Specific Process Knowledge/Lithography/Aligners/Aligner: Maskless 02 processing

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Exposure technology

Aligner: Maskless 02 is not a direct writer. In the maskless aligner, the exposure light is passed through a spatial light modulator, much like in a video projector, and projected onto the substrate, thus exposing an area of the design at a time. The substrate is exposed by scanning the exposure field across the substrate in a succession of stripes.

The light source is a laser diode (array) with a wavelength of 375nm (2.8W) or 405nm (8W). The spacial light modulator is a digital micro-mirror device. The individual mirrors of the DMD are switched in order to represent the design, and the laser is flashed in order to yield the desired exposure dose. This image is projected onto the substrate through a lens(system). The projected image yields a pixel size of 160nm X 160nm at wafer scale. The image is scanned across the substrate, in order to expose the entire design, each stripe overlapping (2 or 4 times) in order to minimize uniformity effects and stitching errors.

The writing head of the Aligner: Maskless 02 moves only in the z-direction. Using an optical (or pneumatic) focusing system, the maskless aligner is able to do real-time autofocus. The defocus process parameter is used to compensate offsets in the focusing mechanism, and to optimize printing quality in different resists and varying thicknesses. The stage of the Aligner: Maskless 02 moves only in x and y. It has no theta-axis. All rotation during alignment is thus accomplished by transformation of the input design.

Process Parameters

The lithographic result of exposure on Aligner: Maskless 02 depends on a lot of factors, including the dose and defocus parameters, and the exposure mode used. The optimal dose and defocus depend on the type and thickness of the resist, and the optical properties of the substrate (e.g. reflective/absorbing/transparent). All of these factors influence the obtainable resolution, as well as the writing speed.

The correct way to determine the best dose-defocus settings is to generate a so-called Bossung plot (known from projection lithography), which plots the printed linewidth as a function of dose and defocus. From this, the most stable region of parameter space is chosen, i.e. the region where the linewidth changes the least when dose and defocus changes. Any deviation from the design linewidth can be corrected using the CD bias parameter. This typically involves SEM imaging of resist cross-sections, and quickly becomes time consuming. However, in most cases, inspection of a dose-defocus matrix (easily generated using the series exposure function) in an optical microscope will get you most of the way.

Data represent dose-defocus tests on Si using optical autofocus unless otherwise stated

Thickness Laser Exposure mode Dose Defoc Resolution Comments
AZ 5206E 0.5 µm 375 nm Fast 60 mJ/cm2 -6 1 µm (not optimized) Dev: 2xSP30s
Quality 60 mJ/cm2 -6 ~750 nm (not optimized) Dev: 2xSP30s
AZ 5214E 1.5 µm 405 nm Fast 90 mJ/cm2 -2 1-2 µm Dev: SP60s
375 nm Fast 65 mJ/cm2 2 ~1 µm Dev: SP60s
Quality 65 mJ/cm2 2 ~750 nm Dev: SP60s
AZ MiR 701 1.5 µm 405 nm Fast 200 mJ/cm2 -5 ~1 µm (not optimized) PEB: 60s@110°C, Dev: SP60s
375 nm Fast 170 mJ/cm2 -5 1 µm PEB: 60s@110°C, Dev: SP60s
Quality 180 mJ/cm2 -6 (Feb 2019)
-2 (Apr 2019)
<750 nm PEB: 60s@110°C, Dev: SP60s
Large structures probably over-exposed
AZ nLOF 2020 2 µm 375 nm Fast 400 mJ/cm2 5 ~1 µm (not optimized) PEB: 60s@110°C, Dev: SP60s
Probably under-exposed
Quality 400 mJ/cm2 0 1 µm PEB: 60s@110°C, Dev: SP60s
Probably under-exposed


Exposure dose

Spectral sensitivity of AZ resists represented as optical absorption. From https://www.lithoprotect.com/en/worth-knowing/


Exposure dose relative to exposure at 365nm (Aligner: Maskless 01):

375nm 405nm
AZ 5214E 0.95 1.3
AZ 4562 ? ?
AZ MiR 701 1 1.2
AZ nLOF 2020 3 NA
SU-8 10-15 NA


Defocus

The autofocus mode (optical or pneumatic) is selected via the substrate template.

Optical: Varies greatly with resist type and thickness, see Process Parameters. Probably also dependent on substrate. Should work for substrates down to 3x3mm2.

Pneumatic: Probably similar for resists of similar thickness, and not likely to vary with substrate. For 375nm exposure, the optimum seems to be around -15 (Large defocus range). Substrates must be at least 10x10mm2.

Exposure mode

Aligner: Maskless 02 offers two exposure modes. The exposure mode is selected during design conversion.

