PN diode example (1D): Difference between revisions

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To compare the numerical results with an analytical solution, the built-in voltage is solved both numerically and analytically in this example.  The results are shown at the end.
This example builds on the 1D resistor example, showing how to create a floods structure with a doping profile that varies with x. After solving, the example compares floods's numerical results with an analytical solution.


Define constants
== New Concepts ==
set eps [expr 11.8 * 8.854e-14 / 1.619e-19]
* refining the grid with non-tagged lines
set Emob 200.0;
* Doping=f(x) : use "sel z="
set Hmob 100.0;
* "sel z=" if-then-else syntax (?:)
* tcl "foreach" and "array"


Define Poisson and continuity equations
== 1D PN Diode Deck ==
  set eqnP "$eps * grad(DevPsi) + Doping - Elec + Hole"
Create 1D structure - [[PN diode example 1D - Create 1D structure explanation | explanation]]
  set eqnE "ddt(Elec) - $Emob * 0.025 * sgrad(Elec, DevPsi/0.025)"
#Grid
  set eqnH "ddt(Hole) - $Hmob * 0.025 * sgrad(Hole, -DevPsi/0.025)"
  line x loc=0.0 spac=0.1 tag=Top
  line x loc=0.5 spac=0.01
  line x loc=1.0 spac=0.1 tag=Bottom
mater add name=Silicon
region Silicon xlo=Top xhi=Bottom
init
#Contacts
contact name=VSS Silicon xlo=-0.1 xhi=0.1 add
contact name=GND Silicon xlo=0.9  xhi=1.1 add


pdbSetDouble Si DevPsi DampValue 0.025
Declare solution variables
  pdbSetDouble Si DevPsi Abs.Error 1.0e-9
  DevicePackage
  pdbSetString Si DevPsi Equation $eqnP
  solution add name=DevPsi pde solve negative damp
  pdbSetString Si Elec Equation $eqnE
  solution add name=Elec   pde solve !negative
pdbSetDouble Si Elec Abs.Error 1.0e-5
  solution add name=Hole   pde solve !negative
pdbSetString Si Hole Equation $eqnH
  pdbSetDouble Si Hole Abs.Error 1.0e-5


  pdbSetDouble top Hole Abs.Error 1.0e-8
Define constants
  pdbSetDouble top Elec Abs.Error 1.0e-8
  set T 300.0
  pdbSetDouble top DevPsi Abs.Error 1.0e-6
set k 1.38066e-23
  pdbSetDouble top Hole Rel.Error 1.0e-2
  set q 1.619e-19
  pdbSetDouble top Elec Rel.Error 1.0e-2
  set Vt [expr {$k*$T/$q}]
  pdbSetDouble top DevPsi Rel.Error 1.0e-2
  set ni 1.1e10
  pdbSetDouble top DevPsi Flux.Scale 1.619e-19
  set esi [expr 11.8 * 8.85418e-14]
  pdbSetDouble top Elec Flux.Scale 1.619e-19
  set eps [expr $esi / $q]
  pdbSetDouble top Hole Flux.Scale 1.619e-19
  set Emob 350.0
  set Hmob 150.0
  set small 1.0e-10


  pdbSetDouble ReflectBottom Hole Abs.Error 1.0e-8
Ionized dopant profile - [[PN diode example 1D - Ionized dopant profile explanation | explanation]]
  pdbSetDouble ReflectBottom Elec Abs.Error 1.0e-8
  sel z=1.0e20*(x<0.5) name=Nd
  pdbSetDouble ReflectBottom DevPsi Abs.Error 1.0e-6
  sel z=1.0e17 name=Na
  pdbSetDouble ReflectBottom Hole Rel.Error 1.0e-2
sel z=(Nd-Na) name=Doping
  pdbSetDouble ReflectBottom Elec Rel.Error 1.0e-2
   
  pdbSetDouble ReflectBottom DevPsi Rel.Error 1.0e-2
  #plot doping
  sel z=Doping
  plot.1d symb=1


  pdbSetBoolean top Elec Fixed 1
Bulk Equations
pdbSetBoolean top Hole Fixed 1
  set eqnP "$eps * grad(DevPsi) + Doping - Elec + Hole"
  pdbSetBoolean top DevPsi Fixed 1
  set eqnE "ddt(Elec) - ($Emob) * $Vt * sgrad(Elec, DevPsi/$Vt)"
  pdbSetBoolean top Elec Flux 1
  set eqnH "ddt(Hole) - ($Hmob) * $Vt * sgrad(Hole, -DevPsi/$Vt)"
pdbSetBoolean top Hole Flux 1
  pdbSetString Silicon DevPsi Equation $eqnP
  pdbSetBoolean top DevPsi Flux 1
  pdbSetString Silicon Elec   Equation $eqnE
  pdbSetString top Elec Equation {Doping - Elec + Hole}
  pdbSetString Silicon Hole   Equation $eqnH
  pdbSetString top Hole Equation {DevPsi + 0.025*log((Hole+1.0e-10)/1.0e10) + top}
  pdbSetString top DevPsi Equation {DevPsi - 0.025*log((Elec+1.0e-10)/1.0e10) + top}
pdbSetDouble Silicon DevPsi DampValue $Vt
pdbSetDouble Silicon DevPsi Abs.Error 1.0e-9
pdbSetDouble Silicon Elec  Abs.Error 1.0e-5
  pdbSetDouble Silicon Hole  Abs.Error 1.0e-5


