Introduction

The precise control of feature size exhibits great importance in fabricating nanodevices for optoelectronics1,2, plasmonics3,4, metasurfaces5,6, and biosciences7,8, just to name a few. Some applications highly require uniform critical dimensions of nanostructures such as nanogratings applied in astronomy9, precision measurements10, or laser applications11, of which non-uniform feature sizes are regarded as defects or aberrations, deteriorating the device performance. But some devices heavily rely on nanostructures with spatially varying feature sizes, such as structural color paintings12,13, metalenses14,15,16, and diffractive waveguides17,18. For example, functional nanostructures can directly generate a structural color by separating light via scattering and diffraction, while the color is mainly dependent on the dimensions and materials19,20,21. Moreover, spatially arranging the dimensions and orientations of nanostructures enables the manipulation of light propagation via phase control, which has been widely adopted in the emerging metalenses22,23.

To date, the precise manipulation of feature size for nanopatterning on a large area is still challenging. Generally, the mainstream approaches for accurate nanopatterning are electron beam lithography (EBL)24,25 and focused ion beam (FIB) milling26,27. However, both are serial pixel-by-pixel writing processes, placing a limitation on the patterning area and suffering from low writing efficiency. Although high-throughput nanofabrication techniques such as interference lithography (IL)28,29 and nanoimprint lithography30,31 are capable of large-area patterning, the former is mainly for fabricating periodic structures and the latter heavily relies on the master imprint mold. In our previous work, the Gaussian-distributed beam profile in the IL has been utilized to fabricate spatially varying nanostructures with a circular gradient profile and demonstrate their applications in wettability manipulation and biosensing32,33. However, because the circular gradient profile is due to the Gaussian distribution of the beam intensity, it is still impossible to achieve an arbitrary modulation profile of the nanostructure feature sizes. Therefore, devising a nanopatterning approach that simultaneously satisfies (1) high-throughput and large-area patterning and (2) precisely and spatially modulating feature size, remains a challenge.

In this paper, we propose a nanopatterning strategy that combines IL and grayscale-patterned secondary exposure (IL-GPSE) to address the above challenges. Used for high-throughput fabrication of nanostructures, IL first efficiently exposes a large-area periodic nanoscale pattern on the photoresist. Then a secondary exposure (SE) of ultraviolet (UV) light, carrying a designed intensity distribution of a grayscale pattern, is applied to the IL-exposed substrate to spatially modulate the feature sizes of individual nanostructures. IL-GPSE allows wafer-scale nanostructure patterning with improved uniformity by compensating the linewidth variation caused by the non-uniform IL exposure field using a specially designed SE intensity distribution. We demonstrated a 4-inch wafer patterned by uniform 400-nm-period and 125-nm-linewidth nanogratings, with the linewidth uniformity improved by 1100% over IL-only exposure. Besides, a 3-inch grayscale painting was also demonstrated as the IL-GPSE enables precise grayscale control by tuning the filling ratio of nanostructures, indicating potential applications in flat optical devices and structural color encryption, etc.

Results

Mechanism of feature size modulation on the IL-exposed nanopatterns using SE

The feature size modulation using IL-GPSE was achieved by a combination of two exposure processes, a high-contrast IL for fabricating large-area periodic nanostructures and a SE for locally tailoring structural dimensions, as illustrated in Fig. 1. Using a positive photoresist as the example, a typical two-beam IL is first implemented to form periodic latent exposed regions with sinusoidal dose profile34,35. The positive photoresist that receives exposure dose above the clearing threshold would be “washed out” during the development while that below the threshold remains36,37. The linewidth of the developed gratings mainly depends on the area proportion exposed below the threshold38,39. In the IL-GPSE fabrication, a SE will follow the IL exposure and provide an additional dose that superimposes on the IL sinusoidal dose profile to increase the effective dose applied on the photoresist, therefore increasing the portion of the photoresist that receives the above-threshold dose and leaving less photoresist after development. Thus, a linewidth modulation can be achieved by superimposing the IL exposure dose with a patterned SE dose.

