Effects of nonlinear absorption on laser Gaussian beam profile
The evolution of the transmitted ultrashort laser beam profile through sapphire samples was examined from linear absorption to nonlinear absorption using a thermal paper. The sapphire samples were either double-sided polished or single-sided polished (with one side rough). For linear absorptio...
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| Format: | Final Year Project |
| Language: | English |
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Nanyang Technological University
2022
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| Online Access: | https://hdl.handle.net/10356/157877 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | The evolution of the transmitted ultrashort laser beam profile through sapphire samples was
examined from linear absorption to nonlinear absorption using a thermal paper. The sapphire
samples were either double-sided polished or single-sided polished (with one side rough). For
linear absorption, a bright exposure associated with a Gaussian beam distribution was observed.
As the incoming laser beam intensity exceeded that for nonlinear absorption, no or significant
reduction in thermal paper changes was observed. This is because the laser beam absorption
by the sapphire sample had significantly increased, resulting in a significant reduction of the
transmitted power to the thermal paper. With further increase in the incoming laser beam
intensity, inconsistent thermal changes were observed, indicating the inconsistency of
nonlinear absorption by the sapphire sample. The absorption inconsistency may be attributed
to the laser damage on the sapphire sample due to nonlinear absorption.
To reveal the details of the transmitted beam profile, parameters such as defocus distance, laser
on time and laser power, were optimized. With these optimum parameters, an annulus
transmitted beam profile in the nonlinear absorption regime was captured on the thermal paper.
This annulus profile indicated that there was little transmitted laser beam energy at the center
of the beam after nonlinear absorption. This observed annulus profile was rather distinctly
different from that for the linear absorption beam profile.
This annulus beam profile could be explained by hypothesizing that with sufficiently high
incoming laser beam intensity, the central focal area of the Gaussian laser beam would have
exceeded that required for nonlinear absorption; this would cause significant nonlinear
absorption with a significant reduction in the transmitted laser power. As such, no/little thermal
changes in the center of the exposure pattern could be observed. In contrast, the outer annulus
ring of the Gaussian beam carrying low laser intensity was below the nonlinear absorption threshold. Only linear, and thus much lower absorption occurred; as such, higher percentage of
laser power was transmitted at this outer annulus region. This would result in an annulus ring
of thermal transformation recorded by the thermal paper. However, experimental observations
indicated that although the intensity at the center of the Gaussian beam had exceeded the
nonlinear absorption for its transmission to be suppressed, it still had resulted in a bright
exposure in the center of the annulus. This resulted in the revised hypothesis that nonlinear
absorption could suppressed the transmission of laser intensity, but it might not totally
eliminate its transmission.
The rough exit surface of a single-sided polished sapphire sample had been previously
hypothesized to cause nonlinear absorption due to total internal reflection. The differences in
the transmitted laser beam profiles between double-sided polished and single-sided polished
sapphire samples were examined. These comparisons further verified the existence of total
internal reflection of a single-sided polished sapphire sample with a rough exit surface. |
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