E-Beam Evaporation Recipes: Difference between revisions

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{{recipes|Vacuum Deposition}}
{{recipes|Vacuum Deposition}}
= Vapor Pressure Chart =
=Vapor Pressure Chart and Materials Deposition Table=

*[[media:Vapor-Pressure-Chart.xlsx|Vapor Pressure of Metals (Excel)]]
*[[Media:Vapor-Pressure-Chart-2.xlsx|Vapor Pressure of Metals (Excel)]]
*[http://www.lesker.com/newweb/deposition_materials/MaterialDeposition.cfm?pgid=0#| Lesker Deposition Table]

=Aluminum Deposition=

*[[Media:Al-thickness-variation-with-rate.jpg|Al thickness change with deposition rate]]

*[[Media:Al-AFM-Variation-Deposition-Rate-Rev1.pdf|Morphology Variation with Deposition Rate - Ebeam 1]]


=[[E-Beam 1 (Sharon)]]=
=[[E-Beam 1 (Sharon)]]=
==Ar-Ion Beam Source==

*[[Media:Argon-ion-beam-etching-ebeam1-procedure-data-revA.pdf|Procedure and data for ion-mill in ebeam1]]

==Materials Table (E-Beam #1)==
==Materials Table (E-Beam #1)==
''There are four hearth "positions" able to be loaded at any one time, meaning only up to 4 materials can be evaporated without breaking vacuum. Now able to handle Four-4" wafers in one run.''
{| border="1" style="border: 1px solid #D0E7FF; background-color:#ffffff; text-align:center; font-size: 95%" class="collapsible wikitable"
{| class="wikitable sortable collapsible" style="border: 1px solid #D0E7FF; background-color:#ffffff; text-align:center; font-size: 95%" border="1"
|-
! colspan=8 width=1100 height=35 bgcolor="#D0E7FF" align="center"|<div style="font-size: 150%;">Materials Table</div>
|- bgcolor="#D0E7FF"
|- bgcolor="#D0E7FF"
! width="75" bgcolor="#D0E7FF" align="center" | '''Material'''
! width="75" bgcolor="#D0E7FF" align="center" |'''Material'''
! width="75" bgcolor="#D0E7FF" align="center" | '''Position'''
! width="75" bgcolor="#D0E7FF" align="center" |'''Position'''
! width="75" bgcolor="#D0E7FF" align="center" | '''Hearth / Crucible'''
! width="75" bgcolor="#D0E7FF" align="center" |'''Hearth / Crucible'''
! width="85" bgcolor="#D0E7FF" align="center" | '''Film Number'''
! width="75" bgcolor="#D0E7FF" align="center" |'''Density'''
! width="75" bgcolor="#D0E7FF" align="center" | '''Density'''
! width="75" bgcolor="#D0E7FF" align="center" |'''Z Ratio'''
! width="75" bgcolor="#D0E7FF" align="center" | '''Z Ratio'''
! width="75" bgcolor="#D0E7FF" align="center" |'''Tooling'''
! width="75" bgcolor="#D0E7FF" align="center" | '''Tooling'''
! width="500" bgcolor="#D0E7FF" align="center" |'''Comments'''
! width="500" bgcolor="#D0E7FF" align="center" | '''Comments'''
|-
|-
| Ag
|Ag
|7 (6, 7, 8)
| 4
| C
|C
| 5
|10.5
| 10.5
|0.529
|110
| 0.524
|
| 140
| Brian, could you please check this table? Z ratio should be 0.529
|-
|-
| Al
|Al
| 2
|1
| C
|C
| 6
|2.7
| 2.7
|1.080
|102
| 1.080
|
| 118
|
|-
|-
| Al<sub>2</sub>O<sub>3</sub>
|Al<sub>2</sub>O<sub>3</sub>
|(6, 7, 8)
| 1
| C
|C
|3.97
| 6
| 3.97
|0.336
|
| 0.50
|
| 169
| Z-ratio should be 0.336
|-
|-
| Au
|Au
| 4
|3
| C
|C
|19.3
| 4
| 19.3
|0.381
|92
| 0.381
|Bazookas can be used at 20-30Å/sec.
| 138
| Bazookas can be used at 20-30Å/sec.
|-
|-
| AuGe
|AuGe
|(6, 7, 8)
| 3
| C
