A method to evaluate explosive crystallization velocity of amorphous silicon films during flash lamp annealing

Abstract: Flash lamp annealing (FLA) of micrometre-order thick amorphous silicon (a-Si) films can induce explosive crystallization (EC), high-speed lateral crystallization driven by the release of latent heat. We develop multipulse FLA system, which emits a quasi-millisecond pulse consisting of a number of subpulses. The emission frequency of the subpulses can be systematically controlled, and the emission of subpulses leads to the periodic modulation of the temperature of a Si film and the resulting formation of macros… Show more

“…The formation of the macroscopic stripe patterns is related to the modulation of the temperature of Si films during millisecond treatment due to discrete sub-pulses. 18,19) These clear examples of experimental evidence indicate that the crystallization of Cat-CVD a-Si:H films by FLA on SiN x -coated textured glass substrates takes place by EC, lateral crystallization induced by the release of latent heat due to the enthalpy difference between a-Si and c-Si and its diffusion. 28) Figure 4 shows the widths of stripes formed on i-and npoly-Si films as a function of the inverse of the frequency of sub-pulse emission.…”

“…The sub-pulse emission leads to the periodic change of Si temperature during FLA and the resulting formation of macroscopic stripe patterns on a poly-Si surface if EC takes place. 18,19) The velocity of EC (v EC ) was estimated from the width of the macroscopic stripe patterns and inverse of sub-pulse frequency. 18,19) The crystallization and crystalline fraction of Si films were characterized by Raman spectroscopy.…”

“…18,19) The velocity of EC (v EC ) was estimated from the width of the macroscopic stripe patterns and inverse of sub-pulse frequency. 18,19) The crystallization and crystalline fraction of Si films were characterized by Raman spectroscopy. The cross-sectional microscopic image of a poly-Si was observed by transmission electron microscopy (TEM).…”

“…14) We have attempted to use precursor a-Si films formed by various types of deposition methods, such as catalytic chemical vapor deposition (Cat-CVD), sputtering, and electron-beam (EB) evaporation. [15][16][17][18][19][20][21][22][23][24] The crystallization of EBevaporated a-Si films on flat glass substrates is driven by liquid-phase explosive crystallization (EC), which leads to the formation of crystal grains with a size of several tens of μm. 17) A different type of EC occurs for the crystallization of Cat-CVD a-Si:H films, through which two types of regions with different microstructures appear alternately in the direction of crystallization with a period of ∼1 μm.…”

Crystallization of catalytic CVD hydrogenated n-a-Si films on textured glass substrates by flash lamp annealing

“…The formation of the macroscopic stripe patterns is related to the modulation of the temperature of Si films during millisecond treatment due to discrete sub-pulses. 18,19) These clear examples of experimental evidence indicate that the crystallization of Cat-CVD a-Si:H films by FLA on SiN x -coated textured glass substrates takes place by EC, lateral crystallization induced by the release of latent heat due to the enthalpy difference between a-Si and c-Si and its diffusion. 28) Figure 4 shows the widths of stripes formed on i-and npoly-Si films as a function of the inverse of the frequency of sub-pulse emission.…”

“…The sub-pulse emission leads to the periodic change of Si temperature during FLA and the resulting formation of macroscopic stripe patterns on a poly-Si surface if EC takes place. 18,19) The velocity of EC (v EC ) was estimated from the width of the macroscopic stripe patterns and inverse of sub-pulse frequency. 18,19) The crystallization and crystalline fraction of Si films were characterized by Raman spectroscopy.…”

“…18,19) The velocity of EC (v EC ) was estimated from the width of the macroscopic stripe patterns and inverse of sub-pulse frequency. 18,19) The crystallization and crystalline fraction of Si films were characterized by Raman spectroscopy. The cross-sectional microscopic image of a poly-Si was observed by transmission electron microscopy (TEM).…”

“…14) We have attempted to use precursor a-Si films formed by various types of deposition methods, such as catalytic chemical vapor deposition (Cat-CVD), sputtering, and electron-beam (EB) evaporation. [15][16][17][18][19][20][21][22][23][24] The crystallization of EBevaporated a-Si films on flat glass substrates is driven by liquid-phase explosive crystallization (EC), which leads to the formation of crystal grains with a size of several tens of μm. 17) A different type of EC occurs for the crystallization of Cat-CVD a-Si:H films, through which two types of regions with different microstructures appear alternately in the direction of crystallization with a period of ∼1 μm.…”

Crystallization of catalytic CVD hydrogenated n-a-Si films on textured glass substrates by flash lamp annealing

“…The equipment used for surface modification was UV irradiation equipment fitted with low pressure Hg lamp source. The low pressure Hg lamp has wavelengths of 184.9 nm (11.5 mW/cm ) and frequency of 3 Hz by the devising of a particular circuit design of the system [5,9]. ) [2,3].…”

Flash Lamp Annealing Method for Improving Adhesion Strength on the Dielectric Material and Reducing Substrate Warpage

Semiconductor Applications