Fig. 1: The schematic diagram of the IL-GPSE process.
figure 1

Step 1, a two-beam IL is performed on the photoresist to form periodic latent exposed regions with sinusoidal dose profile. Step 2, a secondary exposure follows the IL exposure and increases the effective dose applied to the photoresist which increases the portion of photoresist that receives above-threshold dose, and then leaves less photoresist after development

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To demonstrate the linewidth tunability of the above lithographic strategy, a series nanogratings with various linewidths were fabricated through the IL-GPSE with different combinations of IL dose and SE dose. The samples were first exposed with 1000-nm-period grating patterns with various IL doses from 27.6 to 55.2 mJ/cm2, and then followed by the SE of eight flood doses ranging from 0 to 13.2 mJ/cm2, respectively. Figure 2a shows the SEM characterization of these nanogratings, demonstrating a reliable control of the feature sizes by modulating both the initial IL and SE doses. The full width at half-maximum (FWHM) linewidth of the nanogratings was quantitatively characterized and recorded with the corresponding exposure doses in Fig. 2b, indicating that the samples exposed by different initial IL doses show different linewidth modulation ranges during SE. For example, the samples of 1000-nm-period gratings exposed by 27.6 mJ/cm2 IL dose have a 180-nm modulation range of the linewidth from 590 to 410 nm, while that of 55.2 mJ/cm2 IL dose can be tuned with a 140-nm range from 300 to 160 nm. Another notable phenomenon is that nanogratings exposed to different exposure combinations may have a similar FWHM linewidth, however, the sidewall morphologies show a great difference since increasing IL dose benefits vertical sidewall while the SE dose has less effect. Although in this work our investigation is mainly based on positive-tone photoresist, it is worth noting that the IL-GPSE process can also apply to negative-tone photoresist (Fig. S1).

Fig. 2: Experimental results and numerical model of feature size modulation by SE.
figure 2

a SEM image matrix of 1000-nm-period gratings with various linewidths fabricated by different IL and secondary exposure doses. b The FWHM linewidths measured in a, showing the linewidth is negatively correlated to both IL and secondary exposure doses. c Normalized measured photoresist remaining thickness as a function of exposure dose (blue squares) and the corresponding best-fitting curve (red line). d Simulation of the total exposure dose distribution and resulting developed photoresist profiles by setting photoresist contrast as extracted from c and contrast of IL exposure dose distribution as 0.95. e The simulated duty cycle variation as a function of the secondary exposure dose using various initial IL exposure doses

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Generally, the profile of the final exposed nanostructures depends on two important factors, the photoresist contrast and the distribution of the exposure dose. The former relates to not only the resist’s material properties but also baking and development conditions, and can be experimentally characterized using the photoresist characteristic curve40, as shown in Fig. 2c reveals the relation between the normalized photoresist remaining thickness and the exposure dose (details in Methods). The slope of the transition region in the curve largely determines the sidewall angle of the gratings. On the other hand, the distribution of the exposure dose, particularly its contrast, as defined as the relative ratio between the local doses in the constructive and destructive interference regions, also shows a significant influence on the pattern morphology. The dose distribution in the IL exposure can be numerically modeled from the spatial distribution of the electrical field of the two interfering coherent laser beams, by taking into account the fringe drifting due to environmental disturbance35 (details in Methods). The total exposure dose distribution is the summation of the IL exposure dose and the SE dose. The actual nanostructure pattern can be simulated by combining the experimental photoresist characteristic curve in Fig. 2c and the total exposure dose distribution, enabling the morphology prediction and process analysis in our IL-GPSE method. Figure 2d demonstrates the simulated photoresist morphologies varied with different SE doses from 0 to 0.6*Dc, where Dc represents the clearing dose used in the simulation for convenience (details in Methods). The FWHM linewidth shrinks as the SE dose increases, which conceptually confirms the linewidth modulation achieved by SE after IL. In addition, when assigning different photoresist contrast characteristics in the model to simulate the morphological variation, the sidewall angle changes with the photoresist contrast and it is roughly maintained during the linewidth tailoring by SE (Fig. S2). Similarly, simulations with different interference exposure dose distributions in Fig. S3 demonstrate that a high contrast in the interference exposure significantly enlarges the process window of the linewidth tunability since a low-contrast exposure results in photoresist height loss. Using this numerical model, we can also simulate the tuning range of the linewidth or the duty cycle with various initial IL exposure doses, as shown in Fig. 2e, which exhibit the similar trend as in the experimental measurement in Fig. 2b.