|C
|17.63
| 5
| 17.63
|0.397
|
| 0.397
|Composition unpredictable unless you practically empty the crucible.
| 151
| Composition unpredictable unless you practically empty the crucible.
|-
|-
| Cr
|C
|(6, 7, 8)
| 3
| H
|H
|2.250
| 6
| 7.2
|3.260
|
| 0.305
|Carbon. Must sweep beam. 1Å/sec (fluctuating 0.4–0.9Å/sec) at ~1.4–1.6 emission.
| 140
| Do not evaporate more than 200Å of Cr in the E-Beam evaporator.
|-
|-
| Fe
|Co
|(6, 7, 8)
|
|
|C
|
|8.9
| 7.86
|0.343
|
| 0.349
|'''Use only with permission'''
|
|
|-
|-
| Ge
|Fe
|(6, 7, 8)
| 3
| C
|
|7.86
| 6
| 5.35
|0.349
|
| 0.516
|
| 130
|
|-
|-
|Ge
| MgO
|8 (6, 7, 8)
| 1
|
|C
|5.35
| 6
| 3.58
|0.516
|
| 0.411
|
|
|
|-
|-
| Mo
|Gd
|(6, 7, 8)
|
|
|H
|7.89
|
| 10.2
|0.670
|
| 0.257
|'''Use only with permission'''
| 140
|
|
|-
|-
| Ni
|MgO
|(6, 7, 8)
| 1
| H
|
|3.58
| 1
| 8.91
|0.411
|
| 0.331
|'''Use only with permission'''
| 140
| Prone to spitting. Cool down for 15 minutes before venting.
|-
|-
|Mo
| NiCr
|(6, 7, 8)
| 1
| H
|
|10.2
| 6
| 8.23
|0.257
|
| 0.321
|
|
| Density 8.52, z ratio 0.3258
|-
|-
| Nb
|Ni
| 4
|5
| C
|H
|8.91
| 6
| 8.57
|0.331
|104
| 0.516 ( should be 0.492)
|Prone to spitting. Cool down for 15 minutes before venting.
|
| Cool down for at least 35 minutes before venting.
|-
|-
|NiCr
| Pd
|(6, 7, 8)
| 1
| H
|H
|8.50
| 9
|0.3258
| 12.0
|
| 0.357
|Density and z-ratio for Nichrome IV
| 140
|
|-
|-
| Pt
|Nb
|(6, 7, 8)
| 1
| C
|C
| 8
|8.57
|0.516 ( should be 0.492)
| 21.40
|
| 0.245
|Cool down for at least 35 minutes before venting.
| 140
| Prone to spitting. Evaporate at 1.5Å/sec or less.
|-
|-
| Si
|Pd
|6 (6, 7, 8)
| 2
| H
|H
|12.0
| 2
| 2.32
|0.357
|112
| 0.712
|
| 150
| Cool down very slowly after evaporating lest you crack the source.
|-
|-
|Pt
| SiO
|
|4
| C
|C
|21.40
| 6
| 2.13
|0.245
|100
| 0.87
|Prone to spitting. Evaporate at 1.5Å/sec or less.
| 132
|
|-
|-
|Ru
| SiO<sub>2</sub>
|(6, 7, 8)
| 1
| C
|C
|12.362
| 6
|0.182
| 2.2 ( should be 2.648)
|
| 1.07 ( should be 1.000)
|Prone to spitting. Evaporate at 1.0Å/sec or less. Cool down for 20 minutes before venting.
| 140
| Please change the crystal and the upper mirror after evaporating oxide.
|-
|-
|Si
| SrF<sub>2</sub>
|(6, 7, 8)
| 1
| C
|H
|2.32
| 6
| 4.28
|0.712
|
| 0.727
|Cool down very slowly after evaporating lest you crack the source.
| 140
|
|-
|-
| Ta
|SiO
|(6, 7, 8)
| 1
| H
|C
|2.13
| 6
| 16.6
|0.87
|
| 0.262
|'''Use only with permission'''
|
| Requires extremely high current. Minimum 35 minute cool down. Hearth #3 may be used. Call me before you try Ta.
|-
|-
|SiO<sub>2</sub>
| W
|(6, 7, 8)
| 1
| C
|C
|2.648
| 6
| 19.3
|1.00
|
| 0.163
|'''Use only with permission.'''
| 138
Please change the crystal and the upper mirror after evaporating oxide. Density 2.2-2.7 according to thin film dep. table.
|
|-
|-
|SrF<sub>2</sub>
| Ti
|(6, 7, 8)
| 3
| H
|C
|4.28
| 3
| 4.50
|0.727
|
| 0.628
|'''Use only with permission'''
| 139
|
|-
|Ta
|(6, 7, 8)
|H
|16.6
|0.262
|
|Requires extremely high current. Minimum 35 minute cool down. Hearth #3 may be used. Call maintainer before you try Ta.
|-
|W
|(6, 7, 8)
|C
|19.3
|0.163
|
|
|-
|Ti
|2
|H
|4.50
|0.628
|109
|
|}
|}


