.ea:2020} | +Below 1uF NP0/C0G and Acrylic Film are the way to go, above tantalum polymer capactitors.{[Homulle:2019]} 
-^ Kemet, C0603C153J3GACTU | 0.015µF, Ceramic capacitor, used as decoupling capacitor, cold they have $\approx 2pF$ | \cite{PaqueletWuetz.Bavdaz.ea:2020} | + 
-^ Kemet, C0402C101J5GACTU | 100pF, Ceramic capacitor | \cite{PaqueletWuetz.Bavdaz.ea:2020} | +^ Kemet, C0805C473J3GACTU | 0.047uF, Ceramic capacitor, used as decoupling capacitor, cold they have $\approx 11pF$ | {[PaqueletWuetz.Bavdaz.ea:2020]} | 
-^ Vishay Vitramon, VJ0603A101KXBAC31 | 100pF | \cite{Cahall.Gauthier.ea:2018} |+^ Kemet, C0603C153J3GACTU | 0.015µF, Ceramic capacitor, used as decoupling capacitor, cold they have $\approx 2pF$ | {[PaqueletWuetz.Bavdaz.ea:2020]} | 
 +^ Kemet, C0402C101J5GACTU | 100pF, Ceramic capacitor | {[PaqueletWuetz.Bavdaz.ea:2020]} | 
 +^ Vishay Vitramon, VJ0603A101KXBAC31 | 100pF | {[Cahall.Gauthier.ea:2018]} |
  
 Literature: Literature:
   * Table of characterized components: \cite[Table 2.1]{Homulle:2019} Table 2.1   * Table of characterized components: \cite[Table 2.1]{Homulle:2019} Table 2.1
- + 
 +<bibtex bibliography> 
 +</bibtex>
topic/engineering/cryogenics/electronics/passive-components.1616449226.txt.gz · Last modified: by samuel

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