Spatial modulation of nanostructure feature sizes using grayscale-patterned SE

The linewidth manipulation mechanism makes it possible to modulate the nanostructure feature sizes according to a given spatial pattern (Fig. 3a). The patterned SE can be realized through a UV projector, a UV mask aligner, or direct laser writing (DLW). For example, a UV projector is capable of converting a digital grayscale image into the UV intensity distribution for spatially modulating the dimensions (Fig. S4). Figure 3b shows a 3-inch Si wafer carrying an HKU logo, consisting of 600-nm-period photoresist gratings with the linewidths in different regions modulated by the projected grayscale pattern. The photoresist was first exposed with 600-nm-period gratings using IL and then a grayscale image of an HKU logo was projected through a 405-nm projector (Fig. S5). The grayscale pattern projected on the pre-exposed photoresist spatially modulates the linewidths according to the digital grayscale image. SEM images were taken on different parts of the image, including the areas of background, “H”, “K”, and “U” letters respectively, demonstrating the corresponding linewidths of 250, 190, 140, and 110 nm, which indicates a >55% linewidth modulation range (Fig. 3c).

Fig. 3: Spatial modulation of nanostructure feature sizes using grayscale-patterned SE.
figure 3

a Schematic of spatial modulation of linewidth using patterned secondary exposure. b A 3-inch wafer carrying the HKU logo consisting of 600-nm-period photoresist gratings with the linewidths in different regions modulated by projected grayscale pattern. c SEM images taken on background, “H”, “K”, and “U” letters on the wafer, showing corresponding linewidths of 250, 190, 140, and 110 nm. d SEM image of a 600-nm-period hole array modulated by DLW secondary exposure. e Plot of the filling ratio of nanostructures in the green box in d versus the horizontal position, showing a resolution of 1.7 µm. f Optical microscope image of a 12-point-star pattern, consisting of 600-nm-period gratings with linewidths modulated by contact photolithography using a photomask. SEM images taken inside and outside the secondary exposure pattern, showing the 245-nm and 170-nm linewidths, respectively. g Green box and h yellow-box regions in f, characterized by (i) SEM images and (ii) linewidth distributions. i The linewidth variation measured every 200 nm along a grating line (white, Fig. 3h), showing the grating linewidth gradient of 35 nm/µm. Scale bars, 500 nm (c, f), 1 µm (g, h), and 2 µm (d)

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Our proposed strategy allows feature size tuning at micrometer scale, subject to the spatial resolution of the grayscale image of the patterned SE. As IL exposure creates a nearly uniform or slowly varying latent dose image in the photoresist, the resolution of the feature size modulation mainly depends on the resolution of the SE. We investigated the spatial resolution of SE using DLW at different critical dimensions (Fig. S6). The SEM image in Fig. 3d shows an IL-exposed nanohole array in which some holes are transformed into pillars with a SE modulation. The filling ratio of the modulated patterns ranges from over 0.7 to below 0.4 and demonstrates a spatial resolution of ~1.7 microns, as illustrated in Fig. 3e. With single-pixel exposure of 1-µm resolution, we further achieved the fabrication of a photonic crystal pattern with a defect, providing an innovative way to fabricate photonic crystal cavities over a large area for fundamental photonics research and practical device applications, as shown in Fig. S7.

In addition, we also carried out the linewidth modulation on a uniform nanograting using contact photolithography with a photomask. The optical microscope image in Fig. 3f shows a 12-point-star pattern consisting of 600-nm-period gratings with 245-nm linewidth inside and 170-nm outside. Figure 3g(i) and 3h(i) show the SEM images of the photoresist gratings recorded in the tip regions, labeled using green and yellow boxes, in which the grating linewidth changes within a short distance at the pattern edge. The linewidth distribution is mapped in Fig. 3g(ii) and 3h(ii) clearly exhibited the tip outlines with a transition distance of ~2 microns, as quantitatively analyzed in Fig. 3i. The precise quantitative characterization by measuring the linewidth every 200 nm along a grating line (white, Fig. 3h) shows a 35-nm/µm grating linewidth gradient induced by the edge diffraction of patterned SE.

Uniform 4-inch wafer-scale patterning using IL-GPSE

The proposed IL-GPSE can also be applied on non-uniform nanostructures, which are caused by the non-uniform laser beam intensity during IL, to compensate for the spatial variation for improved uniformity, which is essential in many optical applications that demand large-area uniform gratings41,42 and precise interferometry43. Generally, large-area nanogratings fabricated by IL suffer radial-gradient linewidths due to the Gaussian profile in the interfering beams, and researchers often expand the Gaussian beam44 or implement beam shaping devices to transform the Gaussian distribution to a flat top distribution45 to acquire a relatively uniform intensity at the central exposure area. However, the former wastes a large amount of exposure energy and decreases the production capacity while the latter introduces a new challenge of fabricating high-quality large-area beam shaping devices. Employing the SE with a properly designed intensity distribution after the conventional IL with Gaussian intensity profile offers a new and efficient approach to compensating the linewidth variation (Fig. 4a). Figure 4b shows IL-exposed 400-nm-period gratings over a 4-inch wafer. The diffracted blue light intensity gradually decreases from the center to the edge due to Gaussian intensity distribution (Fig. S8), resulting in an increasing linewidth variation from the center to the edge due to the spatially decreasing intensity. We recorded SEM images every 2.5 mm along the radius of the 4-inch wafer (Fig. S9), morphologies of four typical positions were illustrated in Fig. 4c to show the linewidths of 127, 135, 158, and 270 nm, of which a poor control of both linewidth and linewidth roughness was observed near the edge.

