Specific Process Knowledge/Lithography/CSAR: Difference between revisions

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{|border="1" cellspacing="0" cellpadding="3" style="text-align:left;" width="90%"
|-
|-
|-style="background:Black; color:White"
|'''Resist'''
|'''Polarity'''
|'''Manufacturer'''
|'''Comments'''
|'''Technical reports'''
|'''Spinner'''
|'''Developer'''
|'''Rinse'''
|'''Remover'''
|'''Process flows (in docx-format)'''
|-
|-
|-style="background:White; color:black"
|'''[[Specific_Process_Knowledge/Lithography/CSAR|CSAR]]'''
|Positive
|[http://www.allresist.com AllResist]
|Standard positive resist, very similar to ZEP520.
|[[media:Allresist_CSAR62_English.pdf‎|Allresist_CSAR62_English.pdf‎]],, [[media:CSAR_62_Abstract_Allresist.pdf‎|CSAR_62_Abstract_Allresist.pdf‎]]
|[[Specific_Process_Knowledge/Lithography/Coaters#Manual Spinner 1|Manual Spinner 1 (Laurell)]], [[Specific_Process_Knowledge/Lithography/Coaters#Spin_coater:_Manual_Labspin|Spin Coater Labspin]]
|XAR-600-546, XAR-600-548, N50, MIBK:IPA
|IPA
|AR-600-71, 1165 Remover
|[[media:Process_Flow_CSAR.docx‎|Process_Flow_CSAR.docx‎]]
|}




Simple e-beam pattern in this resist has been tested, the results showed on this page. If you have questions to the process or wish to use this e-beam resist, please contact Tine Greibe at tigre@danchip.dtu.dk.


Simple e-beam pattern in this resist has been tested, the results showed on this page. If you have questions to the process or wish to use this e-beam resist, please contact [mailto:lithography@nanolab.dtu.dk lithography] at DTU Nanolab.


== Process Flow ==
{|border="1" cellspacing="0" cellpadding="3" style="text-align:left;" style="width: 80%;"
|-
|-
|-style="background:Black; color:White"
!Equipment
!Process Parameters
!Comments
|-
|-
|-style="background:White; color:black; text-align:center"
!colspan="4"|Pretreatment
|-
|-
|-style="background:LightGrey; color:black"
|4" Si wafers
|No Pretreatment
|
|-
|-
|-style="background:White; color:black; text-align:center"
!colspan="4"|Spin Coat
|-
|-
|-style="background:LightGrey; color:black"
|Spin Coater Manual, LabSpin, A-5
|AR-P 6200/2 AllResist E-beam resist
60 sec at various spin speed.
Acceleration 4000 s-2,
softbake 1 - 5 min at 150 deg Celcius
|Disposal pipette used; clean by N2-gun before use. Use approximately 1.5 ml per 4" wafer, never use a pipette twice. Softbake is not a crucial step, see e-mail correspondence with AllResist [[media:Softbake CSAR.pdf|here]].
|-
|-
|-style="background:White; color:black; text-align:center"
!colspan="4"|Characterization
|-
|-
|-style="background:LightGrey; color:black"
|Ellipsometer VASE B-1
|9 points measured on 100 mm wafer
|ZEP program used; measured at 70 deg only
|-
|-
|-style="background:White; color:black; text-align:center"
!colspan="4"|E-beam Exposure
|-
|-
|-style="background:LightGrey; color:black"
|JEOL 9500 E-beam writer, E-1
|Dosepattern 15nm - 100nm,
dose 120-350 muC/cm2
|Virtual chip mark height detection (CHIPAL V1) used in corner of every dose array
|-
|-
|-style="background:White; color:black; text-align:center"
!colspan="4"|Development
|-
|-
|-style="background:LightGrey; color:black"
|Fumehood, D-3
|60 sec in X AR 600-546,
60 sec rinse in IPA,
N2 Blow dry
|Gentle agitation while developing. After developing, wafer is immersed in beaker with IPA, subsequently blow dried with N2 gun.
|-
|-
|-style="background:White; color:black; text-align:center"
!colspan="4"|Characterization
|-
|-
|-style="background:LightGrey; color:black"
|Zeiss SEM Supra 60VP, D-3
|2-3 kV, shortest working distance possible, chip mounted with Al tape
|For dosepattern SEM inspection: the wafers are diced into smaller pieces and sputter coated with Pt at DTU CEN before SEM inspection; please contact [mailto:ramona.mateiu@cen.dtu.dk Ramona Valentina Mateiu] for further information.
|-
|}


== Spin Curves ==
== Spin Curves ==




[[File:SpinCurveCSAR.jpg|right|600px]]
The thickness is measured on VASE Ellipsometer using a simple Cauchy model for a transparent polymer on Si. The measurements are performed at one incidence angle (70 degrees) only. 9 points on each 4" wafer has been measured; the standard deviation thus representing the homogeinity of the film on the 4" wafers.  


The thickness is measured on VASE Ellipsometer using a simple Cauchy model for a transparent polymer on Si. The measurements are performed at one incidence angle (70 degrees) only. 9 points on each 4" wafer has been measured; the standard deviation thus representing the homogeinity of the film on the 4" wafers.  
Around 2 ml of resist per wafer has been used when fabricating these curves. If you use less than 2 ml, the thickness of the final resist might be smaller than reported here.


Please be aware that I have experienced a somewhat large thickness deviation (5-8 %) depending on the amount of resist applied to the wafer before spin coating.


