The use of continuous wave (CW) lasers with a wavelength of nm has recently increased for a directed energy weapon because these lasers have less attenuation in the atmosphere than ultraviolet or visible wavelength lasers.1,2 Generally, the target is damaged by the thermal effect of the laser energy absorbed into the target material.
Previous investigations of laser-induced thermal damages by laser weapons have focused primarily on missile, rocket, aircraft, and unmanned aerial vehicles.126.96.36.199.–8 In this case, the high power of a laser beam or long exposure time is necessary to induce thermal damage on the target surface in order to increase the temperature to the melting or vaporization point. In general, a hard-kill laser weapon requires 100 kW. However, if an electro-optic/infrared system is exposed to laser beam irradiation, the system can easily break down due to cracking or melting damage of the optics and sensor components at a lower power than in the case of a metallic structure.910.–11 That is, optical systems are specifically weaker to laser attack.
Silicon is normally used as a substrate material in optical elements and photodetectors. Optically, silicon has a low absorption coefficient less than at 1.2 to 7 and 25 to 300 μm light wavelengths; therefore, a very small portion of the laser energy is absorbed, and most laser energy is transmitted at these wavelength ranges. However, much more laser energy can be absorbed at other wavelengths. For example, at a 1070-nm wavelength, the absorption coefficient is and the absorbance is 0.278 at a thickness of 525 μm.12 Moreover, the absorption coefficient rapidly increases with an increase in temperature. Therefore, silicon is very vulnerable to a near-infrared (NIR) laser with a wavelength of approximately 1070 nm.
Even though prestigious achievements in laser-induced thermal damages in silicon crystals have been reported in the field of laser processing technology, most studies focused on the ablation effect induced by ultraviolet (UV) and visible (VIS) wavelength lasers,1314.15.–16 and a few researchers have explained cracking and melting damage induced by an NIR laser.17,18
In this paper, the thermal damages in silicon wafers, such as cracking and melting, induced by an NIR CW laser beam with a 1070-nm wavelength were investigated under various irradiances. Czochralski-grown, single crystal silicon p-type (100) plane specimens were illuminated by a 1070-nm fiber laser, and the surface morphology of specimens after irradiation was observed using an optical microscope (OM) to analyze the cracking and melting damage. In order to identify the damage mechanism, numerical simulations were performed to predict the irradiances that initiate the cracking and melting, and the predicted irradiances were compared with experimental findings. In the simulation, the thermal stress and temperature variations induced by the NIR CW laser were calculated based on the heat transfer and thermoelasticity model.1920.–21 The cracking damage was predicted by comparing the calculated thermal stress with the fracture strength of silicon, and the melting damage was predicted by comparing the calculated temperature with the melting point of silicon.
A schematic diagram of the experimental system is shown in Fig. 1. Czochralski-grown, single crystal silicon p-type (100) plane specimens with a thickness of were illuminated by a CW fiber laser (IPG photonics, 1070-nm wavelength, 1-kW maximum laser beam power, and 5.85-mm laser beam diameter). A quartz beam splitter, reflecting 10% of the laser beam energy to a power meter, was used to monitor the laser beam power. A laser beam with an 11.7-mm diameter irradiated the specimens for 20 s. Although the practical attack time will be a few seconds in the military application, in order to consider the effect of thermal convection and radiation that suppress the temperature rise, we have tested enough long time exposure until the temperature and stress are mostly saturated. The laser power increased from 100 to 200 W in 10 W steps, which correspond to irradiances ranging from 93 to in steps. The tests were performed six times at each laser power. The surface morphology of the silicon specimens subjected to the laser beam was analyzed using an optical microscope.
Figure 2 shows the OM images of the silicon wafer surface before and after laser irradiation at a irradiance, where Fig. 2(a) is the clean surface before laser irradiation and Fig. 2(b) is the cracked surface after. Surface cracks appeared in the and directions [Fig. 2(b)] because these directions are the weakest in the single-crystal silicon (100) plane.22 Surface cracks were observed at irradiance or greater, while no cracks were observed at an irradiance of or less.
Figure 3(a) shows the schematic diagram of the silicon wafer surface when the irradiance of the laser beam was . A partially melted zone appeared. Figure 3(b) shows the OM image of the silicon wafer surface near the center of the laser beam spot. The surface morphology is significantly varied due to partial surface melting. This surface morphology was formed by cracks generated prior to melting. Multiple reflections and absorptions of the laser beam at the crack increased the absorption, causing melting to occur first along the crack.23 Figure 3(c) shows the OM image of the “A” zone in Fig. 3(a), which is the boundary of the melted area. A partially melted zone and surface cracks were observed. The boundary of the partially melted zone showed an orthogonal shape because melting easily occurred in the crack. The irradiances-inducing partial melting was 130 and .
