Hostname: page-component-586b7cd67f-t7fkt Total loading time: 0 Render date: 2024-11-22T16:39:39.783Z Has data issue: false hasContentIssue false

Multilayer dielectric grating pillar-removal damage induced by a picosecond laser

Published online by Cambridge University Press:  11 November 2022

Kun Shuai
Affiliation:
School of Materials Science and Engineering, Wuhan University of Technology, Wuhan, China Laboratory of Thin Film Optics, Shanghai Institute of Optics and Fine Mechanics, Shanghai, China
Xiaofeng Liu
Affiliation:
Laboratory of Thin Film Optics, Shanghai Institute of Optics and Fine Mechanics, Shanghai, China
Yuanan Zhao*
Affiliation:
Laboratory of Thin Film Optics, Shanghai Institute of Optics and Fine Mechanics, Shanghai, China
Keqiang Qiu
Affiliation:
National Synchrotron Radiation Laboratory, University of Science and Technology of China, Hefei, China
Dawei Li
Affiliation:
Laboratory of Thin Film Optics, Shanghai Institute of Optics and Fine Mechanics, Shanghai, China
He Gong
Affiliation:
School of Optical-Electrical and Computer Engineering, University of Shanghai for Science and Technology, Shanghai, China
Jian Sun
Affiliation:
Laboratory of Thin Film Optics, Shanghai Institute of Optics and Fine Mechanics, Shanghai, China
Li Zhou
Affiliation:
National Laboratory on High Power Laser and Physics, Shanghai Institute of Optics and Fine Mechanics, CAS, Shanghai, China
Youen Jiang
Affiliation:
National Laboratory on High Power Laser and Physics, Shanghai Institute of Optics and Fine Mechanics, CAS, Shanghai, China
Yaping Dai
Affiliation:
Research Center of Laser Fusion, China Academy of Engineering Physics, Mianyang, China
Jianda Shao
Affiliation:
Laboratory of Thin Film Optics, Shanghai Institute of Optics and Fine Mechanics, Shanghai, China Hangzhou Institute for Advanced Study, University of Chinese Academy of Sciences, Hangzhou, China
Zhilin Xia*
Affiliation:
School of Materials Science and Engineering, Wuhan University of Technology, Wuhan, China
*
Correspondence to: Y. Zhao, Laboratory of Thin Film Optics, Shanghai Institute of Optics and Fine Mechanics, Shanghai 201800, China. Email: [email protected]. Zhilin Xia, School of Materials Science and Engineering, Wuhan University of Technology, Wuhan 430070, China. Email: [email protected]
Correspondence to: Y. Zhao, Laboratory of Thin Film Optics, Shanghai Institute of Optics and Fine Mechanics, Shanghai 201800, China. Email: [email protected]. Zhilin Xia, School of Materials Science and Engineering, Wuhan University of Technology, Wuhan 430070, China. Email: [email protected]

Abstract

Multilayer dielectric gratings typically remove multiple-grating pillars after picosecond laser irradiation; however, the dynamic formation process of the removal is still unclear. In this study, the damage morphologies of multilayer dielectric gratings induced by an 8.6-ps laser pulse were closely examined. The damage included the removal of a single grating pillar and consecutive adjacent grating pillars and did not involve the destruction of the internal high-reflection mirror structure. Comparative analysis of the two damage morphological characteristics indicated the removal of adjacent pillars was related to an impact process caused by the eruption of localized materials from the left-hand pillar, exerting impact pressure on its adjacent pillars and eventually resulting in multiple pillar removal. A finite-element strain model was used to calculate the stress distribution of the grating after impact. According to the electric field distribution, the eruptive pressure of the dielectric materials after ionization was also simulated. The results suggest that the eruptive pressure resulted in a stress concentration at the root of the adjacent pillar that was sufficient to cause damage, corresponding to the experimental removal of the adjacent pillar from the root. This study provides further understanding of the laser-induced damage behavior of grating pillars and some insights into reducing the undesirable damage process for practical applications.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2022. Published by Cambridge University Press in association with Chinese Laser Press

1 Introduction

The advancement in ultra-high-intensity petawatt laser systems[ Reference Danson, Hillier, Hopps and Neely 1 Reference Zhang, Wu, Hu, Yang, Gui, Ji, Liu, Wang, Liu, Lu, Xu, Leng, Li and Xu 4 ] has promoted the development of extreme physics experiments, laser acceleration devices and biomedical engineering[ Reference Hatchett, Brown, Cowan, Henry, Johnson, Key, Koch, Langdon, Lasinski, Lee, Mackinnon, Pennington, Perry, Phillips, Roth, Sangster, Singh, Snavely, Stoyer, Wilks and Yasuike 5 Reference Hornung, Zobus, Boller, Brabetz, Eisenbarth, Kuhl, Major, Ohland, Zepf, Zielbauer and Bagnoud 8 ]. The chirped pulse amplification (CPA) technology proposed by Gérard Mourou and Donna Strickland[ Reference Strickland and Mourou 9 ] in 1985 was a breakthrough in ultra-intense pulse laser systems. In the CPA system, it is necessary to utilize the dispersion characteristics of diffraction gratings to stretch and compress the laser pulses in the time domain before and after amplification to avoid the nonlinear effect caused by directly amplifying ultrashort laser pulses[ Reference Strickland and Mourou 9 Reference Zhou 11 ]. The final grating must endure the irradiation of the strongest laser pulse. Therefore, research on the laser damage of pulse compression gratings in short pulses has always been a focus in CPA-based laser systems.