<span style="color:#696969">'''Dosepattern has been e-beam exposured and SEM inspected on those wafers marked by silver gray.'''</span>
[[File:CSAR_09.png|right|600px]]
[[File:CSAR_18.png|right|600px]]




Line 149: Line 23:


|-
|-
|-style="background:Black; color:White"
|-style="background:#00308F; color:White"
!colspan="7"|AllResist AR-P 6200 (> 2ml per 4" wafer) spinning on Spin Coater: Manual LabSpin A-5, TIGRE, 09-04-2014. Softbake 5 min @ 150 degC.
!colspan="7"|AllResist AR-P 6200.09 (> 2ml per 4" wafer) spinning on Spin Coater: Manual LabSpin A-5, TIGRE, 09-04-2014. Softbake 5 min @ 150 degC.
|-
|-


|-
|-
|-style="background:Silver; color:black"
|-style="background:silver; color:black"
!Spin Speed [rpm]
!Spin Speed [rpm]
!Acceleration [1/s2]
!Acceleration [1/s2]
!Thickness [nm]
!Thickness [nm]
!St Dev
|-
|-


Line 165: Line 38:
|2000
|2000
|4000
|4000
|225.98
|226
|0.97
|-
|-


Line 173: Line 45:
|3000
|3000
|4000
|4000
|194.00
|194
|0.6
|-
|-


Line 181: Line 52:
|4000
|4000
|4000
|4000
|169.57
|170
|0.32
|-
|-


Line 189: Line 59:
|5000
|5000
|4000
|4000
|151.47
|151
|0.26
|-
|-


|-
|-
|-style="background:Silver; color:black"
|-style="background:WhiteSmoke; color:black"
|6000
|6000
|4000
|4000
|142.38
|142
|0.41
|-
|-


Line 205: Line 73:
|7000
|7000
|4000
|4000
|126.59
|127
|0.36
|-
|-


Line 217: Line 84:


|-
|-
|-style="background:green; color:White"
|-style="background:red; color:White"
!colspan="7"|AllResist CSAR (< 2ml per 4" wafer) on Spin Coater: Manual LabSpin A-5, TIGRE, 16-06-2014. Softbake 2 min @ 150 degC.
!colspan="7"|AllResist CSAR 6200.09 1:1 in anisole (< 2ml per 4" wafer), Spin Coater: Manual LabSpin A-5, TIGRE, 16-06-2014. Softbake 2 min @ 150 degC.
|-
|-


Line 226: Line 93:
!Acceleration [1/s2]
!Acceleration [1/s2]
!Thickness [nm]
!Thickness [nm]
!St Dev
|-
 
|-
|-style="background:WhiteSmoke; color:black"
|2000
|4000
|84
|-
|-


Line 233: Line 106:
|3000
|3000
|4000
|4000
|201.61
|67
|1.20
|-
|-


Line 241: Line 113:
|4000
|4000
|4000
|4000
|173.89
|59
|0.64
|-
|-


Line 249: Line 120:
|5000
|5000
|4000
|4000
|155.91
|53
|0.65
|-
 
|-
|-style="background:WhiteSmoke; color:black"
|6000
|4000
|49
|-
|-


Line 261: Line 138:


|-
|-
|-style="background:red; color:White"
|-style="background:green; color:White"
!colspan="7"|AllResist CSAR 1:1 in anisole (< 2ml per 4" wafer), Spin Coater: Manual LabSpin A-5, TIGRE, 16-06-2014. Softbake 2 min @ 150 degC.
!colspan="7"|AllResist CSAR 6200.18 (< 2ml per 4" wafer), Spin Coater: Manual Standard Resists, E-5, TIGRE, 15-06-2016. Softbake 2 min @ 180 degC.
|-
|-


Line 270: Line 147:
!Acceleration [1/s2]
!Acceleration [1/s2]
!Thickness [nm]
!Thickness [nm]
!St Dev
|-
|-


Line 276: Line 152:
|-style="background:WhiteSmoke; color:black"
|-style="background:WhiteSmoke; color:black"
|2000
|2000
|4000
|2000
|83.48
|1003
|0.49
|-
|-


Line 284: Line 159:
|-style="background:WhiteSmoke; color:black"
|-style="background:WhiteSmoke; color:black"
|3000
|3000
|4000
|2000
|67.12
|809
|0.41
|-
|-


Line 292: Line 166:
|-style="background:WhiteSmoke; color:black"
|-style="background:WhiteSmoke; color:black"
|4000
|4000
|4000
|2000
|58.64
|721
|0.44
|-
|-


|-
|-
|-style="background:Silver; color:black"
|-style="background:WhiteSmoke; color:black"
|5000
|5000
|4000
|2000
|53.13
|639
|0.39
|-
|-


Line 308: Line 180:
|-style="background:WhiteSmoke; color:black"
|-style="background:WhiteSmoke; color:black"
|6000
|6000
|4000
|2000
|48.76
|586
|0.38
|-
 
|-
|-style="background:WhiteSmoke; color:black"
|7000
|2000
|549
|-
|-


|}
|}


== Contrast Curves ==
<br>
<br>
<br>


100 nm lines in ~145 nm thick CSAR has been developed with AR-600-546 (standard CSAR developer) with and without agitation at room temperature and at 5 degrees Celsius. Furthermore, same pattern ahs been developed with N50 (standard developer for ZEP520A).
== Contrast Curve ==
 
=== CSAR 6200.09 ===
 
100 nm lines in both ~70 nm and ~188 nm thick CSAR has been developed with AR-600-546 (standard CSAR developer) at room temperature to provide the following contrast curves.


