Autumn00 develop attenuated phase shift mask by KLA Corporation

Lithography S

Development of High-Quality Attenuated Phase-Shift Masks by Toshihiro Ii and Masao Otaki, Toppan Printing Co., Ltd.

Along with the year-by-year acceleration of semiconductor device miniaturization, the frequency of technology roadmap renewal has increased by a factor of three from once every three years to once a year. It is not possible to cope with fabrication of high-density semiconductor devices simply by reducing the pattern size of the mask because aggressive pattern shrink on the photomask will lead to deterioration of the resist pattern when transferred to the silicon wafer surface in the exposure process. To tackle this problem, OPC (optical proximity correction) features are added to the photomask, which results in increased complexity and miniaturization in the photomask-making process. Consequently, the volume of mask-pattern data is growing drastically, and the time required for mask-defect inspection and mask-writing processes keeps increasing. Moreover, the need to achieve outstanding process accuracy raises the costs of mask production and inspection tools. Such a drop in mask throughput and the increase in cost of materials and tools seriously affects the costs of photomasks.

Step-and-scan-exposure systems adopted ArF lithography in 1999, however, ArF lithography systems, including resist, are still under evaluation and development. From 2000 to 2001, the feature sizes of semiconductor devices will be further reduced to 0.13 Âľm while it is clear that KrF lithography will remain dominant. Challenges of the photomask

Photomask technology is currently facing a number of challenges in various fields. The major challenges are listed below: 1) material 2) volume of mask-pattern data 3) mask exposure and mask-fabrication process 4) inspection and measurement (quality assurance) 5) cost and delivery

Cost will be particularly important in the future of mask production. The drop in mask throughput mentioned above is a primary factor affecting cost. Improvement of accuracy is another challenge along with mask pattern miniaturization. For accuracy, it is critical to come up with a solution to the fluctuation of line width, which constitutes a more serious problem as mask patterns get finer. Fluctuations of mask-pattern dimensions have a multiplied pattern profile impact on the wafer surface, which is called MEEF (Mask Error Enhancement Factor). To be more specific, a change of pattern dimensions on the photomask is multiplied by a factor of two to three times when the pattern is transferred to the wafer surface in the exposure process. The PSM (phase-shift mask) is capable of considerably reducing the MEEF effect, tolerating fluctuation of mask pattern dimensions to some extent. In this sense, the PSM is effective in suppressing mask costs. In general, accuracy of mask fabrication is primarily determined by mask writer and manufacturing process procedure. As for the PSM, however, material selection is a dominant factor for accuracy. For inspection and measurement of the photomask, the major challenges are improvement of detection sensitivity in defect inspection and the establishment of PSM inspection Autumn 2000

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performance of att-PSM to the level of alt-PSM, the transmissivity of the shifter material needs to be increased. With the conventional att-PSM, however, transmissivity of an excimer laser source cannot be set at a high level because such a choice raises the transmissivity of inspection wavelength too high to conduct inspection.

technology. Along with further device miniaturization, it also is necessary to improve the performance of the CD (critical dimension) measurement tools. Needs for resolution enhancement technology (RET)

If KrF lithography is employed for 0.13 µm device production, the ratio of exposure wavelength to dimension of resist pattern on wafer surface will be almost 2:1; and, binary masks with OPC will be unable to achieve the required level of resolution or depth of focus. It will be necessary, therefore, to introduce the PSM.

In an attempt to overcome this difficulty, a new shifter material has been developed: zirconium silicon oxide (ZrSiO). Using ZrSiO shifter film, att-PSM is able to suppress the transmissivity of light from the defect inspection tool below an upper limit enabling inspection for quality assurance.

The alternating PSM (alt-PSM) is capable of achieving high resolution of one-half of exposure wavelength, but it has not yet been actively adopted because technologies for defect inspection and mask repair need to be improved prior to its introduction. On the other hand, the attenuated PSM (att-PSM) has already been adopted in commercial production because the conventional mask inspection and repair technologies used for the binary mask process can be applied as they are. The attenuated PSM, which generally uses shifter film that transmits three to eight percent of excimer laser source, has mainly been applied to the to fabrication of contact holes. This technology is significantly superior to the conventional binary mask technology in terms of depth of focus, but it is not as effective in improving resolution.