=[[E-Beam 2 (Custom)]]=
=[[E-Beam 2 (Custom)]]=
==Materials Table (E-Beam #2)==
==Materials Table (E-Beam #2)==
'''NOTE these recipes are outdated since gun upgrade 2020 - new data to be added soon.'''
{| border="1" style="border: 1px solid #D0E7FF; background-color:#ffffff; text-align:center; font-size: 95%" class="collapsible wikitable"
{| class="wikitable sortable collapsible" style="border: 1px solid #D0E7FF; background-color:#ffffff; text-align:center; font-size: 95%" border="1"
|-
! colspan=5 width=1300 height=35 bgcolor="#D0E7FF" align="center"|<div style="font-size: 150%;">Materials Table</div>
|- bgcolor="#D0E7FF"
|- bgcolor="#D0E7FF"
! width="45" bgcolor="#D0E7FF" align="center" | '''Material'''
! width="45" bgcolor="#D0E7FF" align="center" |'''Material'''
! width="45" bgcolor="#D0E7FF" align="center" | '''Density, g/cm3'''
! width="45" bgcolor="#D0E7FF" align="center" |'''Density, g/cm3'''
! width="45" bgcolor="#D0E7FF" align="center" | '''Z Ratio'''
! width="45" bgcolor="#D0E7FF" align="center" |'''Z Ratio'''
! width="45" bgcolor="#D0E7FF" align="center" | '''Tooling factor, %'''
! width="45" bgcolor="#D0E7FF" align="center" |'''Tooling factor, %'''
! width="100" bgcolor="#D0E7FF" align="center" | '''Comments'''
! width="100" bgcolor="#D0E7FF" align="center" |'''Comments'''
|-
|-
|Al<sub>2</sub>O<sub>3</sub>
|Al<sub>2</sub>O<sub>3</sub>
Line 234: Line 247:
|140.0
|140.0
|Tony could you please check this?
|Tony could you please check this?
|-
|CeO<sub>2</sub>
|7.13
|1.000
|252.0
|Deposition at room temperature (see the details in the following file)
|-
|CeO<sub>2</sub>
|7.13
|1.000
|117.0
|Deposition at 200 C (see the details in the following file)
|-
|CeO<sub>2</sub>
|7.13
|1.000
|99.7
|Deposition at 250 C (see the details in the following file)
|-
|-
|GeO<sub>2</sub>
|GeO<sub>2</sub>
Line 242: Line 273:
|-
|-
|ITO
|ITO
|7.16
|6.43-7.14
|1.000
|1.000
|139.0
|139.0
|z ratio unknown
|Density should be 6.43-7.14, z ratio?
|-
|-
|MgO
|MgO
Line 260: Line 291:
|-
|-
|SiO<sub>2</sub>
|SiO<sub>2</sub>
|2.20
|2.648
|1.070
|1.000
|157.6
|157.6
|Density 2.2-2.7 according to thin film deposition tables
|Should be 2.648, z ratio 1.000
|-
|-
|SiO<sub>x</sub>
|SiO<sub>x</sub>
Line 290: Line 321:
|-
|-
|}
|}

==ITO deposition (E-Beam 2)==

*[[Media:Rapid Thermal Annealing on Room-temperature grown ITO.pdf|Room-temperature ITO Deposition, Annealing, and Electrical and Optical Properties]]
*[[Media:ITO film-200C-O2-35sccm-EBeam2.pdf|ITO Deposition at 200 C]]

==CeO<sub>2</sub> deposition (E-Beam 2)==

*[[Media:CeO2 Deposition-EBeam2.pdf|Room- and High-temperature CeO<sub>2</sub> Depositions with and without an Additional Oxygen Gas Flow]]