Fig. 4: Uniform 4-inch wafer-scale patterning using IL-GPSE.
figure 4

a Schematic of uniform nanopatterning using secondary exposure to compensate the linewidth variation due to the non-uniform laser beam intensity during IL. b Photograph of IL-exposed 400-nm-period gratings over a 4-inch wafer with the diffracted blue light intensity gradually decreasing from the center to the edge. c SEM images taken in the labeled positions in b, showing a poor control of linewidth and roughness. d Photograph of 400-nm-period gratings over a 4-inch wafer using secondary exposure with a designed projected grayscale pattern after IL exposure, diffracting uniform blue light. e SEM images recorded in the labeled positions in g, showing the uniform linewidth and linewidth roughness. f The 4-inch (i) intensity distribution for linewidth tailoring and (ii) devised grayscale image transformed by the characterized relation between the digital grayscale value and projected light intensity via the UV projector. The comparisons of g linewidth and h linewidth roughness distributions over the radius of 4-inch wafers w/o the secondary exposure, respectively. Scale bars: 500 nm

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In contrast, by performing the SE with a designed intensity distribution complementary to the Gaussian distribution, the pattern uniformity, and line edge roughness can be significantly improved. By referring to SEM images and corresponding linewidths under different IL and SE doses, as shown in Figs. S10 and S11, respectively, the SE intensity map required for compensating the non-uniform IL linewidth variation on the 4-inch wafer can be designed. Figure 4f shows the 4-inch intensity map for linewidth tailoring and the devised grayscale image, transformed by using the characterized relationships between the digital grayscale value and projected light intensity via the UV projector (Fig. S12). After applying the SE with the projected grayscale pattern, a 4-inch wafer carrying gratings with highly homogeneous linewidths was obtained and uniformly diffracted blue light, as shown in Fig. 4d. SEM images were obtained on both un-compensated and compensated grating samples for comparison, as in Fig. 4c, e, and showed a significant improvement in grating linewidth uniformity and line edge roughness.

The linewidth distributions were statistically analyzed by measuring the linewidth of the SEM image captured every 2.5 mm along the radius from the wafer center to the edge (Fig. S13). The comparison of linewidth distributions in Fig. 4g shows that gratings tailored by SE had a linewidth deviation of 3.2 nm, which is over 1100% reduced from 36.2 nm, that of the gratings exposed only by IL. The SEM images also show that the linewidth roughness was significantly improved through SE, especially for the gratings near the edge. The difference originates from the total exposure dose on the photoresist, of which a higher dose facilitates the diffusion of photoacid compounds. As a result, a >580% improvement (from 8.7 nm to 1.5 nm) is obtained in the linewidth roughness characterization when the SE is employed (Fig. 4h).

Large-area grayscale painting using IL-GPSE

In addition to the large-area patterning of uniform gratings, the IL-GPSE method also enables the filling ratio modulation for two-dimensional (2D) nanostructures (Fig. 5a), which are major building blocks in structural color based paintings46. Most structural color paintings using 2D nanostructures can be fabricated only on small areas of millimeter scale or less because they need to use EBL, an expensive and time-consuming tool, for high-resolution patterning of spatially varying structures. By adopting our proposed IL-GPSE method, structural color paintings can be fabricated on wafer-scale, because both the IL and patterned SE can be done at a large scale while maintaining sufficiently high resolution. Another factor that needs to be considered is that the diffraction-induced coloration caused by the nanostructure periodicity will interfere with the designed structural color, especially over large-area samples47,48. We intentionally adopt a microscopically roughened surface to mitigate this diffraction effect by randomly scattering the diffracted light. We applied the IL-GPSE process on the unpolished side of an Si wafer and investigated the structural color variation under various SE intensities. As shown in Fig. 5b, 25 squares of 700-nm-period 2D patterns on photoresist modulated by SE projection show a clear grayscale color change from dark brown to light gold, of which the corresponding reflectance increases (Fig. S14). SEM characterization shows non-uniform 2D periodic nanopatterns on the microscopically irregular surface (Fig. 5c and Fig. S15), from which the filling fraction of the photoresist can be extracted (details in Methods). Figure 5d demonstrates that the photoresist filling ratio is negatively correlated to the SE dose, which confirms the lateral filling ratio modulation by SE enables the grayscale tunability.