{|border="1" cellspacing="0" cellpadding="3" style="text-align:left;"  style="width: 95%"
{|border="1" cellspacing="0" cellpadding="3" style="text-align:left;"  style="width: 95%"
Line 324: Line 209:
|-
|-
|-style="background:Black; color:White"
|-style="background:Black; color:White"
!colspan="5"|wafer 9.19 Contrast Curve, Processed by TIGRE, Dec-Jan 2014-2015
!colspan="5"|CSAR Contrast Curve, Processed by TIGRE, FEB-MARCH 2016
|-
|-


Line 338: Line 223:
|-
|-
|-style="background:WhiteSmoke; color:black"
|-style="background:WhiteSmoke; color:black"
|CSAR AR-P6200 AllResist
|CSAR AR-P6200.09 AllResist, CSAR AR-P6200.09 diluted 1:1 in Anisole
|19-12-2014, LabSpin A-1, 4000 rpm, 60s, softbaked 60s @ 150degC
|08-02-2016, LabSpin E-5, 4000 rpm, 60s, softbaked 60s @ 205 degC
|19-12-2014, JBX9500 E-2, 2nA aperture 5, doses 60-600 µC/cm2, 100 nm lines with 300 nm spaces
|09-02-2016, JBX9500 E-2, 2nA aperture 5, doses 40-600 µC/cm2, 100 nm lines and 300 nm spaces
|22-12-2014, 05-01-2015, Fumehood D-2, misc developers, rinsed in IPA 60s. The cold development was performed with developer stored in refrigerator (Cx1), exact temperature was not measured.
|11-02-2016, Fumehood D-2, AR-600-546, rinsed in IPA 60s.
|23-12-2014, 05-01-2015, Zeiss Supra 60VP, 10kV, Inlens detector, stage at - 4-5 degrees. Samples '''not''' coated before inspection.
|02-03-2016 AFM Icon, F-2, ScanAsyst in Air
|-
|-


|}
|}


[[File:ContrastCurvesCSAR.png|500px]]
{| style="border: none; border-spacing: 0; margin: 1em auto; text-align: center;"
[[File:w919sa-d.png|500px]]
 
== Dosetests ==
 
So far (September 2014) three wafers with CSAR have been e-beam exposed with dosetests and inspected in SEM. Thickness of resist, e-beam dose and development time has been changed somewhat from wafer to wafer:
 
 
{|border="1" cellspacing="0" cellpadding="3" style="text-align:left;" style="width: 60%;"
|-
 
|-
|-style="background:Black; text-align:left; color:White"
!rowspan="2"|Process
!rowspan="2"|Equipment
!colspan="3"|Parameters
|-
 
|-
|-style="background:Black; text-align:left; color:White"
!6.13
!4.09
!3.05
|-
 
 
|-
|-style="background:WhiteSmoke; color:black"
|Resist
|Fumehood D-3
|'''Resist:''' AR-P 6200/2 diluted 1:1 in anisole (Bottled opened 16-06-2014 TIGRE)
|'''Resist:''' AR-P 6200/2 diluted 1:1 in anisole (Bottled opened 16-06-2014 TIGRE)
|'''Resist:''' AR-P 6200/2
|-
|-style="background:WhiteSmoke; color:black"
|Spin Coat
|Spin Coater LabSpin A-5
|'''Spin:''' 1 min @ 6000 rpm,<br /> '''softbake:''' 1 min @ 150 degC, <br />'''thickness:''' ~50nm <br />(27-08-2014 TIGRE)
|'''Spin:''' 1 min @ 5000 rpm,<br /> '''softbake:''' 2 min @ 150 degC, <br />'''thickness:''' ~53nm <br />(16-06-2014 TIGRE)
|'''Spin:''' 1 min @ 6000 rpm,<br /> '''softbake:''' 5 min @ 150 degC, <br />'''thickness:''' ~143nm <br />(09-04-2014 TIGRE)
|-
|-
|-style="background:WhiteSmoke; color:black"
|E-beam exposure
|JEOL 9500 E-2
|'''Condition file:''' 0.2nA_ap5,<br /> '''doses:''' 180-420 muC/cm2,<br /> '''Shot pitch:''' 7-27 nm,<br /> '''PEC:''' no <br />(27-08-2014 TIGRE)
|'''Condition file:''' 0.2nA_ap5,<br /> '''doses:''' 207-242 muC/cm2,<br /> '''Shot pitch:''' 5 nm,<br /> '''PEC:''' no <br />(02-07-2014 TIGRE)
|'''Condition file:''' 2nA_ap5,<br /> '''doses:''' 207-242 muC/cm2,<br /> '''Shot pitch:''' 5 nm,<br /> '''PEC:''' no <br />(10-04-2014 TIGRE)
|-
|-
|-style="background:WhiteSmoke; color:black"
|Develop
|Fumehood D-3
|'''Developer:''' SX-AR 600-54/6,<br /> '''time:''' 30 sec,<br /> '''Rinse:''' 30 sec in IPA<br /> (28-08-2014 TIGRE)
|'''Developer:''' SX-AR 600-54/6,<br /> '''time:''' 60 sec,<br /> '''Rinse:''' 30 sec in IPA<br /> (08-07-2014 TIGRE)
|'''Developer:''' SX-AR 600-54/6,<br /> '''time:''' 60 sec,<br /> '''Rinse:''' 60 sec in IPA<br /> (April/May-2014 TIGRE)
|-
|-
|-style="background:WhiteSmoke; color:black"
|Sputter Coat
|Cressington 208HR, DTU CEN, please contact [mailto:ramona.mateiu@cen.dtu.dk Ramona Valentina Mateiu] for information
|3-5 nm Pt, sputtering, (29-08-2014 TIGRE)
|3-5 nm Pt, sputtering (09-07-2014 TIGRE)
|3-5 nm Pt, sputtering (22-05-2014 TIGRE)
|-
|-
|-style="background:WhiteSmoke; color:black"
|Characterization
|Zeiss SEM Supra 60VP, D-3
|'''Acc voltage:''' 3 kV,<br /> '''WD:''' < 4mm, <br />conducting tape close to pattern (29-08-2014 TIGRE)
|'''Acc voltage:''' 3 kV,<br /> '''WD:''' < 4mm, <br />conducting tape close to pattern (09-07-2014 TIGRE)
|'''Acc voltage:''' 2 kV,<br /> '''WD:''' < 4mm, <br />conducting tape close to pattern (06-06-2014 TIGRE)
|-
|-
| [[image:ContrastCurvesCSAR_March2016_log.png|600px]]
|-
| colspan="1" style="text-align:center;|
AR-P 6200 contrast curves.
|}
|}