  pdbSetBoolean ReflectBottom Elec Fixed 1
Contact Equations
pdbSetBoolean ReflectBottom Hole Fixed 1
  proc OhmicContact {Contact} {
pdbSetBoolean ReflectBottom DevPsi Fixed 1
    global Vt ni
pdbSetBoolean ReflectBottom Elec Flux 1
    pdbSetBoolean $Contact Elec Flux 1
pdbSetBoolean ReflectBottom Hole Flux 1
    pdbSetBoolean $Contact Hole Flux 1
pdbSetBoolean ReflectBottom DevPsi Flux 1
    pdbSetBoolean $Contact DevPsi Flux 1
pdbSetString ReflectBottom Hole Equation "Doping - Elec + Hole"
    pdbSetBoolean $Contact Elec Fixed 1
pdbSetString ReflectBottom Elec Equation "DevPsi - 0.025*log((Elec+1.0e-10)/1.0e10)"
    pdbSetBoolean $Contact Hole Fixed 1
pdbSetString ReflectBottom DevPsi Equation "DevPsi + 0.025*log((Hole+1.0e-10)/1.0e10)"
    pdbSetBoolean $Contact DevPsi Fixed 1
    pdbSetDouble $Contact Elec Flux.Scale 1.619e-19
    pdbSetDouble $Contact Hole Flux.Scale 1.619e-19
    pdbSetString $Contact DevPsi Equation "Nd - Na - Elec + Hole"
    pdbSetString $Contact Elec Equation "DevPsi - $Vt*log((Elec)/$ni) -$Contact"
    pdbSetString $Contact Hole Equation "DevPsi + $Vt*log((Hole)/$ni) -$Contact"
}
OhmicContact VSS
OhmicContact GND


Establish the grid and initialize
Initial Conditions - [[PN diode example 1D - Initial conditions explanation | explanation]]
line x loc=0.0 spac=.01 tag=Top
  #Bias contacts
line x loc=0.4 spac=0.01
  contact name=VSS voltage supply=0.0
line x loc=0.7 spac=0.01
  contact name=GND voltage supply=0.0
line x loc=2.0 spac=0.05 tag=Bottom
region silicon xlo=Top xhi=Bottom
#Initial Guess
  init
  sel z= {(Doping>0.0)  
 
            ? ( 0.025*log( (Doping+$small) / $ni))
 
            : (-0.025*log(-(Doping+$small) / $ni))} name = DevPsi
Create the contact
  sel z=$ni*exp(DevPsi/$Vt) name=Elec
  contact name=top silicon xlo=-0.1 xhi=0.1 add
  sel z=$ni*exp(-DevPsi/$Vt) name=Hole
  contact name=top current=1.619e-19*(Hole-Elec) voltage supply=0.0
 
1st DC Solve at Equilibrium (0V)
Initial guesses
  sel z=1.0e20*(x<0.5)-1.0e17 name=Doping
  sel z=0.5*(Doping+sqrt(Doping*Doping+4.0e20))/1.0e10 name=arg
  sel z=0.025*log(arg) name=DevPsi
  sel z=1.0e10*exp(DevPsi/0.025) name=Elec
  sel z=1.0e10*exp(-DevPsi/0.025) name=Hole
 
solve
  device
  device
  puts "Electron Flux [contact name=top sol=Elec flux]"
  puts "Electron Flux [contact name=VSS sol=Elec flux]"
  puts "Hole Flux [contact name=top sol=Hole flux]"
  puts "Hole Flux [contact name=VSS sol=Hole flux]"
#Plot the equilibrium concentration profiles
foreach var {Doping Elec Hole} {
    sel z=log10(abs($var+1.0))
    plot.1d !cle
}