Svakhin et al.[ Reference Svakhin, Sychugov and Tikhomirov 12 ] first prepared a multilayer dielectric grating (MLDG) by etching relief structures on multilayer dielectric films (MLDFs) composed of alternating high- and low-refractive-index dielectric materials, which theoretically have nearly 100% diffraction efficiency and a higher laser-induced damage threshold (LIDT) because of the negligible intrinsic absorption of dielectric materials. The one-on-one LIDTs of MLDGs exhibited a linear dependence on the maximum electric field intensity (EFI) enhancement in short pulses[ Reference Neauport, Lavastre, Raze, Dupuy, Bonod, Balas, de Villele, Flamand, Kaladgew and Desserouer 13 ]. Therefore, near-field theoretical optimization of the LIDT improvement is widely used in MLDG fabrication. For pulses with a duration of femtoseconds (fs), the deterministic initial damage occurred on the ridge of the pillars where the maximum EFI enhancement was located[ Reference Neauport, Lavastre, Raze, Dupuy, Bonod, Balas, de Villele, Flamand, Kaladgew and Desserouer 13 Reference Hocquet, Neauport and Bonod 15 ]. This damage was caused by high-energy electrons excited by a strong laser electric field. For picosecond (ps) pulses, in most cases, damage involves the removal of multiple adjacent grating pillar sections[ Reference Hoffman, Kozlov, Liu, Huang, Oliver, Rigatti, Kessler, Shestopalov and Demos 16 , Reference Alessi, Carr, Hackel, Negres, Stanion, Fair, Cross, Nissen, Luthi, Guss, Britten, Gourdin and Haefner 17 ]. It was reported that the optical performance of MLDGs decreases as the damage size increases[ Reference Kong, Jin, Guan, Liu, Wu, Du and He 18 ]. However, the dynamic formation process of the final multiple-grating pillar removal remains unclear.

The removal of the grating pillars involves a mechanical damage mechanism that is considered to be caused by the stress waves generated by the confined plasma inside the pillars[ Reference Demos, Negres, Raman, Feit, Manes and Rubenchik 19 , Reference Berthe, Fabbro, Peyre, Tollier and Bartnicki 20 ]. Gracewski et al.[ Reference Gracewski, Boylan, Lambropoulos, Oliver, Kessler and Demos 21 ] simulated the internal stress waves of the central pillar in the damaged region by loading pressure pulses with Gaussian time dependence. The pressure pulse normal to the mid-point of the side wall of the pillar with a temporal pulse width of 100 ps caused high tensile stress at the bottom of the pillar, whereas a potential damage region was predicted only at the height of the applied pressure for 10 ps, which did not correspond to the phenomenon of pillar separation from its bottom. Hoffman et al.[ Reference Hoffman, Kozlov, Liu, Huang, Oliver, Rigatti, Kessler, Shestopalov and Demos 16 ] reported the damage characteristic of large-area removal of three adjacent grating pillars, presumably driven by defects in the middle pillar of the three-pillar damage site. Kong et al.[ Reference Kong, Jin, Guan, Liu, Wu, Du and He 18 ] proved that the local removal of the grating pillar enhanced the maximum EFI of its adjacent pillars, causing further growth of the damage site under subsequent laser pulse irradiation. However, no studies have revealed the dynamic interaction process between damaged pillars from experiments under a single laser pulse, resulting in an insufficient understanding of the damage to adjacent pillars.

In this study, the damage morphologies of MLDGs produced by an 8.6-ps laser pulse are examined to reveal their dynamic formation process. The damage resulted in the removal of adjacent grating pillars at 8.6 ps, which did not involve the destruction of the internal high-reflection (HR) mirror structure when compared with the nano-absorbing defect-induced damage[ Reference Lin, Zhao, Liu, Li, Ma, Shao, Qiu, Sun, Kong and Zhu 22 ] located at the layer interface of the MLDG under nanosecond (ns) laser irradiation. Morphological analysis indicated that the removal of adjacent grating pillars was related to the eruptive pressure of the initially damaged pillar. An interaction process of the adjacent damaged pillars is proposed, in which the high-energy superheated materials at the peak EFI site of the initially damaged pillar erupt first and impinge on its adjacent pillar, forming a fracture from the root of the adjacent pillar. A two-dimensional finite-element strain model is developed to simulate the stress distribution in an impacted pillar. Meanwhile, the ionization rate equations and two-temperature model (TTM) are coupled to calculate the eruptive pressure. The results indicate that the impact pressure of the erupted materials can cause a stress concentration at the root of the adjacent pillar that exceeds its tensile strength, corresponding to its removal morphology.

2 Sample and experimental methods

MLDFs were first obtained by depositing high (HfO2) and low (SiO2) refractivity film materials on fused silica substrates with dimensions of 50 mm × 50 mm × 1.5 mm using electron beam evaporation[ Reference Lin, Zhao, Liu, Li, Ma, Shao, Qiu, Sun, Kong and Zhu 22 ]. Subsequently, the photoresist material was spun on the MLDF, and a photoresist grating relief structure was prepared using the holographic method[ Reference Qiu, Xu, Liu, Hong and Fu 23 ]. The trapezoidal grating structures were transferred to the SiO2 top layer by reactive ion-beam etching[ Reference Qiu, Xu, Liu, Hong and Fu 23 , Reference Guzhov 24 ]. A mixture of strong acids and oxidants was used to remove organic residues on the surface of the grating. The MLDGs prepared based on the above methods consist of a bottom-fused silica substrate, internal HR mirrors, top SiO2 matching layer and trapezoidal reliefs, as shown in Figure 1(a). Figure 1(b) shows that the –1st-order diffraction efficiency of the MLDG is greater than 96% at an incident angle of 67° for transverse electric (TE) polarized laser light with a wavelength of 1053 nm. The inset image in Figure 1(b) shows the pristine cross-sectional morphology of the MLDG using scanning electron microscopy (SEM).

Figure 1 (a) Schematic representation of the MLDG and (b) the –1st-order diffraction efficiency of the MLDG; the inset shows an SEM image of the pristine cross-sectional morphology of the MLDG. The measured grating period T = 580 nm, mid-waist duty cycle ƒ = 0.38, groove depth D = 415 nm and base angle of the grating pillar θ = 87°.

Picosecond-pulsed laser damage experiments[ Reference Hao, Sun, Shi, Pan, Zhu, Pang and Zhu 25 ] were performed using the laser damage test system described by Hao et al.[ Reference Hao, Sun, Shi, Pan, Zhu, Pang and Zhu 25 ]. An incident laser[ Reference Peng, Pan, Wang, Fan and Li 26 ] with a central wavelength of 1053 nm, a pulse width of 8.6 ps and a repetition rate of 1 Hz was irradiated on the surface of the grating. The focused near-Gaussian spatial profile beam had a waist diameter of 97.8 μm at normal incidence and the MLDG sample was set on the focal plane. Testing was performed in an air environment at an incident angle of 70° in S-polarization. The one-on-one mode was used for the damage test: each test site was irradiated by a single laser shot and 10 sampling points were exposed to the same fluence pulses during the test. The damage was monitored using a charge-coupled device with a white light source. After the experiments, the damage morphologies were characterized by optical microscopy and SEM (model: Zeiss Auriga). The LIDT of the MLDGs was obtained by damage probability linear extrapolation[ Reference Becker and Bernhardt 27 ], as shown in Figure 2. The measured LIDT of the MLDG was 2.2 ± 0.1 J/cm2. Note that the laser fluence mentioned in this study is given in the beam normal.