=== SEM inspection ===
==Dose to size==
Small features need a comparatively higher dose then big features and hence it can be useful to map out the dose and size dependency. Below is a set of cross sectional images of 100, 50 and 20 nm lines written 500, 250 and 180 nm resist at doses from 200 to 600 µC/cm<sup>2</sup>.


{| class="wikitable collapsible collapsed" style="border: 5px solid black;"  style="width: 90%;" align="center"  
{| style="border: none; border-spacing: 0; margin: 1em auto; text-align: center;"
!colspan="8"|  SEM inspection of wafer 6.13, 100 nm exposed pattern, shot pitch 7 nm
|-
|-
| [[image:thope240214_lines_100_06.png|1200px]]
|-
| [[image:thope240214_lines_50_11.png|1200px]]
|-
| [[image:thope240214_lines_20_13.png|1200px]]
|-  
|-  
! 300 [muC/cm2]
| colspan="1" style="text-align:center;|
| [[File:6_13_100nm_300_shot14.png|200px]]
Cross section SEM images of 500 nm AR-P 6200.09 exposed at 200-600 µC/cm<sup>2</sup>. Top image is 100 nm lines, center image is 50 nm lines, bottom image is 20 nm lines. Au coated for SEM imaging.
| [[File:6_13_100nm_300_shot14_Lines.png|200px]]
| [[File:6_13_100nm_300_shot14_Holes.png|200px]]
| [[File:6_13_100nm_300_shot14_Holes2.png|200px]]
| [[File:6_13_100nm_300_shot14_Pillars.png|200px]]
| [[File:6_13_100nm_300_shot14_Test.png|200px]]
! ACHK NOT READY
|-
|}
|}


{| class="wikitable collapsible collapsed" style="border: 5px solid black;"  style="width: 90%;" align="center"  
{| style="border: none; border-spacing: 0; margin: 1em auto; text-align: center;"
!colspan="7"|  SEM inspection of wafer 6.13, 50 nm exposed pattern, shot pitch 7 nm
|-
|-
|-
| [[image:thope240214_lines250_100nm.png|1200px]]
! 270 [muC/cm2]
| [[File:6_13_50nm_270_shot14.png|200px]]
| [[File:6_13_50nm_270_shot14_Lines.png|200px]]
| [[File:6_13_50nm_270_shot14_Holes.png|200px]]
| [[File:6_13_50nm_270_shot14_Pillars.png|200px]]
| [[File:6_13_50nm_270_shot14_Holes2.png|200px]]
! ACHK NOT READY
|-  
|-  
 
| [[image:thope240214_lines250_50nm.png|1200px]]
|-  
|-  
! 300 [muC/cm2]
| [[image:thope240214_lines250_20nm.png|1200px]]
| [[File:6_13_50nm_300_shot14.png|200px]]
| [[File:6_13_50nm_300_shot14_Lines.png|200px]]
| [[File:6_13_50nm_300_shot14_Holes.png|200px]]
| [[File:6_13_50nm_300_shot14_Pillars.png|200px]]
| [[File:6_13_50nm_300_shot14_Holes2.png|200px]]
! ACHK NOT READY
|-
|-
| colspan="1" style="text-align:center;|
Cross section SEM images of 250 nm AR-P 6200.09 exposed at 200-600 µC/cm<sup>2</sup>. Top image is 100 nm lines, center image is 50 nm lines, bottom image is 20 nm lines. Au coated for SEM imaging.
|}
|}