Fig. 5: Large-area grayscale painting using IL-GPSE.
figure 5

a Schematic of spatial modulation of filling ratio for 2D nanostructures using IL-GPSE. b The photograph of 25 squares of 700-nm-period 2D patterns on photoresist modulated by SE projection, showing a clear grayscale change from dark brown to light gold. c SEM images of the region labeled using white box in b. d Fraction area of photoresist calculated from SEM images of Fig. S15, showing a negative correlation between the photoresist filling ratio and the SE dose. e A photograph of the 3-inch grayscale painting of Along the River During the Qingming Festival in photoresist patterned by IL-GPSE. f A dynamic structural color due to the residual diffraction at tilting angles. Grayscale paintings patterned by IL-GPSE are further g etched into 300-nm-thick SiO2-coated Si wafer, or h deposited with 50-nm-thick Ag on glass. Scale bars, 2 µm (inset in c), 10 µm (c), and 1 cm (b, fh)

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We further demonstrate a grayscale painting using wafer-scale IL-GPSE. The SE projects part of the renowned Chinese artistic painting Along the River During the Qingming Festival (Chinese name: Qingming Shanghe Tu) by Zhang Zeduan (1085–1145) (Fig. S16) on a 3-inch wafer, consisting of a latent image of 700-nm-period 2D patterns in the photoresist. After photoresist development, a grayscale replication of the painting appears on the Si substrate (Fig. 5e). When the wafer is tilted at different angles, a dynamic structural color due to the residual diffraction can also be observed (Fig. 5f), indicating potential applications in cryptography or anti-counterfeiting. Moreover, pattern transfer into other materials can be realized by combining IL-GPSE strategy with other nanofabrication techniques such as reactive ion etching and electron beam evaporation. As an example, Fig. 5g,h show the grayscale paintings of Girl with a Pearl Earring engraved in a 300-nm-thick SiO2-coated Si wafer and deposited with 50-nm-thick Ag on a glass substrate, respectively.

Discussion

In summary, we have invented a practical and scalable lithographic strategy that supports spatial modulation of the feature size of periodic nanostructures on a large area. Our fabrication portfolio uses IL to efficiently fabricate large-area periodic nanostructures and grayscale-patterned SE to spatially modulate the feature sizes. We successfully fabricated highly uniform nanogratings on a 4-inch wafer by compensating for the effect of the non-uniform Gaussian profile of the interference laser beams using a grayscale-patterned SE. Additionally, we demonstrated 3-inch grayscale painting with 2D nanostructures fabricated by IL-GPSE, which may also find potential applications in information encryption, anti-counterfeiting, etc. Our method can also benefit the fabrication of metasurfaces and metalenses that employ nanostructures with spatially modulated filling ratios49. By separating the high-resolution patterning of metasurface building blocks and the size modulation, our method can improve the patterning efficiency for these devices by orders of magnitude when compared with EBL.

Materials and methods

Fabrication of photoresist nanogratings

Firstly, the silicon wafer was ultrasonic cleaned with acetone, isopropanol, and deionized water for 5 min, respectively. Then after oxygen plasma treatment, the Si wafer was spin-coated with a 200-nm-thick anti-reflective coating (ARC; AZ BARLi-II, MicroChemicals, GmbH) layer at 2000 rpm and baked at 200 °C for 2 min to eliminate the standing wave effect in an exposure. Then the positive photoresist (AZ MiR 701, MicroChemicals, GmbH) was spin-coated at 3000 rpm and pre-baked at 90 °C for 60 s. Original and diluted (1:1 with propylene glycol methyl ether acetate) photoresists were used for patterning the periods of 1000 nm/700 nm/600 nm and 400 nm, respectively. The samples were first exposed by a home-made IL system with a 405-nm laser (Omicron, GmbH) to form large-area periodic latent nanostructures and then were exposed via a UV projector (Xiamen Zhisen Electro. Equip. Co., Ltd.), a UV mask aligner (URE-2000/35, Chinese Academy of Sciences), or a DLW machine (MicroWriter ML3, Durham Magneto Optics Ltd.) to spatially modulate the latent feature sizes. After performing IL-GPSE process, samples were post-baked at 110 °C for 60 s, developed (AZ 726 MIF, MicroChemicals, GmbH) for 60 s, and rinsed thoroughly with deionized water.