Figure 1 shows RET (resolution enhancement technology) applicable to each lithography technology. It is possible to roughly estimate which RET is applicable by referring to the ratio of exposure wavelength to the dimension of resist pattern on wafer surface. For the 0.13 µm device to be developed in the near future, it is highly likely att-PSM with high transmissivity will be adopted. Att-PSM should also be an effective technique for ArF lithography, when pattern dimensions are reduced to about two-thirds of wavelength. For ULSI requiring much higher resolution, alt-PSM will be absolutely necessary. If resolution cannot be raised high enough, an alternative excimer laser source with shorter wavelength must be adopted. F2 laser lithography featuring wavelength of 157 nm, combined with ultrahigh resolution technology such as PSM, is expected to achieve as high a resolution as 70 nm.

Alt-PSM, on the other hand, is effective in improving depth of focus and resolution. In order to improve the Node KrF Lithography

ArF Lithography

F2 Lithography

180nm

130nm

100nm

70nm

Feature size / Wavelength Ratio

73%

53%

40%

28%

Binary

OPC / Serif

OPC / Assist Bar

—

Att-PSM*

3–8%

15–25%

—

Alt-PSM**

— —

Shifter Edge Type (Logic Gate) Hidden Shifter Type (Memory)

Shifter Edge Type (Logic Gate) —

— —

Feature size / Wavelength Ratio

93%

67%

52%

36%

Binary

—

OPC Serif

OPC / Assist Bar

—

Att-PSM

—

3–8%

15–25%

—

Alt-PSM

— —

Shifter Edge Type (Logic Gate) Hidden Shifter Type (Memory)

Shifter Edge Type (Logic Gate) —

Feature size / Wavelength Ratio

115%

83%

64%

45%

Binary

—

OPC / Assist Bar

—

Att-PSM

—

3–8%

15–25%

Alt-PSM

— —

Shifter Edge Type (Logic Gate) Hidden Shifter Type (Memory)

High-transmission and Tri-tone type Att-PSM

*Att-PSM = Attenuated Phase Shifting Mask

Figure 1. RET reticles by wavelength and by technology node.

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**Alt-PSM = Alternating Phase Shifting Mask

3.0

1.0 TF.AF

TF.AF

Transmittance Change (%)

Target

2.0

Phase Change (deg.)

1.0 0 -1.0

0.5

Target 0

-0.5

-2.0 -3.0

-1.0 0

Total Energy (kJ/cm2)

Figure 2. Phase shift change (a) and transmissivity change (b) of ZrSiO-based att-PSM as a function of ArF excimer laser irradiation.

We report performance of att-PSM using ZrSiO shifter film that is capable of suppressing transmissivity of inspection wavelength. Development of ZrSiO-based attenuated PSM

In the photomask field, the conventional chromium binary mask is increasingly replaced by the OPC mask, alt-PSM and attPSM. In particular att-PSM attracts attention as it is more suitable than others for volume production. For att-PSM, it is necessary to expand the range of transmissivity from 8 to 20 percent. Conventional materials such as MoSi and CrF, however, cannot secure adequate transmissivity for inspection wavelength due to their physical properties. Moreover, these materials cannot be applied to the photomask for ArF lithography due to their excimer laser resistance and spectral characteristics. Various materials and structures of photomask have been investigated to develop a photo-mask featuring high transmissivity that can be applied to three generations of lithography: KrF, ArF and F2.

Results

Zirconium was first selected as a next-generation PSM material because it features strong ArF laser resistance. Zirconium-type materials were found far more resistant The Structure of ZrSiO Att-PSM

Bi-Layer ZrSiO with Cr and resist

Resist coating EB resist Cr ]Bi-Layer ZrSiO

EB exposure and development

Cr etching

Bi-Layer ZrSiO dry etching

Resist remove Cr Transparent Film Attenuated Film

Tri-Tone Type Resist remove

Figure 3: Structure and fabrication process of ZrSiO-based att-PSM.