{| class="wikitable collapsible collapsed" style="border: 5px solid black;"  style="width: 90%;" align="center"  
{| style="border: none; border-spacing: 0; margin: 1em auto; text-align: center;"
!colspan="6"|  SEM inspection of wafer 6.13, 30 nm exposed pattern, shot pitch 7 nm
|-
|-
|-
! 240 [muC/cm2]
| [[image:thope240214_lines180_100_29.png|1200px]]
| [[File:6_13_30nm_240_shot14.png|200px]]
| [[File:6_13_30nm_240_shot14_Lines.png|200px]]
|
|
| ACHK NOT READY
|-
|-  
|-  
! 270 [muC/cm2]
| [[image:thope240214_lines180_50_31.png|1200px]]
| [[File:6_13_30nm_270_shot14.png|200px]]
| [[File:6_13_30nm_270_shot14_Lines.png|200px]]
| [[File:6_13_30nm_270_shot14_Holes.png|200px]]
| [[File:6_13_30nm_270_shot14_Pillars.png|200px]]
| ACHK NOT READY
|-  
|-  
| [[image:thope240214_lines180_20_33.png|1200px]]
|-  
|-  
! 300 [muC/cm2]
| colspan="1" style="text-align:center;|
| [[File:6_13_30nm_300_shot14.png|200px]]
Cross section SEM images of 180 nm AR-P 6200.09 exposed at 200-600 µC/cm<sup>2</sup>. Top image is 100 nm lines, center image is 50 nm lines, bottom image is 20 nm lines. Au coated for SEM imaging.
| [[File:6_13_30nm_300_shot14_Lines.png|200px]]
| [[File:6_13_30nm_300_shot14_Holes.png|200px]]
| [[File:6_13_30nm_300_shot14_Pillars.png|200px]]
| ACHK NOT READY
|-
|}
|}


{| class="wikitable collapsible collapsed" style="border: 5px solid black;"  style="width: 90%;" align="center"
=== CSAR 6200.18 ===
!colspan="4"|  SEM inspection of wafer 6.13, 20 nm exposed pattern, shot pitch 7 nm
 
|-
|-
! 270 [muC/cm2]
| [[File:6_13_20nm_270_shot14.png|200px]]
| [[File:6_13_20nm_270_shot14_Lines.png|200px]]
| ACHK NOT READY
|-
|-
! 300 [muC/cm2]
| [[File:6_13_20nm_300_shot14.png|200px]]
| [[File:6_13_20nm_300_shot14_Lines.png|200px]]
| ACHK NOT READY
|-
|}


100 nm lines in ~900 nm thick CSAR has been developed with AR-600-546 (standard CSAR developer) at room temperature.


[[File:CSAR 6200.18 developed with AR600546.png|right|400px]]


{| class="wikitable collapsible collapsed" style="border: 5px solid black;"  style="width: 90%;" align="center"
{|border="1" cellspacing="0" cellpadding="3" style="text-align:right;"  style="width: 60%"
!colspan="6"|  SEM inspection of wafer 4.09, 50 nm exposed pattern, shot pitch 5 nm
|-
|-
! 230 [muC/cm2]
| [[File:53nmCSAR50nmOverviewBasedose.png|250px]]
| [[File:53nmCSAR50nmLinesBasedose.png|250px]]
| [[File:53nmCSAR50nmHolesBasedose.png|250px]]
| [[File:53nmCSAR50nmPillarsBasedose.png|250px]]
| [[File:53nmCSAR50nmTestBasedose.png|250px]]
|}


{| class="wikitable collapsible collapsed" style="border: 5px solid black;"  style="width: 90%;" align="center"
!colspan="4"|  SEM inspection of wafer 4.09, 30 nm exposed pattern, shot pitch 5 nm
|-
|-
|-  
|-style="background:Black; color:White"
! 219 [muC/cm2]
!colspan="5"|CSAR Contrast Curve, Processed by TIGRE, JUNE 2016
| [[File:53nmCSAR30nmOverviewBasedose-5%.png|250px]]
| [[File:53nmCSAR30nmLinesBasedose-5%.png|250px]]
| [[File:30nmShot10.png|250px]]
|-
|-
|-
 
! 230 [muC/cm2]
| [[File:53nmCSAR30nmOverviewBasedose.png|250px]]
| [[File:53nmCSAR30nmLinesBasedose.png|250px]]
|
|-
|-
|-  
|-style="background:WhiteSmoke; color:black"
! 242 [muC/cm2]
!Resist
| [[File:53nmCSAR30nmOverviewBasedose+5%.png|250px]]
!Spin Coat
| [[File:53nmCSAR30nmLinesBasedose+5%.png|250px]]
!E-beam exposure
|
!Development
!Characterisation
|-
|-
|}


{| class="wikitable collapsible collapsed" style="border: 5px solid black;"  style="width: 90%;" align="center"
!colspan="4"|  SEM inspection of wafer 4.09, 20 nm exposed pattern, shot pitch 5 nm
|-
|-
|-  
|-style="background:WhiteSmoke; color:black"
! 230 [muC/cm2]
|CSAR AR-P6200.18 AllResist
| [[File:53nmCSAR20nmOverviewBasedose.png|220px]]
|15-06-2016, LabSpin E-5, 2000 rpm, 60s, softbaked 60s @ 205 degC
| [[File:53nmCSAR20nmLinesBasedose.png|220px]]
|15-06-2016, JBX9500 E-2, 2nA aperture 5, doses 40-600 µC/cm2, 100 nm lines and 300 nm spaces
| [[File:20nmShot10.png|220px]]
|16-06-2016, Fumehood E-4, AR-600-546, 30s/60s/90s, rinsed in IPA 60s.
|-
|JUNE/JULY 2016 SEM Supra 2, 10 keV
|-  
! 242 [muC/cm2]
| [[File:53nmCSAR20nmOverviewBasedose+5%.png|220px]]
| [[File:53nmCSAR20nmLines2Basedose+5%.png|220px]]
|
|-
|-  
! 253 [muC/cm2]
| [[File:53nmCSAR20nmOverviewBasedose+10%.png|220px]]
| [[File:53nmCSAR20nmLinesBasedose+10%.png|220px]]
|
|-
|-
|}
|}