Plot the concentration profiles of the initial doping and electrons and holes at equilibrium
Ramp the DC Bias to make I-V plot
sel z=log10(abs(Doping))
  #initialize an array, bias (Vb) and counter (i), and create and new graph window
plot.1d
sel z=log10(Elec)
  plot.1d !cle
sel z=log10(Hole)
plot.1d !cle
 
initialize an array, bias (Vb) and counter (i), and create and new graph window
  array set curr {}
  array set curr {}
  set Vb 0.0
  #set Vb 0.0
set i 1
#Ramp from 0.0-1.2V and Plot
  set Win [CreateGraphWindow]
  set Win [CreateGraphWindow]
  set i 1
  for {set bias 0.0} {$bias < 1.2} {set bias [expr $bias+0.05]} {
    set Vbias($i) -$bias
    contact name=VSS supply=-$bias
    device init
    set curr($i) [expr ([contact name=VSS sol=Elec flux] - [contact name=VSS sol=Hole flux])]
    sel z=log10(abs(Hole)+1.0)
    plot.1d !cle
    AddtoLine $Win IV -$bias $curr($i)
    incr i
}
#Get the last few points on the IV curve to use for linear extrapolation of the built-in voltage
set l [list "$Vbias(24)" "$curr(24)" "$Vbias(23)" "$curr(23)" "$Vbias(22)" "$curr(22)" ]
#Fit the data points with "Bestline". The output will give the x-intercept or built-in voltage
Bestline $l
#Create a "fit" line to plot on top of IV curve using the data points and "Bestline" x-intercept result
set line [list "$Vbias(24)" "$curr(24)" "$Vbias(23)" "$curr(23)" "$Vbias(22)" "$curr(22)" -0.99919 0]
CreateSingleLine  $Win Vbi_fit $line


For loop that plots the IV curve of the diode in forward bias from 0V to 1.2V
for {set Vb 0.0} {$Vb < 1.2} {set Vb [expr $Vb+0.05]} {
    contact name=top supply = -$Vb
set Vbias($i) -$Vb 
device init
set curr($i) [expr ([contact name=top sol=Elec flux] - [contact name=top sol=Hole flux])]
plot.1d !cle
AddtoLine $Win IV -$Vb $curr($i)
incr i
}


Get the last few points on the IV curve to use for linear extrapolation of the built-in voltage
In forward bias (negative voltage applied to the top (n-type) contact), the output IV plot with the absolute value of the built-in voltage equal to 0.9998 is shown below. The built in voltage calculated by the equation Vbi=Vt*ln((Nd*Na)/ni^2) is 0.9786.
  set l [list "$Vbias(24)" "$curr(24)" "$Vbias(23)" "$curr(23)" "$Vbias(22)" "$curr(22)" ]


Fit the data points with "Bestline". The output will give the x-intercept or built-in voltage
[[Image:pn_IV_2.jpg]]
Bestline $l


Create a "fit" line to plot on top of IV curve using the data points and "Bestline" x-intercept result
== Full Deck Without Explanations ==
set line [list "$Vbias(24)" "$curr(24)" "$Vbias(23)" "$curr(23)" "$Vbias(22)" "$curr(22)" 0.9998 0]  
Copy-paste [[PN diode (1D) - full deck | this entire deck]] into a file (for example, 1dpndiode.tcl) to make running it easy. Use the [[Startup Script | startup script]] to alias your paths to the floods executable. Then, on the BASH and then flooxs command line type:
  CreateSingleLine $Win Vbi_fit $line
  $ floods
  flooxs> source 1dpndiode.tcl


== Exercises ==


The output IV plot with built-in voltage equal to 0.9998.  The built in voltage calculated by the equation Vbi=Vt*ln((Nd*Na)/ni^2) is 0.9786.
== Notes ==
[[Image:pn_IV.jpg]]

Latest revision as of 15:54, 17 November 2010

This example builds on the 1D resistor example, showing how to create a floods structure with a doping profile that varies with x. After solving, the example compares floods's numerical results with an analytical solution.

New Concepts

  • refining the grid with non-tagged lines
  • Doping=f(x) : use "sel z="
  • "sel z=" if-then-else syntax (?:)
  • tcl "foreach" and "array"

1D PN Diode Deck

Create 1D structure - explanation 

#Grid
line x loc=0.0 spac=0.1 tag=Top
line x loc=0.5 spac=0.01
line x loc=1.0 spac=0.1 tag=Bottom

mater add name=Silicon
region Silicon xlo=Top xhi=Bottom
init

#Contacts
contact name=VSS Silicon xlo=-0.1 xhi=0.1 add
contact name=GND Silicon xlo=0.9  xhi=1.1 add

Declare solution variables 

DevicePackage
solution add name=DevPsi pde solve negative damp
solution add name=Elec   pde solve !negative
solution add name=Hole   pde solve !negative

Define constants 

set T 300.0
set k 1.38066e-23
set q 1.619e-19
set Vt [expr {$k*$T/$q}]
set ni 1.1e10
set esi [expr 11.8 * 8.85418e-14]
set eps [expr $esi / $q]
set Emob 350.0
set Hmob 150.0
set small 1.0e-10