Figure 2 Damage probability fitting curve of MLDGs under one-on-one test mode. The LIDT of the MLDGs was 2.2 J/cm2 irradiated by an 8.6 ps-pulsed laser with the wavelength of 1053 nm.

In a short-pulse laser damage system, the self-focusing effect in the air caused by the high-peak-power-focused beam should be estimated. The self-focusing effect was defined by evaluating the B-integral[ Reference Neauport, Lavastre, Raze, Dupuy, Bonod, Balas, de Villele, Flamand, Kaladgew and Desserouer 13 ] at the focus, which can be expressed as follows:

(1) $$\begin{align}B=\frac{4\pi}{\lambda^2}{n}_2\frac{\xi}{\tau},\end{align}$$

where λ is the laser wavelength, the nonlinear refractive index ${n}_2$ is $3\times {10}^{-19}\ {\mathrm{cm}}^2/ \mathrm{W}$ [ Reference Nibbering, Grillon, Franco, Prade and Mysyrowicz 28 ], τ is the laser duration and ξ is the laser energy. In our experiments, the maximum fluence of a single-shot pulse incident on the grating surface was 5.5 J/cm2, and the maximum incident energy was less than 0.5 mJ. According to Equation (1), the value of the B-integral was approximately 0.02, which is far from the air self-focusing critical value of approximately 1. Therefore, the self-focusing effect was absent in our experiments.

3 Damage morphology analysis

Figure 3(a) shows the typical damage morphology of the MLDGs. An incident laser with a fluence of 3.3 J/cm2 irradiated the grating surface from the left-hand side. The overall characteristic of the damage region was the grating pillar removal, which did not involve the destruction of the HR mirror structure because the damage of the internal layers would cause bulging of the grating surface or the formation of ejected pits[ Reference Alessi, Carr, Hackel, Negres, Stanion, Fair, Cross, Nissen, Luthi, Guss, Britten, Gourdin and Haefner 17 , Reference Lin, Zhao, Liu, Li, Shuai, Ma, Shao, Sun, Qiu, Cui, Dai and Shao 29 , Reference Huang, Kong, Xia, Jin, Li, Wang, Chen, Zhang, Cui and Shao 30 ]. Specifically, the damaged features can be classified as local damage to a single grating pillar and damage to multiple adjacent grating pillars in the horizontal direction.

Figure 3(b) shows the magnified local damage characteristics of a single grating pillar. The three damaged pillars with tiny missing backlight surface ridges in the yellow circles marked ① indicate the initial state of the damage process. This seems to grow into a larger removal that includes the entire top of the pillar, as shown by the yellow circle marked ②. The bottom of the missing region located inside the pillar has a smooth surface, which may be caused by the local melting of the pillar. The pillar material was observed to be overturned upward at the top of the removed area, indicating that the destruction involved a concentrated eruptive process in which the impact of superheated eruptive materials caused the top of the pillar to yield.

Figure 3 SEM images of typical damage morphology characteristics of the MLDGs. (a) Top-view image of the damage area irradiation by the ps-pulsed laser, and (b)–(d) are the local magnified views of the three black rectangular areas in (a). The test laser irradiated the surface from left to right with a fluence of 3.3 J/cm2.

The consecutive damage morphology of two or more adjacent grating pillars has been widely reported in previous studies[ Reference Hoffman, Kozlov, Liu, Huang, Oliver, Rigatti, Kessler, Shestopalov and Demos 16 , Reference Alessi, Carr, Hackel, Negres, Stanion, Fair, Cross, Nissen, Luthi, Guss, Britten, Gourdin and Haefner 17 ]. However, subtle phenomena between these pillars, revealing the damage process more intuitively, were observed in this study. The typical features are the damage to two adjacent grating pillars, as shown in the damaged area marked ③ in Figures 3(c) and 3(d). Table 1 lists the characteristics of the adjacent damaged pillars. The centers of the damaged pillars were arranged along the horizontal direction. A bright ‘foggy’ region was formed in the grooves of the gratings, starting from the right-hand (backlight) side of the left-hand pillar and extending continuously toward the right. In the left-hand damaged pillar, a 200-nm long fracture was formed on the surface, which was similar to the damaged pillar ②. This indicates that the removal of adjacent grating pillars should be the result of the growth of a single damaged pillar. In particular, the residual pillar materials collapsed toward the left, and cracks were observed on the pillar surface. Moreover, the right-hand damaged pillar fractured from its root, resulting in the removal of the entire pillar and the formation of a long fracture, along the longitudinal direction, of approximately 1 μm.

Table 1 Morphological characteristics of the adjacent damaged pillars.

According to the analysis of the morphological features of the adjacent damaged pillars, the formation of the adjacent pillar damage should be related to an eruptive impact process, as shown in Figure 3(c), where the high-energy superheated materials that erupted in the left-hand pillar propagated diffusely and produced an impact pressure on the adjacent pillar, causing the right-hand pillar to break from the root. Heat released during the eruption may have modified the groove and formed the ‘foggy’ region. The collapse of the residual left-hand pillar toward the left direction and the diffusion direction of the ‘foggy’ region further verify this dynamic eruptive process. The left-hand pillar was affected by the eruptive recoil force toward the left, which created a 200-nm long fracture on the surface and caused the pillar materials to collapse to the left. However, this limited recoil force could only achieve incomplete separation of the left-hand pillar. A fracture of approximately 1 μm along the longitudinal direction formed in the right-hand pillar due to the impact of the eruptive materials.

In the following section, this dynamic damage behavior is discussed through the stress field distribution of the right-hand pillar loading by the localized material eruptive pressure from the left-hand pillar.