{| class="wikitable collapsible collapsed" style="border: 5px solid black;"  style="width: 90%;" align="center"
<br clear="all"/>
!colspan="4"|  SEM inspection of wafer 4.09, 15 nm exposed pattern, shot pitch 5 nm
 
|-
 
|-
=== Dark Erosion ===
! 253 [muC/cm2]
 
| [[File:53nmCSAR15nmOverviewBasedose+10%.png|250px]]
Dark erosion has been measured on a un-exposed 4" wafer spin coated with CSAR 6200.18 to a thickness of approximately 549 nm. The resist thickness has been measured by VASE Ellipsometer before development, and after 3 minutes, 13 minutes, and 30 minutes of development in AR 600 546.
| [[File:53nmCSAR15nmLinesBasedose+10%.png|250px]]
 
|[[File:15nmShot10.png|250px]]
The graphs shows the measured thicknesses; the errorbars represents the standard deviations from the ellipsometric measurements. The average etch rate of CSAR is ~0.1 nm/min.
|-
 
|-
[[File:dark erosion.png|right|400px]]
! 276 [muC/cm2]
 
| [[File:53nmCSAR15nmOverviewBasedose+20%.png|250px]]
 
| [[File:53nmCSAR15nmLinesBasedose+20%.png|250px]]
 
|
<br clear="all" />
|-
 
|}
== Development ==
 
Many resists can be developed in different developers, CSAR can be developed in: AR 600-546, AR 600-548, ZED N-50 and mix of MIBK and IPA among others.


CSAR and ZEP520A are in principle the same chemical, however the pretreatment (filtration and temperature control) can differ.


{| class="wikitable collapsible collapsed" style="border: 5px solid black;"  style="width: 90%;" align="center"
Some users have reported residues and residual layers when using ZED N-50 on CSAR and vice verca, hence we recommend to use AR 600-546 or AR 600-548 (3 times stronger) to develop CSAR and not ZED N-50.
!colspan="4"|  SEM inspection of wafer 3.05, 50 nm exposed pattern, shot pitch 5 nm
|-
|-  
! 207 [muC/cm2]
| [[File:CSAR50nmoverview-10%.png|270px]]
| [[File:CSAR50nmlines-10%.png|270px]]
|NO ACHK READY
|-
|-
! 219 [muC/cm2]
| [[File:CSAR50nmoverview-5%.png|270px]]
| [[File:CSAR50nmlines-5%.png|270px]]
|
|-
|-
! 230 [muC/cm2]
| [[File:CSAR50nmoverview.png|270px]]
| [[File:CSAR50nmlines.png|270px]]
|
|-
|-
! 242 [muC/cm2]
| [[File:CSAR50nmoverview+5%.png|270px]]
| [[File:CSAR50nmlines+5%.png|270px]]
|
|-
|}


{| class="wikitable collapsible collapsed" style="border: 5px solid black;"  style="width: 90%;" align="center"
When this is said some users still observe residues when using AR 600-546, the producer "'''All resist GMBH'''" have recommended to use 3-5s, dip in pure MIBK to remove residues.  
!colspan="4"|  SEM inspection of wafer 3.05, 30 nm exposed pattern, shot pitch 5 nm
|-
AR 600 546 will dissolve different plastic materials, hence never use it on PS compounds.
|-
! 207 [muC/cm2]
| [[File:CSAR30nmoverview-10%.png|270px]]
| [[File:CSAR30nmlines-10%.png|270px]]
|NO ACHK READY
|-
|-
! 219 [muC/cm2]
| [[File:CSAR30nmoverview-5%.png|270px]]
| [[File:CSAR30nmlines-5%.png|270px]]
|
|-
|-
! 230 [muC/cm2]
| [[File:CSAR30nmoverview.png|270px]]
| [[File:CSAR30nmlines.png|270px]]
|
|-
|-
! 242 [muC/cm2]
| [[File:CSAR30nmoverview+5%.png|270px]]
| [[File:CSAR30nmlines+5%.png|270px]]
|
|-
|}


{| class="wikitable collapsible collapsed" style="border: 5px solid black;"  style="width: 90%;" align="center"
<br clear="all"/>
!colspan="4"|  SEM inspection of wafer 3.05, 20 nm exposed pattern, shot pitch 5 nm
|-
|-
! 207 [muC/cm2]
| [[File:CSAR30nmoverview-10%.png|270px]]
| [[File:CSAR30nmlines-10%.png|270px]]
|NO ACHK READY
|-
|-
! 230 [muC/cm2]
| [[File:CSAR20nmoverview.png|280px]]
|
|-
|-
! 242 [muC/cm2]
| [[File:CSAR20nmoverview+5%.png|280px]]
|
|-
|-
! 253 [muC/cm2]
| [[File:CSAR20nmoverview+10%.png|280px]]
|
|-
|}