=[[E-Beam 3 (Temescal)]]=
=[[E-Beam 3 (Temescal)]]=
==Materials Table (E-Beam #3)==
==Materials Table (E-Beam #3)==
''The following materials are always installed in the evaporator. There are 4 materials available on each gun (front/rear guns), allowing for co-deposition by running both guns simultaneously.''
{| border="1" style="border: 1px solid #D0E7FF; background-color:#ffffff; text-align:center; font-size: 95%" class="collapsible wikitable"
{| class="wikitable sortable collapsible" style="border: 1px solid #D0E7FF; background-color:#ffffff; text-align:center; font-size: 95%" border="1"
|-
|-
! colspan=9 width=1300 height=35 bgcolor="#D0E7FF" align="center"|<div style="font-size: 150%;">Materials Table</div>
|- bgcolor="#D0E7FF"
|- bgcolor="#D0E7FF"
! width="45" bgcolor="#D0E7FF" align="center" | '''Material'''
! width="45" bgcolor="#D0E7FF" align="center" |'''Material'''
! width="45" bgcolor="#D0E7FF" align="center" | '''Gun'''
! width="45" bgcolor="#D0E7FF" align="center" |'''Gun'''
! width="45" bgcolor="#D0E7FF" align="center" | '''Hearth /Crucible'''
! width="45" bgcolor="#D0E7FF" align="center" |'''Hearth /Crucible'''
! width="45" bgcolor="#D0E7FF" align="center" | '''Process Gain, A/sec/%pwr'''
! width="45" bgcolor="#D0E7FF" align="center" |'''Process Gain, A/sec/%pwr'''
! width="45" bgcolor="#D0E7FF" align="center" | '''Film Number'''
! width="45" bgcolor="#D0E7FF" align="center" |'''Film Number'''
! width="45" bgcolor="#D0E7FF" align="center" | '''Density, g/cm3'''
! width="45" bgcolor="#D0E7FF" align="center" |'''Density, g/cm3'''
! width="45" bgcolor="#D0E7FF" align="center" | '''Z Ratio'''
! width="45" bgcolor="#D0E7FF" align="center" |'''Z Ratio'''
! width="45" bgcolor="#D0E7FF" align="center" | '''Tooling, %'''
! width="45" bgcolor="#D0E7FF" align="center" |'''Tooling, %'''
! width="100" bgcolor="#D0E7FF" align="center" | '''Comments'''
! width="100" bgcolor="#D0E7FF" align="center" |'''Comments'''
|-
|-
|Ag
|Au
|Front
| Rear
| C
|C
| 10.0
|2.0
| 2
|3
|10.50
|19.30
| 0.529
|0.381
| 67
|56
|
|
|-
|-
| Al
|Ni
|Front
| Rear
| C
|C
| 10.0
|0.5
| 1
|2
|2.70
|8.91
| 1.080
|0.331
| 53
|67
|
|
|-
|-
| Au
|Pt
| Front
|Front
| C
|C
| 2.0
|0.4
| 3
|1
|19.30
|21.40
| 0.381
|0.245
| 56
|67
|
|
|-
|-
| Ge
|Ti
|Front
| Rear
| C
|C
| 10.0
|5.0
| 3
|4
|5.35
|4.50
| 0.516
|0.628
| 80
|67
|
|
|-
|-
| Ni
|Ag
|Rear
| Front
| C
|C
| 0.5
|10.0
| 2
|2
|8.91
|10.50
| 0.331
|0.529
| 67
|67
|
|
|-
|-
| Pd
|Al
| Rear
|Rear
| C
|C
| 0.9
|10.0
| 4
|1
|12.038
|2.70
| 0.357
|1.080
| 48
|53
|
|
|-
|-
| Pt
|Ge
