Specific Process Knowledge/Lithography/Aligners/Aligner: Maskless 02 processing: Difference between revisions

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Revision as of 13:49, 28 March 2019

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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

Exposure dose

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


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

Exposure mode

Aligner: Maskless 02 offers two exposure modes: 'high quality' (4) for optimal resolution and minimum stripe stitching effects; and 'fast' for maximum exposure speed.

Resolution

  • 5206E 0.5µm 375nm, dev 2xSP30s

Fast: 60mJ/cm2; defoc -6 (1µm, not optimized)

Quality: 60mJ/cm2; defoc -6 (~750nm, not optimized)

  • 5214E 1.5µm 405nm, dev SP60s

Fast: 90mJ/cm2; defoc -2 (1-2µm)

  • 5214E 1.5µm 375nm, dev SP60s

Fast: 65mJ/cm2; defoc 2 (~1µm)

Quality: 65mJ/cm2; defoc 2 (~750nm)

  • MiR 701 1.5µm 405nm, PEB 60s@110°C dev SP60s

Fast: 200mJ/cm2; defoc -5 (~1µm, not optimized)

  • MiR 701 1.5µm 375nm, PEB 60s@110°C dev SP60s

Fast: 170mJ/cm2; defoc -5 (1µm)

Quality: 180mJ/cm2; defoc -6 (750nm)

  • nLOF 2020 2µm 375nm, PEB 60s@110°C dev SP60s

Fast: 400mJ/cm2; defoc 5 (~1µm, not optimized)

Quality: 400mJ/cm2; defoc 0 (1µm)


Writing speed

(high quality, fast)

  • Speed vs. area (375nm)
    • Online
    • Offline
The writing speed of Aligner: Maskless 02 (Fast mode) as a function of the exposure area


  • Speed vs. dose (375nm + 405nm)
The writing speed of Aligner: Maskless 02 as a function of the exposure dose


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.

  • Substrate centering + flat alignment test

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 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. 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. ';').


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 enable 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

In High AR mode, 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). 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:

150µm high SU-8 Pillars 150µm high SU-8 Rings
Standard (800)

6000 mJ/cm2

Large (100)

16500 mJ/cm2

X-Large (60)

55000 mJ/cm2


Alignment

Shift (median) [µm] Misplacement [µm] Run-out (gain) [ppm] Rotation [ppm]
No flat alignment

(two samples)

X 0.0±0.05 0.0±0.05 0.0±1.67 0.0±1.18
Y 0.0±0.05 0.0±0.05 0.0±1.67 0.0±1.18
With flat alignment X 0.0±0.05 0.0±0.05 0.0±1.67 0.0±1.18
Y 0.0±0.05 0.0±0.05 0.0±1.67 0.0±1.18


Top Side Alignment

  • 4 marks (before final installation)
  • Scaling (375nm, high res camera)
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 0.0±0.05 0.0±0.05 0.0±1.18 0.0±1.67
Y NA 0.0±0.05 0.0±0.05 0.0±1.18 0.0±1.67
4 alignment marks

375nm, high res camera

X 0±0 0.000±0.000 0.0±0.05 0.0±0.05 0.0±1.18 0.0±1.67
Y 0±0 0.0±0.05 0.0±0.05 0.0±1.18 0.0±1.67
4 alignment marks

405nm, high res camera

X 0±0 0.000±0.000 0.0±0.05 0.0±0.05 0.0±1.18 0.0±1.67
Y 0±0 0.0±0.05 0.0±0.05 0.0±1.18 0.0±1.67

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 0±0 0.000±0.000 0.0±0.05 0.0±0.05 0.0±1.18 0.0±1.67
Y 0±0 0.0±0.05 0.0±0.05 0.0±1.18 0.0±1.67
4 alignment marks

375nm, high res camera

X not used not used 0.0±0.05 0.0±0.05 0.0±1.18 0.0±1.67
Y not used 0.0±0.05 0.0±0.05 0.0±1.18 0.0±1.67

Back Side Alignment

  • Tested, 2-3µm error in X observed
  • Corrected
Shift (median) [µm]
Align-flip180-align X 0.0±0.5
Y 0.0±0.5
KOH-window X 0.0±0.5
Y 0.0±0.5

Advanced Field alignment (TSA)

  • 4 marks, 25 fields (375nm, high res camera)
  • Scaled first print, 10 fields (375nm, high res camera)
  • 4 marks, 25 fields (405nm, high res camera)
Shift (median) [µm] Misplacement [µm]
25 fields

375nm, high res camera

X 0.0±0.05 0.0±0.05
Y 0.0±0.05 0.0±0.05
Scaled first print, 10 points

375nm, high res camera

X 0.0±0.05 0.0±0.05
Y 0.0±0.05 0.0±0.05
25 fields

405nm, high res camera

X 0.0±0.05 0.0±0.05
Y 0.0±0.05 0.0±0.05