Obtaining the photoresist characteristic curves

The raw data were recorded by exposing 800-nm-thick photoresist on ARC/Si substrates with different exposure doses and then measuring the corresponding residual thicknesses after development. The remaining photoresist thickness, T, was then normalized to the initial unexposed thickness and plotted as a fitting function of the dose, D, to fit the characteristic curve50:

$$T\left( D \right) = \frac{1}{{1 + e^{{\gamma }\left( {D - D_{{{{\mathrm{c}}}}}}\right)}}}$$
(1)

where Dc is the clearing dose and γ is the photoresist contrast, extracted to be 40.77 and 0.2474. As a convenience, Dc and γ are regarded as basic units of parameters in simulations. Notably, the photoresist characteristic curves should be recalibrated with experimental data when the process conditions, such as the photoresist type, thickness, development parameters, etc., are changed.

Numerical model of IL-GPSE strategy

The interference exposure dose distribution on the photoresist can be calculated as

$$D_{{{{\mathrm{IL}}}}}\left( x \right) = D_{{{{\mathrm{IL}}}}}\left[ {1 + {\Gamma}\cos \left( {\frac{{2\pi x}}{p}} \right)} \right]$$
(2)

where Γ is the contrast of the interference exposure dose distribution, p is the grating period, and x is the horizontal position. By superimposing a SE on the IL dose distribution, the total exposure dose can be described as

$$D_{{{\mathrm{T}}}}\left( x \right) = D_{{{{\mathrm{IL}}}}}\left( x \right) + D_{{{{\mathrm{SE}}}}}\left( x \right)$$
(3)

where DSE(x) is the distribution of SE dose. When the SE is a flood exposure, DSE(x) should be a constant; when it is a grayscale pattern exposure, DSE(x) should be a variable depending on spatial distribution. By applying Eqs. (13), a spatial photoresist thickness variation can be obtained as the numerical model.

Extraction of the photoresist filling ratio

SEM images are saved as uint16 data type which shows morphological information of nanostructures using 256 grayscale values. In the SEM images, the photoresist appears brighter while the exposed silicon surface appears dark. By obtaining the grayscale values of all pixels and setting a properly chosen threshold, the number of pixels that are covered by photoresist can be counted and the photoresist filling ratio can be calculated.

Fabrication of the grayscale painting

For the grayscale painting of Along the River During the Qingming Festival, IL-GPSE was employed on the backside of a 3-inch 200-nm-thick SiO2-coated silicon wafer, spin-coated with 200-nm-thick ARC and 800-nm-thick photoresist. For the grayscale painting of Girl with a Pearl Earring in Fig. 5g, IL-GPSE was first employed on the backside of a 300-nm-thick SiO2-coated silicon substrate, spin-coated with 200-nm-thick ARC and 800-nm-thick photoresist. After patterning on the photoresist, the underlying ARC and SiO2 layers were etched using O2 plasma and CHF3/H2 in a reactive ion etching system (RIE-10NR, Samco), respectively, to transfer the pattern into SiO2. Finally, the photoresist and ARC residues were removed to complete the grayscale painting. For the grayscale painting of Girl with a Pearl Earring in Fig. 5h, IL-GPSE was first employed on a glass substrate, spin-coated with 200-nm-thick ARC and 800-nm-thick photoresist. After patterning in the photoresist, the underlying ARC layer was etched using O2 plasma to expose the surface of glass. Next, 50-nm-thick Ag was deposited using electron beam evaporation (EB500-I, Shenyang Scientific Instrument Ltd.). Finally, a lift-off process was performed with ultrasonic cleaning in RCA-1 solution (NH3·H2O:H2O2:H2O = 1:1:5) at 80 °C for 3 min, leaving the glass substrate with Ag grayscale pattern.

Characterizations

SEM (Zeiss Sigma 300) was performed to characterize the morphologies of the nanostructures. SEM images were analyzed by a commercial software ProSEM (GenISys Ltd.) statistically calculate the linewidth and roughness. The photoresist thickness was measured by an ellipsometer (TF-UVISEL, HORIBA Jobin Yvon). The light intensity was measured by a commercial digital power meter (PM160, Thorlabs, Inc.). The reflective spectra were collected using a commercial spectrometer (QE65Pro, Ocean Optics).