4 Theoretical calculation and discussion

4.1 Stress field distribution in MLDGs

Figures 3(c) and 3(d) show the impact pressure of the erupted materials acting on the adjacent right-hand grating pillar. A two-dimensional plane strain finite-element model[ Reference Gracewski, Boylan, Lambropoulos, Oliver, Kessler and Demos 21 ] can be used to approximate the stress distribution. The impact pressure causes a uniform boundary load (P 0) on the right-hand pillar, as shown in Figure 4(a). The Young’s moduli of the SiO2, HfO2 and substrate used in the calculation are 72, 127 and 73 GPa, respectively. The Poisson’s ratios of the SiO2, HfO2 and substrate are 0.17, 0.18 and 0.17, respectively[ Reference Li and Xia 31 ]. For oxide dielectric materials, the tensile strengths are significantly lower than their compressive strengths (e.g., the compressive strength of fused silica is 690–1380 MPa, whereas its tensile strength is 110 MPa[ Reference Gracewski, Boylan, Lambropoulos, Oliver, Kessler and Demos 21 , 32 Reference Zheng, Wang, Cheng, Yue, Han, Zhang, Shan, Mao, Ye, Yin and Ma 34 ]). Therefore, the locations of maximum tensile stress were considered as indicators of the potential mechanical damage.

Figure 4 Two-dimensional finite-element strain simulation model and calculation results. (a) Schematic representation of the eruptive impact process; the localized eruption of the left-hand pillar induced a rightward impact pressure on the right-hand pillar. (b), (c) Normal stress distributions along the y- and x-axis directions, ${\sigma}_{{yy}}$ and ${\sigma}_{{xx}}$ , of the right-hand pillar in (a), respectively. Positive values are tensile stresses and negative values are compressive stresses.

In the simulation, we calculated the internal peak stress of the right-hand pillar after applying different initial boundary loads P 0. The calculation showed that the pillar would be damaged when the impact pressure applied to the right-hand pillar exceeded 20 MPa. The normal stress distributions inside the right-hand pillar when P 0 = 20 MPa are shown in Figures 4(b) and 4(c). The normal stresses in the y- and x-directions are expressed as ${\sigma}_{{yy}}$ and ${\sigma}_{{xx}}$ , respectively. Figure 4(b) shows that tensile and compressive stress concentrations are formed on the left- and right-hand sides of the pillar root in the y-direction, respectively. On the left-hand side of the pillar root, the peak ${\sigma}_{{yy}}$ of more than 300 MPa exceeds the tensile strength of the material, and fractures will primarily occur. In the x-direction, high-stress concentrations of more than 300 MPa on both sides of the pillar root, as shown in Figure 4(c), will induce pillar separation. Therefore, the high tensile stress in both the x- and y-directions from the left-hand side of the pillar root will inevitably cause the fractured pillar to flip. It will cause the fracture to propagate along the direction of the pressure, eventually leading to the removal of the entire pillar.

The peak normal stress in the y-direction of more than 300 MPa started to exceed the tensile strength of the material when P 0 = 20 MPa. Therefore, 20 MPa was chosen as the critical fracture pressure (CFP). By taking 20 MPa as the CFP, the critical eruptive pressure (CEP) from the left-hand pillar required to remove the right-hand pillar was estimated according to the ratio of the damaged cross-sectional areas of the two adjacent pillars. Meanwhile, the impact pressure on the right-hand pillar was uniformly distributed; otherwise, it would cause a larger localized stress concentration and lower CFP of the pillar. The ratio of the fracture lengths of the left- and right-hand damaged pillars along the longitudinal direction were approximately 1/5 and 1/6, respectively, as shown in Figure 3(c). In a homogeneous medium, the diffusion ratios of the localized eruption in different directions should be consistent. Therefore, the ratio of the damaged cross-sectional areas of adjacent pillars was regarded as the square of the ratio of their longitudinal fracture lengths and the diffusion ratio was approximately 1/36 to 1/25; the CEP of the left-hand pillar can be considered to be approximately 500–720 MPa since the CFP was 20 MPa.

4.2 Dynamic model of grating materials eruption

The physical process of grating materials eruption can be expressed as follows. Extensive free electrons, excited by the ionization of the grating materials, rapidly absorb laser energy under a strong laser field. Subsequently, the energy is transferred from electrons to lattices owing to electron–phonon scattering, and part of the materials can be heated to melt or even boil. These ionized superheated materials can be considered to be plasma, which causes a rapid increase in the internal pressure. The eruption occurs when the internal pressure exceeds the tensile strength of the material. The eruptive pressure of the plasma can be solved by coupling the following three modules with the time-domain finite-element method: (i) the electric field propagation module for solving Maxwell’s equations; (ii) the dynamic evolution module of the electronic density based on ionization rate equations; and (iii) the plasma eruptive pressure evaluation module.

4.2.1 Electric field distribution in gratings

The electric field distribution was calculated according to Maxwell’s equations:

(2) $$\begin{align}{\nabla}^2E+{k}^2{\mu}_{\mathrm{r}}{\varepsilon}_{\mathrm{r}}E=0,\end{align}$$

where ${E}$ is the EFI, ${\mu}_{\mathrm{r}}$ is the relative permeability, $k$ is the wave number in free space ( $k=\omega /{c}_0$ , where ω is the laser frequency and ${c}_0$ is the speed of light in vacuum), ${\varepsilon}_{\mathrm{r}}$ is the relative permittivity and ${\varepsilon}_{\mathrm{r}}={n}^2$ , where $n$ is the refractivity. For dielectric materials, the relative permeability was calculated based on the Drude model:

(3) $$\begin{align}{\varepsilon}_{\mathrm{r}}={\varepsilon}_{\mathrm{c}}-\left[{e}^2 {n}_{\mathrm{e}}/\left({m}_{\mathrm{e}} {\varepsilon}_{\mathrm{v}}\right)\right]/\left({\omega}^2+{\omega_{\mathrm{k}}}^{-2}\right),\end{align}$$

where ${\varepsilon}_{\mathrm{c}}$ is the materials dielectric constant in the normal state (2.02 for SiO2 and 3.4 for HfO2), $e$ is the electron charge, ${n}_{\mathrm{e}}$ is the free electron number density in the conduction band, ${m}_{\mathrm{e}}$ is the free electron mass, ${\varepsilon}_{\mathrm{v}}$ is the dielectric constant of vacuum and ${\omega}_{\mathrm{k}}$ is the electron–phonon scattering frequency.