Figure 4(a) shows the schematic diagram of the silicon wafer surface when the irradiance of the laser beam was . A completely melted zone was observed at the center of the laser beam spot, and a partially melted zone and cracks were observed at the outside. Figure 4(b) shows the OM image of the “B” zone in Fig. 4(a), which is the boundary of complete and partial melting. As the irradiance of the laser beam increased, the center of the partially melted zone shown in Fig. 3(b) dissolved entirely and became flat. A completely melted zone was observed at an irradiance of or greater. A summary of these experimental results is shown in Table 1.
Summary of the experimental results.
|Typical OM image|
|Damage||No damage||Cracking||Partial melting||Partial melting||Complete melting|
Discussion of the Damage Mechanism using Numerical Analysis
In order to identify the damage mechanism, numerical analysis was performed based on the heat transfer and thermoelasticity model. First, the thermal stress was calculated at various laser irradiances, and the cracking irradiance was predicted by determining the irradiance at which the calculated von mises stress exceeded the fracture strength. The temperature was then calculated at various laser irradiances, and the melting irradiance was predicted by determining the irradiance at which the calculated temperature exceeded the melting point. These predictions were compared with the experimental results.
The thermal stress variation in specimens subjected to laser irradiation was obtained from the solution of the Duhamel-Neumann law for linear elasticity, which considers the effect of thermal expansion as follows:19
In Eq. (1), the transient temperature distribution can be obtained using a classical heat conduction analysis. The three-dimensional (3-D) differential equation of the heat conduction is given as follows:20
The heat source per unit volume can be represented as the incident laser intensity. Assuming that the spatial distribution of the laser beam is Gaussian, the heat source per unit volume can be expressed as follows:21
The thermal stress and temperature variations of a silicon wafer induced by CW laser irradiation were simulated with a 3-D one fourth symmetric model using COMSOL Multiphysics. Figure 5 shows the simulation model of the silicon specimen irradiated by a CW laser beam. The radius of the specimen was 50.8 mm, and the symbol “D” denotes the volume of the heat source. A boundary condition of “E” is symmetric. The other boundary is traction-free, where convection and radiation into the ambient were given as follows:
The NIR CW laser with a 1070-nm wavelength used in this model has a Gaussian beam shape. The radius of the laser beam was 5.85 mm. The temperature-dependent physical and optical properties of the silicon, including density, thermal conductivity, heat capacity, thermal expansion coefficient, Young’s modulus, Poisson’s ratio, absorption coefficient and reflectivity, are given in Table 2.12,17,24 A time-dependent solver was used, and the solid–liquid phase change in the silicon was considered in terms of the specific heat capacity.20 The calculation duration time was 20 s in 0.01 s intervals, and the initial temperature of the silicon wafer was 20°C.
Physical and optical properties of a silicon wafer depending on temperature.
|Thermal conductivity [W/(m°C)]||159.3||81.5||49.6||34.8||27.5||24.6||23.4|
|Heat capacity (J/(kg°C))||708.8||795.8||865.1||903.6||956.6||996.7||1018.8|
|Thermal expansion coefficient (10−6/°C)||2.57||3.60||4.06||4.22||4.33||4.45||4.57|
|Young’s modulus (GPa)||130.7||124.9||119.0||113.1||107.6||95.4||89.8|
|Absorption coefficient (1/cm)||10||87||370||1088||2570||5249||9673|
Simulation results for the profiles of typical stresses , , , and (von mises stress) on the surface of silicon specimen subjected to a laser irradiance of for 20 s are shown in Fig. 6. The tensile stress is positive and the compressive stress is negative. For the stresses and , the maximum compressive stress is located at the center of the laser beam spot with the approximate value of 215 MPa. On the other hand, the maximum stress of is only 1.5 MPa which is very small compared with the other stresses. This means that the effect of stress is negligible. For the von mises stress , the maximum stress is located at the center of the laser beam spot with the approximate value of 214 MPa.
The variation of the von mises stress () at the center of the laser beam for irradiances of 112, 121, 130, and is shown in Fig. 7. To predict the cracking occurrence, the stress variation was compared with the fracture strength. In general, the fracture strength of silicon depends on the specimen size and thickness. Moreover, the fracture strength has large deviations due to the brittle fracture behavior. Paul et al.25 statistically studied the fracture strength of silicon with varying thicknesses using Weibull and normal models. The fracture strength of silicon with a thickness of 525 μm ranged from 96 to 386 MPa with a nearly normal distribution (average fracture strength of 222 MPa and a standard deviation of 70 MPa). As a result, the fracture strength range of was adopted, which has a high probability density. This range is shown as a band in Fig. 7. Assuming that the cracking occurred when the von mises stress reached the range of the fracture strength, the cracking is predicted to be initiated when the laser irradiance is greater than for 20 s. These results agree well with experimental findings.