|Rear
| Front
| C
|C
| 0.4
|10.0
| 1
|3
|21.40
|5.35
| 0.245
|0.516
| 67
|80
|
|
|-
|-
| Ti
|Pd
|Rear
| Front
| C
|C
| 5.0
|0.9
| 4
|4
|4.50
|12.038
| 0.628
|0.357
| 67
|48
|
|
|-
|-
Line 391: Line 431:
=[[E-Beam 4 (CHA)]]=
=[[E-Beam 4 (CHA)]]=
==Materials Table (E-Beam #4)==
==Materials Table (E-Beam #4)==
{| border="1" style="border: 1px solid #D0E7FF; background-color:#ffffff; text-align:center; font-size: 95%" class="collapsible wikitable"
{| class="wikitable sortable collapsible" style="border: 1px solid #D0E7FF; background-color:#ffffff; text-align:center; font-size: 95%" border="1"
|-
! colspan=6 width=1300 height=35 bgcolor="#D0E7FF" align="center"|<div style="font-size: 150%;">Materials Table</div>
|- bgcolor="#D0E7FF"
|- bgcolor="#D0E7FF"
! width="45" bgcolor="#D0E7FF" align="center" | '''Material'''
! width="45" bgcolor="#D0E7FF" align="center" |'''Material'''
! width="45" bgcolor="#D0E7FF" align="center" | '''Density, g/cm3'''
! width="45" bgcolor="#D0E7FF" align="center" |'''Density, g/cm3'''
! width="45" bgcolor="#D0E7FF" align="center" | '''Z Ratio'''
! width="45" bgcolor="#D0E7FF" align="center" |'''Z Ratio'''
! width="45" bgcolor="#D0E7FF" align="center" | '''Master tooling, %'''
! width="45" bgcolor="#D0E7FF" align="center" |'''Master tooling, %'''
! width="45" bgcolor="#D0E7FF" align="center" | '''Process Gain, A/sec/%pwr'''
! width="45" bgcolor="#D0E7FF" align="center" |'''Process Gain, A/sec/%pwr'''
! width="100" bgcolor="#D0E7FF" align="center" | '''Comments'''
! width="100" bgcolor="#D0E7FF" align="center" |'''Comments'''
|-
|-
|Ag
|Ag
| 10.50
|10.50
| 0.529
|0.529
|110
|110
|10.0
|10.0
|
|Tony, could you please check this?
|-
|-
|Al
|Al
| 2.70
|2.70
| 1.080
|1.080
|165
|110
|6.0
|6.0
|updated 9/1/2021
|
|-
|-
|Au
|Au
|19.30
|19.30
| 0.381
|0.381
|120
|120
|10.0
|10.0
Line 425: Line 463:
|Co
|Co
|8.90
|8.90
| 0.343
|0.343
|150
|150
|5.0
|5.0
Line 432: Line 470:
|Cr
|Cr
|7.20
|7.20
| 0.305
|0.305
|140
|140
|10.0
|10.0
Line 439: Line 477:
|Fe
|Fe
|7.86
|7.86
| 0.349
|0.349
|165
|165
|10.0
|10.0
Line 446: Line 484:
|Ge
|Ge
|5.35
|5.35
| 0.516
|0.516
|126
|126
|10.0
|10.0
Line 453: Line 491:
|Hf
|Hf
|13.09
|13.09
| 0.360
|0.360
|150
|150
|10.0
|10.0
Line 460: Line 498:
|Ir
|Ir
|22.40
|22.40
| 0.129
|0.129
|130
|130
|10.0
|10.0
Line 467: Line 505:
|Ni
|Ni
|8.91
|8.91
| 0.331
|0.331
|150
|150
|5.0
|5.0
Line 473: Line 511:
|-
|-
|NiCr
|NiCr
|8.23
|8.50
| 0.321
|0.3258
|140
|140
|10.0
|10.0
|density should be 8.50, z ratio 0.3258
|density and z ratio for Nichrome IV
|-
|-
|NiFe
|NiFe