Figure 5(a) shows the simulation model of the electric field. The incident light was irradiated from the left-hand side to the grating surface at an incident angle of 70° in S-polarization. Periodic boundaries were used on the left- and right-hand sides of the model to reduce the computation. Figure 5(b) illustrates the EFI distribution in the MLDG. The peaks of the EFI inside the grating are located on the backlight side of the ridge, and a row of strong-field regions is also distributed at the interfaces between SiO2 and HfO2. The uneven distribution of EFI in the grating leads to different ionization rates. In the region with the highest ionization rate, dense plasma forms first and induces damage. The initial damage position cannot be identified based on the EFI distribution only, considering that HfO2 has a lower material band gap than SiO2. Therefore, we analyzed the ionization process of the materials.

Figure 5 (a) Schematic representation of the electric field simulation model and (b) laser electric field distribution in MLDGs. The incident laser pulse is centered at 1053 nm, and its pulse width is 8.6 ps.

4.2.2 Ionization process of grating materials

The electron number density n e of the grating material can be calculated from the ionization rate. The ionization mechanism in the picosecond regime combines field and avalanche ionization. At the early stage of the laser pulse, valence band electrons transition to the conduction band by absorbing photon energy and become initial free electrons (i.e., field ionization dominates the ionization process). Multiphoton absorption can significantly promote the breakdown process when the photon energy band gap of the incident laser is approximately one-third that of the dielectric material[ Reference Bloembergen 35 ].

The field ionization rate was calculated using the Keldysh model[ Reference Keldysh 36 ]. Adopting the following parameter

(4) $$\begin{align}\gamma =\omega \sqrt{\left({m}_{\mathrm{e}} {E}_{\mathrm{g}}\right)}/\left(e E\right)\end{align}$$

to define multiphoton absorption and tunneling ionization, where ${E}_{\mathrm{g}}$ is the band gap of the material. For the case of low electric field and high laser frequency, $\gamma \gg 1$ , multiphoton ionization (MPI) dominates the ionization process. The ionization rate can be expressed as follows:

(5) $$\begin{align}{\omega}_{\mathrm{M}}=A f\left(\gamma \right) \varPhi {\left[2l-\left(2{E}_{\mathrm{g}}/\mathrm{\hslash} \omega \right)\right]}^{0.5},\end{align}$$

where $A=2\omega {\left({m}_{\mathrm{e}} \omega /\hslash \right)}^{1.5}/\left(9\pi \right)$ , $\kern0.24em \varPhi (z)$ is the Dawson integral and $\varPhi \left({z}\right)={\int}_0^{{z}}\exp \left({{y}}^2-{{z}}^2\right) \mathrm{d}y$ , $\kern0.24em f\left(\gamma \right)={e}^{\left[2{l} \left(1-0.25 {\gamma}^{-2}\right)\right]} {\left(4\gamma \right)}^{-2{l}}$ , where $l$ is the order of MPI, and it is the largest integer below ${E}_{\mathrm{g}}/\hslash \omega +1$ , where $\mathrm{\hslash}$ is the Planck constant. The tunneling phenomenon occurs when $\gamma \ll 1$ and can be neglected in our experiments .

Inelastic collisions between energetic electrons and ions lead to avalanche ionization, exponentially increasing the electronic density. The electronic density can be calculated using the following empirical formula[ Reference Gamaly 37 ]:

(6) $$\begin{align}{n}_{\mathrm{e}}={n}_{\mathrm{e}0} \exp \left({\omega}_{\mathrm{A}} {t}_{\mathrm{p}}\right),\end{align}$$

where ${n}_{\mathrm{e}0}$ is the initial electronic density[ Reference Li and Xia 31 ], ${t}_{\mathrm{p}}$ is the pulse width and ${\omega}_{\mathrm{A}}$ is the avalanche ionization rate, ${\omega}_{\mathrm{A}}=(\ln 2) {e}^2 \cdot {E}^2 {\tau}_{\mathrm{k}}/\left[{m}_{\mathrm{e}} {E}_{\mathrm{g}}\left(1+{\omega}^2 {\tau_{\mathrm{k}}}^2\right)\right]$ (see Ref. [Reference Li and Xia31]), where ${\tau}_{\mathrm{k}}$ is the electron–ion relaxation time.

Figure 6 shows the evolution of the electronic density for the grating ridge with the peak EFI and two internal HfO2 layers with a strong EFI. The electronic density greatly increased during the laser irradiation, and the backlight side of the top SiO2 pillar ridge had the maximum electronic density, exceeding 1.6 × 1027 m–3, irradiated by the laser pulse with a fluence of 3.3 J/cm2. Electron recombination and electron–phonon scattering reduced the electronic density after the laser pulse. For the internal strong-field HfO2 layers, although the material band gap of HfO2 is narrower than that of SiO2, its maximum electronic density only reached 6.8 × 1025 m–3 because of the limited EFI. This proves that the initial damage occurred in the pillar rather than in the HfO2 layers, as shown by ① in Figure 3(b).

Figure 6 Evolution of the electronic density ${n}_{\mathrm{e}}$ in the conduction band. The rectangular, circular and triangular shapes represent the sampling point curves on the upper inset image. The calculation time is three times that of the laser pulse width.

4.2.3 Eruptive pressure of the plasma

Free electrons excited by ionization can absorb the energy of the laser field, which is partially used in the eruption process. The eruptive pressure ${P}_0$ can be expressed as follows[ Reference Li and Xia 31 ]:

(7) $$\begin{align}{P}_0={E}_{\mathrm{k}}/V,\end{align}$$

where ${E}_{\mathrm{k}}$ is the total eruptive kinetic energy in volume $V$ . The ionization process forms a plasma inside the material, which is regarded as an ideal gas, and its eruptive kinetic energy[ Reference Zhou, Zhang, Zhou, Yin, Yang, Wu and Guo 38 ] can be written as follows:

(8) $$\begin{align}{E}_{\mathrm{k}}=\frac{\alpha -1}{2\alpha -1}{E}_{\mathrm{T}},\end{align}$$

where $\alpha$ is the adiabatic index of the plasma and ${E}_{\mathrm{T}}$ is the total energy absorbed by the plasma. Therefore, the following can be concluded:

(9) $$\begin{align}{P}_0=\frac{\alpha -1}{2\alpha -1}{P}_{\mathrm{T}},\end{align}$$

where ${P}_{\mathrm{T}}$ is the total pressure of the plasma and ${P}_{\mathrm{T}}={P}_{\mathrm{H}}+{P}_{\mathrm{i}}$ [ Reference Xia, Xue, Guo, Li and Fu 39 ], where ${P}_{\mathrm{H}}$ is the hydrodynamic pressure of the electronic system and ${P}_{\mathrm{H}}={n}_{\mathrm{e}} {k}_{\mathrm{B}} {T}_{\mathrm{e}}$ . For plasma with a high ionic density, the ionic pressure ${P}_{\mathrm{i}}$ cannot be ignored and ${P}_{\mathrm{i}}={n}_{\mathrm{i}} {k}_{\mathrm{B}} {T}_{\mathrm{i}}$ . Here, ${T}_{\mathrm{e}}$ and ${T}_{\mathrm{i}}$ are the electronic and ionic temperatures, respectively, ${n}_{\mathrm{i}}$ is the ionic density and ${k}_{\mathrm{B}}$ is the Boltzmann constant.

TTM[ Reference Rethfeld, Ivanov, Garcia and Anisimov 40 ] was employed to estimate the temperature evolution of the electron and lattice:

(10) $$\begin{align}{C}_{\mathrm{e}}\frac{\partial {T}_{\mathrm{e}}}{\partial t}=\nabla \cdot \left({K}_{\mathrm{e}}\nabla {T}_{\mathrm{e}}\right)-G\left({T}_{\mathrm{e}}-{T}_{\mathrm{i}}\right)+Q,\end{align}$$
(11) $$\begin{align}{C}_{\mathrm{i}}\frac{\partial {T}_{\mathrm{i}}}{\partial t}=\nabla \cdot \left({K}_{\mathrm{i}}\nabla {T}_{\mathrm{i}}\right)+G\left({T}_{\mathrm{e}}-{T}_{\mathrm{i}}\right),\end{align}$$

where $G$ is the electron–lattice coupling factor ( $G={C}_{\mathrm{e}}/{\tau}_{\mathrm{eq}}$ ) (see Ref. [Reference Gamaly37]), ${\tau}_{\mathrm{eq}}$ is the electron–phonon relaxation time, ${C}_{\mathrm{e}}$ is the electronic heat capacity ( ${C}_{\mathrm{e}}=0.5 {\pi}^2 {k_{\mathrm{B}}}^2 {T}_{\mathrm{e}}/{E}_{\mathrm{f}}$ ) (see Ref. [Reference Gamaly37]), ${E}_{\mathrm{f}}$ is the Fermi energy, ${K}_{\mathrm{e}}$ is the electronic thermal conductivity ( ${K}_{\mathrm{e}}={\pi}^2 {n}_{\mathrm{e}} {k_{\mathrm{B}}}^2 {T}_{\mathrm{e}} {\tau}_{\mathrm{k}}/\left(3 {m}_{\mathrm{e}}\right)$ ) (see Ref. [Reference Gamaly37]) and $Q$ is the laser source term. The free electrons absorb laser energy through the inverse bremsstrahlung process at a rate[ Reference Stuart, Feit, Herman, Rubenchik, Shore and Perry 41 ] of $\mathrm{d}J/ \mathrm{d}t={e}^2 {E}^2 {\tau}_{\mathrm{k}}/\left[{m}_{\mathrm{e}} \left(1+{\omega}^2 {\tau_{\mathrm{k}}}^2\right)\right]$ , where $J$ is the electronic energy. Table 2 lists the material parameters used in the calculations. Here, ${C}_{\mathrm{i}}$ and ${K}_{\mathrm{i}}$ are the heat capacity and thermal conductivity of the lattice, respectively.

Table 2 Material parameters used in the calculation[ Reference Li and Xia 31 ].

The evolution of eruptive pressure is shown in Figure 7(a). The laser fluence used in the calculation was 3.3 J/cm2, which is the experimental peak fluence used to obtain the damage morphology in Figure 3. The maximum eruptive pressure during laser irradiation exceeds 7 GPa. Therefore, the adjacent pillar will be fractured under a strong impact pressure. The calculated maximum eruptive pressure is much larger than the CEP calculated in Section 3.1, which may be because of the Gaussian distribution of the beam, resulting in the laser fluence used in the calculation being greater than the practical fluence-induced damage. Figure 7(b) shows that the maximum eruptive pressure in the grating is located at the backlight side ridge of the pillar, which is consistent with the peak EFI site, and damage occurs first in this region.

Figure 7 Calculation of the eruptive pressure in the MLDGs. The time step adopted was 10% that the pulse width. (a) Evolution of the eruptive pressure distribution on the right-hand side ridge and (b) distribution of the eruptive pressure in the grating when $t=21.5\;\mathrm{ps}.$ The red line in the inset image indicates the sampling boundary for eruptive pressure in (a).

In previous studies[ Reference Lin, Zhao, Liu, Li, Shuai, Ma, Shao, Sun, Qiu, Cui, Dai and Shao 29 ], the nano-absorbing defect located at the first SiO2/HfO2 interface was considered as the damage precursor in the ns-pulsed laser damage of the MLDGs. However, under the ps-pulsed laser, the damage initiation source of the MLDGs was changed due to the peak EFI located in the grating relief. Figure 3(a) shows a random distribution of the damage sites on the grating surface, which is different from the morphology of periodical damaged pillars due to the plasma induced by the periodic distribution of EFI observed by Hocquet et al.[ Reference Hocquet, Neauport and Bonod 15 ]. Therefore, besides maximal EFI, shallow defects related with pillars, which are mentioned as type-III damage precursors[ Reference Kozlov, Lambropoulos, Oliver, Hoffman and Demos 42 ], also contributed to the formation of the adjacent damaged pillars. The presence of maximal EFI and defects may trigger the initially damaged pillars. For the shorter fs-pulsed laser[ Reference Guan, Jin, Liu, Kong, Du, He, Yi and Shao 43 , Reference Poole, Trendafilov, Shvets, Smith and Chowdhury 44 ], the dominance of the EFI was further enhanced, and the influence of the shallow defects disappeared gradually. Particularly for pulses with several tens of fs, the damage was highly deterministic and the initial damage typically located on the back edges of the grating ridges was in correspondence with the maximum EFI.