== Etch Tests ==
== Etch Tests ==
Line 766: Line 437:
! rowspan="4" align="center"| Recipe
! rowspan="4" align="center"| Recipe
| Gasses
| Gasses
| C<sub>4</sub>F<sub>8</sub> sccm, SF<sub>6</sub> sccm
| C<sub>4</sub>F<sub>8</sub> 70 sccm, SF<sub>6</sub> 38 sccm
|rowspan="7" width="20%" | Profiles of lines exposed at 300 µC/cm2, etched 60s with recipe 'ProcessC'
|rowspan="7" width="20%" | Profiles of lines exposed at 300 µC/cm2, etched 60s with recipe 'ProcessC'
  [[File:tigre 6.17 0% 3b_ 07.png|200px]] [[File:tigre 6.17 0% 3b_ 16.png|200px]]
  [[File:tigre 6.17 0% 3b_ 07.png|200px]] [[File:tigre 6.17 0% 3b_ 16.png|200px]]
Line 772: Line 443:
|-
|-
| Pressure
| Pressure
| mTorr,  
| 4 mTorr,  
Strike:  secs @  mTorr
Strike:  secs @  mTorr


|-
|-
| Power
| Power
|  W Coil Power, W Platen Power
450 W Coil Power, 100 W Platen Power
|-  
|-  
|Platen temperature
|Platen temperature
20°C
10°C
|-
|-



Latest revision as of 08:36, 21 February 2024



Simple e-beam pattern in this resist has been tested, the results showed on this page. If you have questions to the process or wish to use this e-beam resist, please contact lithography at DTU Nanolab.


Spin Curves

The thickness is measured on VASE Ellipsometer using a simple Cauchy model for a transparent polymer on Si. The measurements are performed at one incidence angle (70 degrees) only. 9 points on each 4" wafer has been measured; the standard deviation thus representing the homogeinity of the film on the 4" wafers.

Around 2 ml of resist per wafer has been used when fabricating these curves. If you use less than 2 ml, the thickness of the final resist might be smaller than reported here.



AllResist AR-P 6200.09 (> 2ml per 4" wafer) spinning on Spin Coater: Manual LabSpin A-5, TIGRE, 09-04-2014. Softbake 5 min @ 150 degC.
Spin Speed [rpm] Acceleration [1/s2] Thickness [nm]
2000 4000 226
3000 4000 194
4000 4000 170
5000 4000 151
6000 4000 142
7000 4000 127


AllResist CSAR 6200.09 1:1 in anisole (< 2ml per 4" wafer), Spin Coater: Manual LabSpin A-5, TIGRE, 16-06-2014. Softbake 2 min @ 150 degC.
Spin Speed [rpm] Acceleration [1/s2] Thickness [nm]
2000 4000 84
3000 4000 67
4000 4000 59
5000 4000 53
6000 4000 49


AllResist CSAR 6200.18 (< 2ml per 4" wafer), Spin Coater: Manual Standard Resists, E-5, TIGRE, 15-06-2016. Softbake 2 min @ 180 degC.
Spin Speed [rpm] Acceleration [1/s2] Thickness [nm]
2000 2000 1003
3000 2000 809
4000 2000 721
5000 2000 639
6000 2000 586
7000 2000 549




Contrast Curve

CSAR 6200.09

100 nm lines in both ~70 nm and ~188 nm thick CSAR has been developed with AR-600-546 (standard CSAR developer) at room temperature to provide the following contrast curves.

CSAR Contrast Curve, Processed by TIGRE, FEB-MARCH 2016
Resist Spin Coat E-beam exposure Development Characterisation
CSAR AR-P6200.09 AllResist, CSAR AR-P6200.09 diluted 1:1 in Anisole 08-02-2016, LabSpin E-5, 4000 rpm, 60s, softbaked 60s @ 205 degC 09-02-2016, JBX9500 E-2, 2nA aperture 5, doses 40-600 µC/cm2, 100 nm lines and 300 nm spaces 11-02-2016, Fumehood D-2, AR-600-546, rinsed in IPA 60s. 02-03-2016 AFM Icon, F-2, ScanAsyst in Air

AR-P 6200 contrast curves.

Dose to size

Small features need a comparatively higher dose then big features and hence it can be useful to map out the dose and size dependency. Below is a set of cross sectional images of 100, 50 and 20 nm lines written 500, 250 and 180 nm resist at doses from 200 to 600 µC/cm2.

Cross section SEM images of 500 nm AR-P 6200.09 exposed at 200-600 µC/cm2. Top image is 100 nm lines, center image is 50 nm lines, bottom image is 20 nm lines. Au coated for SEM imaging.

Cross section SEM images of 250 nm AR-P 6200.09 exposed at 200-600 µC/cm2. Top image is 100 nm lines, center image is 50 nm lines, bottom image is 20 nm lines. Au coated for SEM imaging.

Cross section SEM images of 180 nm AR-P 6200.09 exposed at 200-600 µC/cm2. Top image is 100 nm lines, center image is 50 nm lines, bottom image is 20 nm lines. Au coated for SEM imaging.

CSAR 6200.18

100 nm lines in ~900 nm thick CSAR has been developed with AR-600-546 (standard CSAR developer) at room temperature.