High quality (4) mode is used for optimal resolution and minimum stripe stitching effects. In the high quality mode, an area of the pattern is exposed by 4 stripes, each 160µm wide and exposing a quarter of the dose. At the same time, sub-pixel interpolation is applied, yielding an address grid size of 40nm.

Fast mode is used for maximum exposure speed. In the fast mode, each area of the pattern is exposed by 2 stripes only. This effectively cuts the exposure time in half, but also doubles the size of the address grid in the X-direction. Due to less averaging of non-uniformities, stitching effects will be more prominent in this mode.

Writing speed

According to specs, the writing speed of Aligner: Maskless 02 is 285mm2/min in fast mode. Using the high quality exposure mode cuts this speed in half, to approximately 140mm2/min. The writing speed for a 100x100mm2 area measured during installation of the machine (acceptance test) was ~340mm2/min for both exposure wavelengths.

The writing speed of Aligner: Maskless 02 (fast mode, 375nm) as a function of the exposure area

Speed vs. area:

During exposure of a stripe the stage moves at a constant speed. Each stripe thus includes a certain movement overhead for acceleration and deceleration. As the stripes get shorter, this overhead becomes more significant, and the normal writing speed is no longer achieved. For samples smaller than a 2" wafer, the writing speed of Aligner: Maskless 02 drops below the specified 285mm2/min.

When the exposure is started on the maskless aligner, the software starts converting the design to the data needed for the exposure. When sufficient data has been generated, the hardware starts exposing the sample while more data is being generated. This simultaneous data conversion and exposure is called Online conversion. Once a design has been converted (exposed) the data may be reused for repeated exposures (Offline conversion). Due to no time lost waiting for data, offline exposure may be several tens of % faster than online. However, the converted data can only be reused if no alignment is needed, including flat alignment ("Expose with substrate angle").


The writing speed of Aligner: Maskless 02 as a function of the exposure dose

Speed vs. dose:

The writing speed remains almost constant up to a dose of 1000mJ/cm2. Due to the higher power of the 405nm laser, the writing speed remains high up to a dose of 1000mJ/cm2 for this wavelength. After this point, the writing speed decreases almost linearly with dose. For 375nm, the writing speed is 50% at a dose of 4500mJ/cm2, while 405nm requires a dose of 8500mJ/cm2 to drop to that speed.


Speed vs. design:

Depending on the complexity and density of the pattern, the conversion process may slow down the exposure significantly. A 4" wafer exposed with a pattern consisting of 200 million 5µm circles took 65 minutes (154mm2/min), compared to the specified 35 minutes (285mm2/min). It took 12 minutes before the first stripe was exposed.

The maskless aligner exposes the design in north-south oriented stripes (perpendicular to the flat). The stripes all have the same length, set by the height of the design, and only completely empty stripes are skipped. The writing speed may thus be affected by the layout of the design, as shown below.

Design case: Five 100µm wide, 40mm long lines, spaced 10mm apart (40x40mm2)
This design printed in 6 minutes (260mm2/min) This design printed in 1 minute (1600mm2/min)


Acceptance test

Acceptance criteria on a 100 X 100 mm2 area: Width of smallest resolved line 600±100 nm, alignment error 500 nm, writing speed 285 mm2/min.

The acceptance test also included a verification of back side alignment (better than 1 µm), as well as functionality tests of grayscale and high aspect ratio mode.

Exposed on mask blank with 0.5 µm AZ1500 (possibly S1800) at DTU, then transferred via wet chrome etch and measured at Heidelberg

SAT Feb 2019 Width of smallest resolved line [nm] Alignment error (TSA) [nm] Exposure speed [mm2/min]
405 nm X 532±64 251 333
Y 599±58 382
375 nm X 556±44 214 347
Y 579±63 224

Features

Substrate centring and flat alignment

During substrate detection, the sample is scanned along the X- and Y-axes, as well as diagonally. From these measurements, the size (diameter) of the substrate is calculated, as well as the stage position matching the center of the substrate. This stage position will be the default origin for the subsequent exposure.

At the end of substrate detection, the sample is scanned twice along the bottom edge (flat), in order to determine the substrate rotation. This angle will be presented in the exposure panel along with the option to expose the design rotated in order to compensate for this angle, i.e. aligned to the flat/edge of the substrate.

Result of using "Expose with substrate angle" on three samples with optical autofocus:

  • Rotation: 0.5±0.2°
  • Centring:
    • X 100±250µm
    • Y 200±250µm

The error on the flat alignment is surprising when compared to the 0±0.1° measured on Aligner: Maskless 01. The centring, on the other hand, is seen to be within a few hundred µm, without correcting for the flats.