5 Conclusion

The damage morphology of the MLDG induced by a laser pulse of 8.6 ps included the removal of a single grating pillar and consecutive adjacent grating pillars and did not involve the destruction of the HR structure. A comparative analysis of the two damage morphological characteristics indicated the removal of adjacent pillars was related to an impact process caused by the eruption of localized materials from the left-hand pillar. The collapse of the residual left-hand pillar toward the left-hand direction and the diffusion direction of the ‘foggy’ region further verified this dynamic eruptive process. The backlight side of the pillar ridge with peak EFI had a high ionization rate, which sharply increased the electronic density under laser irradiation. The pressure formed by the expansion of the dense plasma promoted the eruption of the materials in the pillar and caused fractures along the root of the adjacent pillar. However, the limited EFI in the HfO2 layers cannot induce internal damage to the grating, despite the narrower band gap of HfO2 compared with SiO2. This study reveals the interaction process of dynamic eruption-induced damage between grating pillars through an experimental investigation. For future work, improvements in the impact strength of grating pillars, such as more reliable aspect ratios, can be emphasized to limit the occurrence of large-area removal of multiple-grating pillars.

Acknowledgments

This research was supported by the National Key R&D Program of China (2018YFE0115900) and the Key Foreign Cooperation Projects of Bureau of International Cooperation of Chinese Academy of Sciences (181231KYSB20210001). The authors would like to express their gratitude to Yun Cui and Fanyu Kong from the Shanghai Institute of Optics and Fine Mechanics for their help with the SEM observation and grating preparation.

Footnotes

These authors contributed equally to this work.

References

Danson, C., Hillier, D., Hopps, N., and Neely, D., High Power Laser Sci. Eng. 3, e3 (2015).Google Scholar
Galletti, M., Oliveira, P., Galimberti, M., Ahmad, M., Archipovaite, G., Booth, N., Dilworth, E., Frackiewicz, A., Winstone, T., Musgrave, I., and Hernandez-Gomez, C., High Power Laser Sci. Eng. 8, e31 (2020).Google Scholar
Radier, C., Chalus, O., Charbonneau, M., Thambirajah, S., Deschamps, G., David, S., Barbe, J., Etter, E., Matras, G., Ricaud, S., Leroux, V., Richard, C., Lureau, F., Baleanu, A., Banici, R., Gradinariu, A., Caldararu, C., Capiteanu, C., Naziru, A., Diaconescu, B., Iancu, V., Dabu, R., Ursescu, D., Dancus, I., Ur, C. A., Tanaka, K. A., and Zamfir, N. V., High Power Laser Sci. Eng. 10, e21 (2022).CrossRefGoogle Scholar
Zhang, Z., Wu, F., Hu, J., Yang, X., Gui, J., Ji, P., Liu, X., Wang, C., Liu, Y., Lu, X., Xu, Y., Leng, Y., Li, R., and Xu, Z., High Power Laser Sci. Eng. 8, e4 (2020).Google Scholar
Hatchett, S. P., Brown, C. G., Cowan, T. E., Henry, E. A., Johnson, J. S., Key, M. H., Koch, J. A., Langdon, A. B., Lasinski, B. F., Lee, R. W., Mackinnon, A. J., Pennington, D. M., Perry, M. D., Phillips, T. W., Roth, M., Sangster, T. C., Singh, M. S., Snavely, R. A., Stoyer, M. A., Wilks, S. C., and Yasuike, K., Phys. Plasmas 7, 2076 (2000).CrossRefGoogle Scholar
Daido, H., Nishiuchi, M., and Pirozhkov, A. S., Rep. Prog. Phys. 75, 056401 (2012).Google Scholar
Izawa, Y., Miyanaga, N., Kawanaka, J., and Yamakawa, K., J. Opt. Soc. Korea 12, 178 (2008).CrossRefGoogle Scholar
Hornung, J., Zobus, Y., Boller, P., Brabetz, C., Eisenbarth, U., Kuhl, T., Major, Z., Ohland, J. B., Zepf, M., Zielbauer, B., and Bagnoud, V., High Power Laser Sci. Eng. 8, e24 (2020).Google Scholar
Strickland, D. and Mourou, G., Opt. Commun. 56, 219 (1985).Google Scholar
Bonod, N. and Neauport, J., Adv. Opt. Photonics 8, 156 (2016).CrossRefGoogle Scholar
Zhou, C., Chin. Opt. Lett. 18, 110502 (2020).Google Scholar
Svakhin, A. S., Sychugov, V. A., and Tikhomirov, A. E., Quantum Electron. 24, 233 (1994).CrossRefGoogle Scholar
Neauport, J., Lavastre, E., Raze, G., Dupuy, G., Bonod, N., Balas, M., de Villele, G., Flamand, J., Kaladgew, S., and Desserouer, F., Opt. Express 15, 12508 (2007).CrossRefGoogle Scholar
Xie, L., Zhang, J., Zhang, Z., Ma, B., Li, T., Wang, Z., and Cheng, X., Opt. Express 29, 2669 (2021).CrossRefGoogle Scholar
Hocquet, S., Neauport, J., and Bonod, N., Appl. Phys. Lett. 99, 061101 (2011).CrossRefGoogle Scholar
Hoffman, B. N., Kozlov, A. A., Liu, N., Huang, H., Oliver, J. B., Rigatti, A. L., Kessler, T. J., Shestopalov, A. A., and Demos, S. G., Opt. Express 28, 24928 (2020).CrossRefGoogle Scholar
Alessi, D. A., Carr, C. W., Hackel, R. P., Negres, R. A., Stanion, K., Fair, J. E., Cross, D. A., Nissen, J., Luthi, R., Guss, G., Britten, J. A., Gourdin, W. H., and Haefner, C., Opt. Express 23, 15532 (2015).Google Scholar
Kong, F., Jin, Y., Guan, H., Liu, S., Wu, J., Du, Y., and He, H., Appl. Opt. 53, 4859 (2014).Google Scholar
Demos, S. G., Negres, R. A., Raman, R. N., Feit, M. D., Manes, K. R., and Rubenchik, A. M., Optica 2, 765 (2015).Google Scholar
Berthe, L., Fabbro, R., Peyre, P., Tollier, L., and Bartnicki, E., J. Appl. Phys. 82, 2826 (1997).Google Scholar
Gracewski, S. M., Boylan, S., Lambropoulos, J. C., Oliver, J. B., Kessler, T. J., and Demos, S. G., Opt. Express 26, 18412 (2018).CrossRefGoogle Scholar
Lin, X., Zhao, Y., Liu, X., Li, D., Ma, H., Shao, Y., Qiu, K., Sun, J., Kong, F., and Zhu, M., Proc. SPIE 11912, 119120O (2021).Google Scholar
Qiu, K., Xu, X., Liu, Y., Hong, Y., and Fu, S., Proc. SPIE 6832, 68322L (2008).Google Scholar
Guzhov, V. Y., J. Opt. Technol. 69, 685 (2002).Google Scholar
Hao, Y., Sun, M., Shi, S., Pan, X., Zhu, Z., Pang, X., and Zhu, J., Proc. SPIE 10339, 103390H (2017).Google Scholar
Peng, Y., Pan, X., Wang, J., Fan, W., and Li, X., Chin. J. Lasers 41, 0802009 (2014).CrossRefGoogle Scholar
Becker, J. and Bernhardt, A., Proc. SPIE 2114, 703 (1994).Google Scholar
Nibbering, E. T. J., Grillon, G., Franco, M. A., Prade, B. S., and Mysyrowicz, A., J. Opt. Soc. Am. B 14, 650 (1997).Google Scholar
Lin, X., Zhao, Y., Liu, X., Li, D., Shuai, K., Ma, H., Shao, Y., Sun, J., Qiu, K., Cui, Y., Dai, Y., and Shao, J., Opt. Mater. Express 12, 643 (2022).Google Scholar
Huang, H., Kong, F., Xia, Z., Jin, Y., Li, L., Wang, L., Chen, J., Zhang, H., Cui, Y., and Shao, J., Opt. Mater. 72, 130 (2017).Google Scholar
Li, Z. and Xia, Z., Appl. Surf. Sci. 494, 977 (2019).Google Scholar
Brambilla, G. and Payne, D. N., Nano Lett. 9, 831 (2009).CrossRefGoogle Scholar
Zheng, K., Wang, C., Cheng, Y.-Q., Yue, Y., Han, X., Zhang, Z., Shan, Z., Mao, S. X., Ye, M., Yin, Y., and Ma, E., Nat. Commun. 1, 24 (2010).CrossRefGoogle Scholar
Bloembergen, N., IEEE J. Quantum Electron. 10, 375 (1974).CrossRefGoogle Scholar
Keldysh, L. V., Sov. Phys. JETP 20, 1307 (1965).Google Scholar
Gamaly, E. G., Phys. Rep. 508, 91 (2011).Google Scholar
Zhou, J., Zhang, Y., Zhou, M., Yin, S., Yang, J., Wu, H., and Guo, D., Chin. J. Lasers 32, 135 (2005).Google Scholar
Xia, Z., Xue, Y., Guo, P., Li, Z., and Fu, Z., Opt. Commun. 282, 3583 (2009).Google Scholar
Rethfeld, B., Ivanov, D. S., Garcia, M. E., and Anisimov, S. I., J. Phys. D 50, 193001 (2017).CrossRefGoogle Scholar
Stuart, B. C., Feit, M. D., Herman, S., Rubenchik, A. M., Shore, B. W., and Perry, M. D., Phys. Rev. B 53, 1749 (1996).Google Scholar
Kozlov, A. A., Lambropoulos, J. C., Oliver, J. B., Hoffman, B. N., and Demos, S. G., Sci. Rep. 9, 607 (2019).CrossRefGoogle Scholar
Guan, H., Jin, Y., Liu, S., Kong, F., Du, Y., He, K., Yi, K., and Shao, J., Laser Phys. 23, 115301 (2013).CrossRefGoogle Scholar
Poole, P., Trendafilov, S., Shvets, G., Smith, D., and Chowdhury, E., Opt. Express 21, 26341 (2013).Google Scholar
Figure 0