Latest revision as of 18:59, 25 October 2022

Back to Vacuum Deposition Recipes.

Vapor Pressure Chart and Materials Deposition Table

Aluminum Deposition

E-Beam 1 (Sharon)

Ar-Ion Beam Source

Materials Table (E-Beam #1)

There are four hearth "positions" able to be loaded at any one time, meaning only up to 4 materials can be evaporated without breaking vacuum. Now able to handle Four-4" wafers in one run.

Material Position Hearth / Crucible Density Z Ratio Tooling Comments
Ag 7 (6, 7, 8) C 10.5 0.529 110
Al 1 C 2.7 1.080 102
Al2O3 (6, 7, 8) C 3.97 0.336
Au 3 C 19.3 0.381 92 Bazookas can be used at 20-30Å/sec.
AuGe (6, 7, 8) C 17.63 0.397 Composition unpredictable unless you practically empty the crucible.
C (6, 7, 8) H 2.250 3.260 Carbon. Must sweep beam. 1Å/sec (fluctuating 0.4–0.9Å/sec) at ~1.4–1.6 emission.
Co (6, 7, 8) C 8.9 0.343 Use only with permission
Fe (6, 7, 8) 7.86 0.349
Ge 8 (6, 7, 8) C 5.35 0.516
Gd (6, 7, 8) H 7.89 0.670 Use only with permission
MgO (6, 7, 8) 3.58 0.411 Use only with permission
Mo (6, 7, 8) 10.2 0.257
Ni 5 H 8.91 0.331 104 Prone to spitting. Cool down for 15 minutes before venting.
NiCr (6, 7, 8) H 8.50 0.3258 Density and z-ratio for Nichrome IV
Nb (6, 7, 8) C 8.57 0.516 ( should be 0.492) Cool down for at least 35 minutes before venting.
Pd 6 (6, 7, 8) H 12.0 0.357 112
Pt 4 C 21.40 0.245 100 Prone to spitting. Evaporate at 1.5Å/sec or less.
Ru (6, 7, 8) C 12.362 0.182 Prone to spitting. Evaporate at 1.0Å/sec or less. Cool down for 20 minutes before venting.
Si (6, 7, 8) H 2.32 0.712 Cool down very slowly after evaporating lest you crack the source.
SiO (6, 7, 8) C 2.13 0.87 Use only with permission
SiO2 (6, 7, 8) C 2.648 1.00 Use only with permission.

Please change the crystal and the upper mirror after evaporating oxide. Density 2.2-2.7 according to thin film dep. table.

SrF2 (6, 7, 8) C 4.28 0.727 Use only with permission
Ta (6, 7, 8) H 16.6 0.262 Requires extremely high current. Minimum 35 minute cool down. Hearth #3 may be used. Call maintainer before you try Ta.
W (6, 7, 8) C 19.3 0.163
Ti 2 H 4.50 0.628 109

E-Beam 2 (Custom)

Materials Table (E-Beam #2)

NOTE these recipes are outdated since gun upgrade 2020 - new data to be added soon.
Material Density, g/cm3 Z Ratio Tooling factor, % Comments
Al2O3 3.97 0.336 140.0 Tony could you please check this?
CeO2 7.13 1.000 252.0 Deposition at room temperature (see the details in the following file)
CeO2 7.13 1.000 117.0 Deposition at 200 C (see the details in the following file)
CeO2 7.13 1.000 99.7 Deposition at 250 C (see the details in the following file)
GeO2 6.24 1.000 139.0
ITO 6.43-7.14 1.000 139.0 z ratio unknown
MgO 3.58 0.411 157.6 OK
Si 2.32 0.712 150.0
SiO2 2.648 1.000 157.6 Density 2.2-2.7 according to thin film deposition tables
SiOx 2.13 0.87 130.0
SrF2 4.28 0.727 140.0
Ta2O5 8.2 0.30 157.6
TiO2 4.26 0.400 139.0

ITO deposition (E-Beam 2)

CeO2 deposition (E-Beam 2)

E-Beam 3 (Temescal)

Materials Table (E-Beam #3)

The following materials are always installed in the evaporator. There are 4 materials available on each gun (front/rear guns), allowing for co-deposition by running both guns simultaneously.

Material Gun Hearth /Crucible Process Gain, A/sec/%pwr Film Number Density, g/cm3 Z Ratio Tooling, % Comments
Au Front C 2.0 3 19.30 0.381 56
Ni Front C 0.5 2 8.91 0.331 67
Pt Front C 0.4 1 21.40 0.245 67
Ti Front C 5.0 4 4.50 0.628 67
Ag Rear C 10.0 2 10.50 0.529 67
Al Rear C 10.0 1 2.70 1.080 53
Ge Rear C 10.0 3 5.35 0.516 80
Pd Rear C 0.9 4 12.038 0.357 48

E-Beam 4 (CHA)

Materials Table (E-Beam #4)

Material Density, g/cm3 Z Ratio Master tooling, % Process Gain, A/sec/%pwr Comments
Ag 10.50 0.529 110 10.0
Al 2.70 1.080 110 6.0 updated 9/1/2021
Au 19.30 0.381 120 10.0
Co 8.90 0.343 150 5.0
Cr 7.20 0.305 140 10.0
Fe 7.86 0.349 165 10.0
Ge 5.35 0.516 126 10.0
Hf 13.09 0.360 150 10.0
Ir 22.40 0.129 130 10.0
Ni 8.91 0.331 150 5.0
NiCr 8.50 0.3258 140 10.0 density and z ratio for Nichrome IV
NiFe 8.70 1.000 100 10.0
Pd 12.038 0.357 112 10.0
Pt 21.40 0.245 130 10.0
Ru 12.362 0.182 100 10.0
Ti 4.50 0.628 183 10.0
Zr 6.49 0.600 150 10.0