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to ArF laser than materials used for the conventional att-PSM materials. Figure 2 shows phase shift and transmissivity change as a function of ArF excimer laser irradiation. Laser irradiation conditions were set based on the assumption that mask lifetime was three years. Specifically, total irradiation was set at 30 kJ/cm2 (or 0.2mJ/cm2/pulse). Under these conditions, ZrSiO-based att-PSM was found effective in suppressing the change of phase shift below 0.5Â° and transmissivity below 0.2 percent.

12 Transmissive ^, p, y Absorptive ^, p, y

Transmissive ^Resist Absorptive ^Resist

Selectivity

8 6 4 2 0 8

Figure 3 shows structure and manufacturing process of ZrSiO-based att-PSM. On quartz glass, shifter film is formed by stacking attenuated film (AF) with low oxygen concentration for transmissivity modulation and oxygen-rich transparent film (TF) for phase modulation.

14 Pressure (Pa)

Figure 5. Etching selectivity among films of ZrSiO-based att-PSM in dr y etching.

the ZrSiO-based att-PSM makes it possible to conduct inspection without employing any special algorithms.

Chromium (Cr) opaque film is stacked on top of the shifter film. The shifter film is composed of two layers in order to lower transmissivity not only of excimer laser from the exposure tool with wavelength of 193 nm, but also of light from measurement and inspection tools featuring wavelengths of 365 nm, 488 nm, and 550 nm. For tri-tone-type att-PSM in which Cr patterns are used to shield light for part of half-tone patterns, an overlay process is conducted to fabricate patterns on the Cr opaque film. This process, however, is the same as the conventional MoSi-based att-PSM manufacturing process. Figure 4 shows spectral characteristics of ZrSiO-based att-PSM blank which features ArF transmissivity of six percent. Transmissivity of light with wavelength of 365 nm is suppressed below 13 percent, which means

Detection sensitivity is currently being investigated by using test masks with programmed multiphase defects. The ZrSiO-based att-PSM, which has been tested with a position-accuracy measurement tool and the CD SEM, has proved to be the preferred measurement technique. Conditions for the mask-making process, such as those for dry etching, have been established. Figure 5 shows etching selectivity as a function of working pressure in dry etching using BCl3 gas. Selectivity between the anti-transmission film (AF) and the underlying quartz substrate can be increased to more than ten by increasing the reaction pressure. It is possible, therefore, to improve the uniformity of phase shift and of transmissivity within the six-inch mask to the level of the mask blank.

Transmittance (%)

ZrSiO 30

0 200

Quartz 300

400

500

600

Wavelength (nm) Figure 4. Spectral characteristics of ZrSiO-based att-PSM blank featuring Figure 6. Pattern profile of ZrSiO-based att-PSM.

ArF transmissivity of six percent.

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0.5 Âľm

Spec. of Blank

Spec. of Process

Spec. of Mask

Spec. of Litho

Item Transmittance @ 193nm Reflectance @ 193nm Phase shift accuracy Phase shift within a mask Transmittance accuracy Transmittance within a mask Durability for chemicals [phase shift change] [transmittance change] Dry etching selectivity to resist to substrate Pattern profile Minimum feature size CD uniformity CD mean to target Image placement error Phase shift accuracy Phase shift within a mask Transmittance accuracy Transmittance within a mask Irradiation durability

2â&#x20AC;&#x201C;20% < 25% 180 +/- 2 deg. 2 degrees Target +/- 0.3% 0.3 +/- 1 deg. +/- 0.1 deg. >1 > 10 80 degrees 400nm +/- 12nm +/- 12nm 30nm 180 +/- 3 deg. 3 deg. Target +/- 0.3% 0.3 > 3 years

Figure 7. ArF lithography photomask targets in 2001.

As shown in the SEM image(s) (Figure 6), the pattern profile is extremely good; it does not have any boundary layers formed due to gap of oxygen concentration in half-tone film. This leads to considerable improvement in lithography performance.

100

Target for 2001

PS (deg.)

Transmittance (%)