Figure 1 (a) Schematic representation of the MLDG and (b) the –1st-order diffraction efficiency of the MLDG; the inset shows an SEM image of the pristine cross-sectional morphology of the MLDG. The measured grating period T = 580 nm, mid-waist duty cycle ƒ = 0.38, groove depth D = 415 nm and base angle of the grating pillar θ = 87°.

Figure 1

Figure 2 Damage probability fitting curve of MLDGs under one-on-one test mode. The LIDT of the MLDGs was 2.2 J/cm2 irradiated by an 8.6 ps-pulsed laser with the wavelength of 1053 nm.

Figure 2

Figure 3 SEM images of typical damage morphology characteristics of the MLDGs. (a) Top-view image of the damage area irradiation by the ps-pulsed laser, and (b)–(d) are the local magnified views of the three black rectangular areas in (a). The test laser irradiated the surface from left to right with a fluence of 3.3 J/cm2.

Figure 3

Table 1 Morphological characteristics of the adjacent damaged pillars.

Figure 4

Figure 4 Two-dimensional finite-element strain simulation model and calculation results. (a) Schematic representation of the eruptive impact process; the localized eruption of the left-hand pillar induced a rightward impact pressure on the right-hand pillar. (b), (c) Normal stress distributions along the y- and x-axis directions, ${\sigma}_{{yy}}$ and ${\sigma}_{{xx}}$, of the right-hand pillar in (a), respectively. Positive values are tensile stresses and negative values are compressive stresses.

Figure 5

Figure 5 (a) Schematic representation of the electric field simulation model and (b) laser electric field distribution in MLDGs. The incident laser pulse is centered at 1053 nm, and its pulse width is 8.6 ps.

Figure 6

Figure 6 Evolution of the electronic density ${n}_{\mathrm{e}}$ in the conduction band. The rectangular, circular and triangular shapes represent the sampling point curves on the upper inset image. The calculation time is three times that of the laser pulse width.

Figure 7

Table 2 Material parameters used in the calculation[31].

Figure 8

Figure 7 Calculation of the eruptive pressure in the MLDGs. The time step adopted was 10% that the pulse width. (a) Evolution of the eruptive pressure distribution on the right-hand side ridge and (b) distribution of the eruptive pressure in the grating when $t=21.5\;\mathrm{ps}.$ The red line in the inset image indicates the sampling boundary for eruptive pressure in (a).