Result of loading the same substrate 2x9 times without removing it from the stage:

Average Range
Optical

autofocus

3.7 mRad ±13.9 mRad

±0.8°

Pneumatic

autofocus

-3.1 mRad ±1.4 mRad

±0.08°

This shows that using optical autofocus significantly increases the error on the flat measurement, while using pneumatic atuofocus performs similar to Aligner: Maskless 01. It is thus recommended to use pneumatic autofocus for the first print if crystal alignment is important for subsequent processing.

Result of using only the alignment tool, pushing it to the extremes:

-11.08 to 5.54mRad, corresponding to -0.6 to 0.3°, average -0.1±0.5° (6 measurements, including 2 without pushing the alignment tool). Measured using pneumatic autofocus. This should be compared to the ±1° crystal alignment spec of the SEMI wafer standard.

It would seem that applying the flat angle measured with optical autofocus to the print introduces more error than relying only on the alignment tool.


Labeling

An example of wafer ID produced by the labeling function

The conversion manager software allows for inclusion of labels during the design conversion process. The labels are configured in a .lbl tab-delimited ASCII file with a special header in the first row, which must be located in the 'HIMT\Designs\Labels' folder. When used, the labels defined in the label file will be merged with the pattern in the source file, and the result can be inspected in the viewer. The X and Y positions of the labels should be given in design coordinates, and will be subject to any offsets/shifts applied to the design. Note, that if the label file is changed, the job file will not update automatically.

Example of a label file:

X | Y | UNIT | HEIGHT | UNIT | TITLE

-16000 | -46000 | um | 2000 | um | TARAN DTU Nanolab 20190320

This produces a 2mm high, approximately 32mm long wafer ID at the flat of a 4" wafer. Some special characters are not allowed (e.g. ';').


Large defocus range

The standard range for the defocus parameter is -10 to 10, but a special feature allows to extend this range to -25 to 25. The large defocus range feature is set in the resist template, and can only be accessed by choosing the 'NLAB Large defoc range' resist template during the job setup. The dose must be set manually, as this is an otherwise empty resist template. Also, this feature will work in the entire range for pneumatic focus, but it will likely fail at the extremes for optical focus.

Technically, it is possible to combine this feature with other features, such as high aspect ratio mode, but this requires that at custom resist template is set up by staff.

High Aspect Ratio (DOF) mode

Aligner: Maskless 02 is configured with the so-called "Write Mode I", which uses a higher demagnification, higher NA lens system to achieve higher resolution. This reduces the depth of focus (technically depth of field), making it more difficult to achieve good lithographic results in thicker resist coatings. The theoretical DOF of Aligner: Maskless 02 is 0.3µm, compared to 1µm for Aligner: Maskless 01. In order to improve processing of thick resists, the Aligner: Maskless 02 has been configured with the High Aspect Ratio Mode, which uses a variable aperture in the optical path to decrease the (illumination) NA of the system, thus increasing the DOF at the expense of intensity and resolution limit.

The exposure intensity of Aligner: Maskless 02 as a function of the high AR mode aperture setting

The aperture size is controlled via a parameter in the resist template. The high AR parameter can be Standard (aperture fully open; 800 motor steps), Large (100 steps), or X-Large (60 steps).

  • Standard: No resist template or any normal resist template
  • Large: 'NLAB High AR mode Large'
  • X-Large: 'NLAB High AR mode XL'

Assuming a linear relation between motor steps and aperture diameter, Large corresponds to a relative aperture area of 1.6%, while X-Large corresponds to 0.6% aperture area. Intensity measurements show a relative intensity of approximately 25%, and 6%, respectively. The effective dose can be corrected by increasing the nominal dose in the exposure, either by a fixed machine parameter, or by the user setting a higher dose themselves. At the moment, the user will be required to increase the nominal dose.

Decreasing the aperture size significantly reduces the amount of light that reaches the sample, and thus the effective dose, as can be seen in the graph to the right, and the table below. The resolution limit, however, seem to be much less affected. Tests using 1.5µm MiR resist suggest that using the X-Large setting (60 steps) reduces the achievable resolution from 1µm at Standard setting to 3µm for exposure at 375nm, but only to 1.75µm for exposure at 405nm.

Dose factor for different wavelengths and aperture settings:

375nm 405nm
Large (100) X-Large (60) Large (100) X-Large (60)
Intensity measurements 3.3 17.4 5.7 14.6
150µm SU-8 acceptance test ~3 ~10 NA NA
1.5µm AZ MiR 701 dose test 7.5 20.8 6.7 18.0
10µm AZ 4562 dose test ? ? ? ?


