Specific Process Knowledge/Lithography/EBeamLithography/JEOLAlignment: Difference between revisions

From LabAdviser
Thope (talk | contribs)
Thope (talk | contribs)
Line 3: Line 3:


==Job preparation==
==Job preparation==
The job illustrated below writes a chip layout in a 5 x 5 matrix into a 2 x 2 matrix as illustrated in the figure. The first layer, L1, has defined global marks at P = (-30000,0) and Q = (30000,0). The local chip marks are placed at M1 = (-450,450), M2 = (450,450), M3 = (450,-450) and M4=(-450,-450). First a global alignment is called via the '''GLMDET''' command and subsequently chip alignment is called using the '''CHIPAL''' command. The mark positions are stated in the JDF file using the '''GLMPOS''' command for PQ marks and the '''M1''' to '''M4''' commands for chip marks.
The job illustrated below writes a chip layout in a 5 x 5 matrix into a 2 x 2 matrix as illustrated in the figure. The first layer, L1, has defined global marks at P = (-30000,0) and Q = (30000,0). The local chip marks are placed at M1 = (-450,450), M2 = (450,450), M3 = (450,-450) and M4=(-450,-450). First a global alignment is called via the '''GLMDET''' command and subsequently chip alignment is called using the '''CHIPAL''' command. The mark positions are stated in the JDF file using the '''GLMPOS''' command for PQ marks and the '''M1''' to '''M4''' commands for chip marks. Remember that a V30 file is placed relative to its bounding box center coordinate and hence it might be necessary to control the bounding box extents by adding control geometry (corner marks) if the design is not symmetric around (0,0) in the chip design coordinate system.
 
 


{| style="border: none; border-spacing: 0; margin: 1em auto; text-align: center;"
{| style="border: none; border-spacing: 0; margin: 1em auto; text-align: center;"
Line 15: Line 13:
|}
|}


===Chip alignment SDF ===
The following SDF and JDF files will be used for the example.


<pre>
<pre>
;SDF
MAGAZIN 'THOPE'
MAGAZIN 'THOPE'


Line 26: Line 25:
CALPRM '6na_ap5'
CALPRM '6na_ap5'
DEFMODE 2       
DEFMODE 2       
GLMDET S
GLMDET A
CHIPAL 1
CHIPAL 1
HSWITCH OFF,ON
HSWITCH OFF,ON
Line 35: Line 34:
END 8
END 8
</pre>
</pre>
'''CHIPAL [mode]'''
'''CHIPAL''' has six modes
*0 - Cancels chip alignment
*S - SEM mode. The user is prompted to use SEM mode to manually find M1
*1 - One mark is used for position correction
*4 - Four marks are used for position, rotation and gain correction
*V1 - Virtual mode 1. A single mark position is used for height detection of the substrate, no position correction
*V4 - Virtual mode 4. Four mark positions are used for height detection of the substrate, no position correction
In addition to position correction mode 1 and 4 also detects substrate height. The virtual modes are only used to detect substrate height since no mark detection is done. Mode S obviously very time consuming for a high number of chips.
If set up properly on good quality marks mode 1 or mode 4 chip alignment can usually execute in about 1-2 seconds per mark. The time estimate at compilation will account for the time spend on chip alignment at the current settings of the '''CHIPAL''' subprogram.
===Chip alignment JDF ===
In addition to the use of '''CHMPOS''' for chip mark position definition the example below illustrate making arrays of an array. The first array is set up as a 2x2 array assigning array '''A1'''. '''A1''' is defined below as '''1:''', since '''1''' is defined as an array it can be referenced as '''A1'''. '''A''' then defines a 5x5 array assigning pattern '''P(1)''' to each element. The chip mark position command must be used in the same array that assigns the corresponding pattern.


<pre>
<pre>
;JDF
JOB/W    'THOPE',4  ; 4inch wafer
JOB/W    'THOPE',4  ; 4inch wafer



Revision as of 23:08, 5 May 2023

Aligned exposure on JEOL 9500

There is quite a few things to remember in order to align an exposure to an existing pattern. The example below is a step by step guide illustrating global substrate alignment as well as chip alignment. If your job only requires global alignment simply skip the chip alignment part. In the example we assume a layer, L1, is already defined on the substrate and the goal is to align the next layer, L2, to it.

Job preparation

The job illustrated below writes a chip layout in a 5 x 5 matrix into a 2 x 2 matrix as illustrated in the figure. The first layer, L1, has defined global marks at P = (-30000,0) and Q = (30000,0). The local chip marks are placed at M1 = (-450,450), M2 = (450,450), M3 = (450,-450) and M4=(-450,-450). First a global alignment is called via the GLMDET command and subsequently chip alignment is called using the CHIPAL command. The mark positions are stated in the JDF file using the GLMPOS command for PQ marks and the M1 to M4 commands for chip marks. Remember that a V30 file is placed relative to its bounding box center coordinate and hence it might be necessary to control the bounding box extents by adding control geometry (corner marks) if the design is not symmetric around (0,0) in the chip design coordinate system.

Illustration of chip alignment using a chip array instanced into another array. Notice in the right most illustration how four corner marks are used to force symmetry around (0,0) such that the pattern is placed correctly.

The following SDF and JDF files will be used for the example.

;SDF
MAGAZIN	'THOPE'

#8
%4C     
JDF	'thope230126',1
ACC 100
CALPRM '6na_ap5'
DEFMODE 2      
GLMDET A	
CHIPAL 1
HSWITCH OFF,ON
RESIST 250
SHOT A,6
OFFSET(-44,-139)

END 8
;JDF
JOB/W    'THOPE',4  ; 4inch wafer

GLMPOS    P=(-30000,0),Q=(30000,0)

PATH FT01
  ARRAY	(-15000,2,30000)/(10000,2,20000)
	ASSIGN A(1) -> ((1,1))	

1: 	ARRAY (-4000,5,2000)/(4000,5,2000)
	CHMPOS M1=(-450,450),M2=(450,450),M3=(450,-450),M4=(-450,-450)
	ASSIGN P(1) -> (*,*)

  AEND
PEND

LAYER	1	
        P(1)  'thope230126.v30'
        SPPRM 4.0,,,,1.0,1
        STDCUR  6

END

CHMPOS [M1=(x1,y1){,M2=(x2,y2),M3=(x3,y3),M4=(x4,y4)}]

CHMPOS defines the chip alignment marks in the local chip coordinate system, unit is µm. M1 is mandatory while M2-M4 are optional in one mark mode. In four mark mode all marks must be defined. The order of the marks is important, M1 must be top left with M2-M4 placed clockwise around the center. In the given example the four marks are placed symmetrically at ±450 µm in x and ±450 µm in y.

It V1 mode it is customary to set M1 = (0,0) such that substrate height is detected at the center of the chip. In this way V1 mode can be used to exactly read out substrate height where the chip pattern will be written.