CSAR Contrast Curve, Processed by TIGRE, JUNE 2016
Resist Spin Coat E-beam exposure Development Characterisation
CSAR AR-P6200.18 AllResist 15-06-2016, LabSpin E-5, 2000 rpm, 60s, softbaked 60s @ 205 degC 15-06-2016, JBX9500 E-2, 2nA aperture 5, doses 40-600 µC/cm2, 100 nm lines and 300 nm spaces 16-06-2016, Fumehood E-4, AR-600-546, 30s/60s/90s, rinsed in IPA 60s. JUNE/JULY 2016 SEM Supra 2, 10 keV



Dark Erosion

Dark erosion has been measured on a un-exposed 4" wafer spin coated with CSAR 6200.18 to a thickness of approximately 549 nm. The resist thickness has been measured by VASE Ellipsometer before development, and after 3 minutes, 13 minutes, and 30 minutes of development in AR 600 546.

The graphs shows the measured thicknesses; the errorbars represents the standard deviations from the ellipsometric measurements. The average etch rate of CSAR is ~0.1 nm/min.



Development

Many resists can be developed in different developers, CSAR can be developed in: AR 600-546, AR 600-548, ZED N-50 and mix of MIBK and IPA among others.

CSAR and ZEP520A are in principle the same chemical, however the pretreatment (filtration and temperature control) can differ.

Some users have reported residues and residual layers when using ZED N-50 on CSAR and vice verca, hence we recommend to use AR 600-546 or AR 600-548 (3 times stronger) to develop CSAR and not ZED N-50.

When this is said some users still observe residues when using AR 600-546, the producer "All resist GMBH" have recommended to use 3-5s, dip in pure MIBK to remove residues.

AR 600 546 will dissolve different plastic materials, hence never use it on PS compounds.


Etch Tests

If you have wafers or chips with CSAR you would like to have tested, please send me an [email].

Chlorine versus flourine-based etches

We have experienced problems with removal of CSAR after chlorine-based dry etch, see the file File:DryEtchTestsCSAR.pdf. It seems the chlorine etch forms particles of chlorinated CSAR on the surface, and these particles remains on the surface after resist removal with AR-600-71. The C4F8/SF6 etch also forms particles on the surface, but much smaller than those formed in the chlorine etch. It seems these particles are removed after 3 minutes in AR-600-71.

How to mount chips in dry etch tools

All etch rates presented here are measured on chips (i.e. diced 4" wafers) crystal bonded to a carrier. The carrier is either a blank Si wafer, a Si wafer spin coated with resist or a Si wafer coated with ALD grown Al2O3.

Etch Tests of CSAR, recipe 'nano1.42', DRIE PEGASUS, A-1. CSAR thickness measured on Ellipsometer VASE at 70 degrees
Sample CSAR Etch rate nm/min
Full 4" Si wafer with non-patterned ~180 nm CSAR ~56.5 (based on 2 runs)
Full 4" Si wafer with non-patterned ~240 nm CSAR,
postbaked 60 sec @ 130 degC
~56.5 (based on 2 runs)
1/4 4" Si wafer with non-patterned ~125 nm CSAR,
not crystal bonded to Si carrier
~83.3 (based on 3 runs)
1/4 4" Si wafer with non-patterned ~125 CSAR,
crystal bonded to 4" Si carrier
~54 (based on 1 run)

Etch rates and profile inspection

Continous Etches

Recipe nano1.42 on Deep Reactive Ion Etch PEGASUS A-1
Recipe Gasses C4F8 75 sccm, SF6 38 sccm Profiles of lines exposed at 300 µC/cm2, etched 2:30 minutes (150s) with recipe 'nano1.42'
  
  
Pressure 4 mTorr,

Strike: 3 secs @ 15 mTorr

Power 800 W Coil Power,

40 W Platen Power

Platen temperature - 20°C
Conditions Conditioning Pre-clean: 10 min oxygen clean

5 min oxygen clean between runs

Etch rates Si

500 nm lines: ~200 nm/min
190 nm lines: ~200 nm/min
102 nm lines: ~190 nm/min
61 nm lines: ~170 nm/min

CSAR ~55 nm/min


Recipe processC on Deep Reactive Ion Etch PEGASUS A-1
Recipe Gasses C4F8 70 sccm, SF6 38 sccm Profiles of lines exposed at 300 µC/cm2, etched 60s with recipe 'ProcessC'
 
  
Pressure 4 mTorr,

Strike: secs @ mTorr

Power 450 W Coil Power, 100 W Platen Power
Platen temperature 10°C
Conditions Conditioning Pre-clean: 10 min oxygen clean

5 min oxygen clean between runs

Etch rates Si

500 nm lines: ~300 nm/min
102 nm lines: ~250 nm/min

CSAR 158 nm/min

Bosch Etch

Recipe NBoost01 on Deep Reactive Ion Etch PEGASUS A-1
Recipe Deposition step Duration 2.5 s Profiles of lines exposed at 300 µC/cm2, etched 6:00 minutes with recipe 'NBoost01'
 
 

 
Gasses C4F8 50 sccm, SF6 0 sccm
Pressure 10 mTorr
Powers 500 W Coil
Etch step (boost) Duration 1.5 s
Gasses C4F8 0 sccm, SF6 60 sccm
Pressure 5 mTorr
Powers 400 W Coil, 50 W Platen
Etch step (main) Duration 3.5 s
Gasses C4F8 40 sccm, SF6 60 sccm
Pressure 15 mTorr
Powers 400 W Coil, 20 W Platen
Platen temperature 20 °C
Conditions Conditioning Pre-clean: 10 min oxygen clean

5 min oxygen clean between runs

Etch rates Si

200 nm lines: ~700 nm/min
130 nm lines: ~580 nm/min

CSAR ~18 nm/min