Results from acceptance test on 150µm thick SU-8:

Pillars Rings
Standard (800)

6000 mJ/cm2

Large (100)

16500 mJ/cm2

X-Large (60)

55000 mJ/cm2


Alignment

Data from the stage stitching test, representing a 60x60mm2 area.

Stage stitching test:

Shift (median) [µm] Misplacement [µm] Run-out (gain) [ppm] Rotation [ppm]
9 points, 60x60mm2 X -0.15±0.05 -0.16±0.05 0.8±1.7 -3.6±1.2
Y 0.25±0.125 0.26±0.11 -0.3±1.7 -0.3±1.2
All 25 points X -0.150±0.075
Y 0.250±0.125


Top Side Alignment

Overlay accuracy (spec): 0.5µm

Camera field of view (W x H):
High Res 64µm x 48µm
Low Res 213µm x 160µm
Overview 13mm x 10mm

Accessible stage coordinates:
High/Low Res X = ±108mm; Y = ±108mm
Overview X = ±108mm; Y = +39mm to -180mm
To be sure the Overview camera can be used to locate the first alignment mark, it is advised to use a mark in the bottom left portion (3rd quadrant) of the design as mark 1.

Overview camera image of a TSA alignment mark during alignment.
The circle is 3mm in diameter, the alignment mark is 300µm. The blue cross-hair is ~400µm.
Low Res camera image of a TSA alignment mark during alignment.
The lines of the cross are 20µm wide. The blue cross-hair is ~7µm.
High Res camera image of a TSA alignment mark during alignment.
The lines of the central cross are 3µm wide. The blue cross-hair is ~2µm.


MLA-MLA Scaling [ppm] Shearing [mRad] Shift (median) [µm] Misplacement [µm] Run-out (gain) [ppm] Rotation [ppm]
2 alignment marks

375nm, high res camera

X NA NA 0.25±0.15 0.25±0.05 1.7±1.7 2.2±1.3
Y NA 0.3±0.13 0.29±0.05 0.8±1.7 0.0±1.7
4 alignment marks

375nm, high res camera

X -1 0.001 0.2±0.05 0.17±0.05 -0.6±1.7 0.3±1.2
Y -1 0.4±0.05 0.42±0.05 0.6±1.7 0.6±1.2
4 alignment marks

375nm, low res camera

X -6 0.002 -0.05±0.13 -0.06±0.05 -1.9±1.7 0.8±1.3
Y -2 0.3±0.05 0.3±0.05 -0.6±1.7 1.1±1.7

Scaled first print:

MLA-MLA Scaling [ppm] Shearing [mRad] Shift (median) [µm] Misplacement [µm] Run-out (gain) [ppm] Rotation [ppm]
4 alignment marks

375nm, high res camera

X 100 0.000 -0.05±0.1 -0.01±0.05 1.7±3.3 0.6±2.4
Y 101 0.2±0.05 0.18±0.05 0±3.3 0±2.4
4 alignment marks

375nm, high res camera

X not used not used -2.75±3.0 -2.98±0.25 -101±8.3 -0.6±5.9
Y not used 3.0±2.9 3.12±0.25 -96.1±8.3 0.0±5.9

Back Side Alignment

Image of a BSA alignment mark during alignment. The mark is 300µm wide. The blue cross-hair is ~18µm.

Overlay accuracy (spec): 1.0µm

BSA windows: along the X and Y axes, 10mm x 46mm, starting 14.5mm from the center.

Camera field of view (W x H): 640µm x 480µm

BSA marks positionned at x = ±20mm on a 2" wafer BSA marks positionned at x = ±40mm on a 4" wafer BSA marks positionned at x = ±50mm on a 6" wafer BSA marks positionned at x = ±50mm on an 8" wafer


Offset (median) [µm] Comment
Align-flip180-align, 3 points
375nm
X -0.625±0.125 0.5µm verniers, May 2019
Y -0.75±0.125
Align-flip180-align, 3 points
405nm
X -0.625±0.125 0.5µm verniers, May 2019
Y -0.375±0.125
KOH-window, ? points X 0.0±0.0 Not performed yet
Y 0.0±0.0


Advanced Field alignment (TSA)

Overlay accuracy (spec): 0.25µm (5x5mm2 area)

Shift, rotation, scaling, and shearing is determined and set by global alignment marks. The shift is corrected by automatic alignment to one mark in each field (chip).

Shift (median) [nm] Error (average) [nm]
25 fields

375nm, high res camera

X 50±75 70±75
Y 150±50 128±50
Scaled first print, 10 fields

375nm, high res camera

X -25±50 -5±50
Y 100±50 120±50
25 fields

405nm, high res camera

X 100±75 108±75
Y 0±50 16±50