In this study, we have tested enough long time exposure until the stress and temperature were mostly saturated by the effect of thermal convection and radiation. In practice, in military applications, however, a shorter time exposure with higher laser irradiance may be interesting. Even in such a case, our simulation scheme is still available, since the damage mechanism is not changed when the irradiation time is only longer than a millisecond.
The temperature variation at the center of the laser beam for irradiances of 112, 121, 130, and is shown in Fig. 8. The temperature increased sharply at the beginning of the laser beam irradiation and then slowly increased due to the effects of convection and radiation. The maximum temperature was , 1015, 1090, and 1155°C after 20 s, respectively, and all of these temperatures were below the melting point of silicon (1412°C). Therefore, melting is not expected to occur in these cases.
To predict the melting occurrence, a simulation was performed with the stronger laser beam irradiance of . The simulation result for the temperature distribution on the silicon specimen subjected to a laser beam irradiation for 20 s is shown in Fig. 9. The temperature at the center of the laser beam increased to 1442°C, which was greater than the melting point of silicon. Therefore, melting is expected to occur when a laser beam with irradiance of or greater irradiates the silicon wafer for 20 s.
However, partial melting was observed at the lower irradiances, which is reasonable when considering the increase in absorbance of laser energy by multiple reflections and absorptions in the cracks.23 In the simulation model, the absorption of the laser beam was supposed to occur only once. But if surface cracks appeared during the laser beam irradiation, the absorbance of the laser energy is increased by multiple reflections and absorptions. Therefore, in the experiments, surface melting occurred at the lower irradiances than the numerically predicted irradiance.
Laser-induced thermal damages, such as cracking and melting, on the silicon wafer surface subjected to the irradiation of a 1070-nm wavelength NIR CW laser were investigated by experiments and numerical simulations. Czochralski-grown, single crystal silicon p-type (100) plane specimens were illuminated by a CW fiber laser at various irradiances for 20 s, and the surface morphology of specimens after irradiation was analyzed using an OM. With the increase in irradiance, surface cracks appeared first and then subsequent partial and complete melting occurred. Surface cracks occurred in the <110> direction because this direction is the weakest in the (100) plane. Melting occurred first along the crack because the absorption of laser energy increased at the crack due to multiple reflections and absorptions. This formed a partially melted zone. As the irradiance is further increased, the surface was entirely melted. The irradiances responsible for initiating a crack, partial melting and complete melting were 121, 130 and , respectively.
These values were compared with the numerical predictions to verify that experimentally observed damages, such as cracking and melting, were induced by thermal stress and increased temperature. A numerical calculation model was based on the heat transfer and thermoelasticity. The cracking irradiance was predicted by determining the irradiance that the calculated von mises stress reached the fracture strength range, , and the melting irradiance was predicted by finding the temperature at which the calculated temperature exceeds the melting point, 1442°C. The predicted cracking irradiance was identical to the experimental result. However, numerical prediction for initiating surface melting was , which is greater than the experimental observation. Nevertheless, this is reasonable when considering the absorbance of the laser energy increased due to the multiple reflection and absorptions at the cracks induced prior to the melting so that the melting occurred at a lower irradiance than the numerically predicted value.
Based on these investigations, laser-induced thermal damages of a silicon wafer surface subjected to CW NIR laser irradiation were identified.
This work was supported by the research fund of the Survivability Technology Defense Research Center of Agency for Defense Development of Korea (No. UD120019OD).
Sungho Choi received his BS in mechanical engineering from Hanyang University, Seoul, Korea in 2010. He is currently working on his MS/PhD at Hanyang University, Seoul, Korea studying laser-material interactions and ultrasonic nondestructive evaluation methods.
Kyung-Young Jhang received BS and MS degrees in precision mechanical engineering from Hanyang University, Seoul, Korea, in 1983 and 1985, respectively. In 1991, he received a PhD in precision mechanical systems from the Tokyo Institute of Technology, Yokohama, Japan. He has been a professor at Hanyang University, Seoul, Korea since 1992. His research interests are experimental mechanics, ultrasonic nondestructive evaluation, optical measuring system, visual image processing, random signal processing, and laser-material interaction.