Ionized dopant profile - explanation 

sel z=1.0e20*(x<0.5) name=Nd
sel z=1.0e17 name=Na
sel z=(Nd-Na) name=Doping

#plot doping
sel z=Doping
plot.1d symb=1

Bulk Equations 

set eqnP "$eps * grad(DevPsi) + Doping - Elec + Hole"
set eqnE "ddt(Elec) - ($Emob) * $Vt * sgrad(Elec, DevPsi/$Vt)"
set eqnH "ddt(Hole) - ($Hmob) * $Vt * sgrad(Hole, -DevPsi/$Vt)"
pdbSetString Silicon DevPsi Equation $eqnP
pdbSetString Silicon Elec   Equation $eqnE
pdbSetString Silicon Hole   Equation $eqnH 

pdbSetDouble Silicon DevPsi DampValue $Vt
pdbSetDouble Silicon DevPsi Abs.Error 1.0e-9
pdbSetDouble Silicon Elec   Abs.Error 1.0e-5
pdbSetDouble Silicon Hole   Abs.Error 1.0e-5

Contact Equations 

proc OhmicContact {Contact} {
    global Vt ni
    pdbSetBoolean $Contact Elec Flux 1
    pdbSetBoolean $Contact Hole Flux 1
    pdbSetBoolean $Contact DevPsi Flux 1
    pdbSetBoolean $Contact Elec Fixed 1
    pdbSetBoolean $Contact Hole Fixed 1
    pdbSetBoolean $Contact DevPsi Fixed 1
    pdbSetDouble $Contact Elec Flux.Scale 1.619e-19
    pdbSetDouble $Contact Hole Flux.Scale 1.619e-19
    pdbSetString $Contact DevPsi Equation "Nd - Na - Elec + Hole"
    pdbSetString $Contact Elec Equation "DevPsi - $Vt*log((Elec)/$ni) -$Contact"
    pdbSetString $Contact Hole Equation "DevPsi + $Vt*log((Hole)/$ni) -$Contact"
}
OhmicContact VSS
OhmicContact GND

Initial Conditions - explanation 

#Bias contacts
contact name=VSS voltage supply=0.0
contact name=GND voltage supply=0.0

#Initial Guess
sel z= {(Doping>0.0) 
            ?  ( 0.025*log( (Doping+$small) / $ni))
            :  (-0.025*log(-(Doping+$small) / $ni))} name = DevPsi
sel z=$ni*exp(DevPsi/$Vt)  name=Elec
sel z=$ni*exp(-DevPsi/$Vt) name=Hole

1st DC Solve at Equilibrium (0V) 

device
puts "Electron Flux [contact name=VSS sol=Elec flux]"
puts "Hole Flux [contact name=VSS sol=Hole flux]"

#Plot the equilibrium concentration profiles
foreach var {Doping Elec Hole} {
    sel z=log10(abs($var+1.0))
    plot.1d !cle
}

Ramp the DC Bias to make I-V plot 

#initialize an array, bias (Vb) and counter (i), and create and new graph window
array set curr {}
#set Vb 0.0
set i 1

#Ramp from 0.0-1.2V and Plot
set Win [CreateGraphWindow]
for {set bias 0.0} {$bias < 1.2} {set bias [expr $bias+0.05]} {
   set Vbias($i) -$bias

   contact name=VSS supply=-$bias
   device init

   set curr($i) [expr ([contact name=VSS sol=Elec flux] - [contact name=VSS sol=Hole flux])]

   sel z=log10(abs(Hole)+1.0)
   plot.1d !cle

   AddtoLine $Win IV -$bias $curr($i)
   incr i
}

#Get the last few points on the IV curve to use for linear extrapolation of the built-in voltage
set l [list "$Vbias(24)" "$curr(24)" "$Vbias(23)" "$curr(23)" "$Vbias(22)" "$curr(22)" ]

#Fit the data points with "Bestline". The output will give the x-intercept or built-in voltage
Bestline $l

#Create a "fit" line to plot on top of IV curve using the data points and "Bestline" x-intercept result
set line [list "$Vbias(24)" "$curr(24)" "$Vbias(23)" "$curr(23)" "$Vbias(22)" "$curr(22)" -0.99919 0] 
CreateSingleLine  $Win Vbi_fit $line


In forward bias (negative voltage applied to the top (n-type) contact), the output IV plot with the absolute value of the built-in voltage equal to 0.9998 is shown below. The built in voltage calculated by the equation Vbi=Vt*ln((Nd*Na)/ni^2) is 0.9786.

Full Deck Without Explanations

Copy-paste this entire deck into a file (for example, 1dpndiode.tcl) to make running it easy. Use the startup script to alias your paths to the floods executable. Then, on the BASH and then flooxs command line type: 

$ floods
flooxs> source 1dpndiode.tcl

Exercises

Notes

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