Your search keyword '"Hossain, Azmain A."' showing total 12 results

1. Atomic layer etching of SiO$_2$ using sequential exposures of Al(CH$_3$)$_3$ and H$_2$/SF$_6$ plasma

Author

Catherall, David, Hossain, Azmain, and Minnich, Austin

Subjects

Physics - Applied Physics, Condensed Matter - Materials Science

Abstract

On-chip photonic devices based on SiO$_2$ are of interest for applications such as microresonator gyroscopes and microwave sources. Although SiO$_2$ microdisk resonators have achieved quality factors exceeding one billion, this value remains an order of magnitude less than the intrinsic limit due to surface roughness scattering. Atomic layer etching (ALE) has potential to mitigate this scattering because of its ability to smooth surfaces to sub-nanometer length scales. While isotropic ALE processes for SiO$_2$ have been reported, they are not generally compatible with commercial reactors, and the effect on surface roughness has not been studied. Here, we report an ALE process for SiO$_2$ using sequential exposures of Al(CH$_3$)$_3$ (trimethylaluminum, TMA) and Ar/H$_2$/SF$_6$ plasma. We find that each process step is self-limiting, and that the overall process exhibits a synergy of 100%. We observe etch rates up to 0.58 \r{A} per cycle for thermally-grown SiO$_2$ and higher rates for ALD, PECVD, and sputtered SiO$_2$ up to 2.38 \r{A} per cycle. Furthermore, we observe a decrease in surface roughness by 62% on a roughened film. The residual concentration of Al and F is around 1-2%, which can be further decreased by O$_2$ plasma treatment. This process could find applications in smoothing of SiO$_2$ optical devices and thereby enabling device quality factors to approach limits set by intrinsic dissipation., Comment: 19 pages, 8 figures, 1 table

Published

2024

2. Isotropic atomic layer etching of MgO-doped lithium niobate using sequential exposures of H$_2$ and SF$_6$ plasmas

Author

Chen, Ivy I., Solgaard, Jennifer, Sekine, Ryoto, Hossain, Azmain A., Ardizzi, Anthony, Catherall, David S., Marandi, Alireza, Renzas, James R., Greer, Frank, and Minnich, Austin J.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Physics - Optics

Abstract

Lithium niobate (LiNbO$_3$, LN) is a ferroelectric crystal of interest for integrated photonics owing to its large second-order optical nonlinearity and the ability to impart periodic poling via an external electric field. However, on-chip device performance based on thin-film lithium niobate (TFLN) is presently limited by propagation losses arising from surface roughness and corrugations. Atomic layer etching (ALE) could potentially smooth these features and thereby increase photonic performance, but no ALE process has been reported for LN. Here, we report an isotropic ALE process for $x$-cut MgO-doped LN using sequential exposures of H$_2$ and SF$_6$/Ar plasmas. We observe an etch rate of $1.59 \pm 0.02$ nm/cycle with a synergy of $96.9$%. We also demonstrate ALE can be achieved with SF$_6$/O$_2$ or Cl$_2$/BCl$_3$ plasma exposures in place of the SF$_6$/Ar plasma step with synergies of $99.5$% and $91.5$% respectively. The process is found to decrease the sidewall surface roughness of TFLN waveguides etched by physical Ar$^+$ milling by 30% without additional wet processing. Our ALE process could be used to smooth sidewall surfaces of TFLN waveguides as a post-processing treatment, thereby increasing the performance of TFLN nanophotonic devices and enabling new integrated photonic device capabilities.

Published

2023

3. Isotropic plasma-thermal atomic layer etching of superconducting TiN films using sequential exposures of molecular oxygen and SF$_6/$H$_2$ plasma

Author

Hossain, Azmain A., Wang, Haozhe, Catherall, David S., Leung, Martin, Knoops, Harm C. M., Renzas, James R., and Minnich, Austin J.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Condensed Matter - Superconductivity

Abstract

Microwave loss in superconducting titanium nitride (TiN) films is attributed to two-level systems in various interfaces arising in part from oxidation and microfabrication-induced damage. Atomic layer etching (ALE) is an emerging subtractive fabrication method which is capable of etching with Angstrom-scale etch depth control and potentially less damage. However, while ALE processes for TiN have been reported, they either employ HF vapor, incurring practical complications; or the etch rate lacks the desired control. Further, the superconducting characteristics of the etched films have not been characterized. Here, we report an isotropic plasma-thermal TiN ALE process consisting of sequential exposures to molecular oxygen and an SF$_6$/H$_2$ plasma. For certain ratios of SF$_6$:H$_2$ flow rates, we observe selective etching of TiO$_2$ over TiN, enabling self-limiting etching within a cycle. Etch rates were measured to vary from 1.1 \r{A}/cycle at 150 $^\circ$C to 3.2 \r{A}/cycle at 350 $^\circ$C using ex-situ ellipsometry. We demonstrate that the superconducting critical temperature of the etched film does not decrease beyond that expected from the decrease in film thickness, highlighting the low-damage nature of the process. These findings have relevance for applications of TiN in microwave kinetic inductance detectors and superconducting qubits., Comment: 17 pages, 7 figures

Published

2023

4. Isotropic plasma-thermal atomic layer etching of aluminum nitride using SF$_6$ plasma and Al(CH$_3$)$_3$

Author

Wang, Haozhe, Hossain, Azmain, Catherall, David, and Minnich, Austin J.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We report the isotropic plasma atomic layer etching (ALE) of aluminum nitride using sequential exposures of SF$_6$ plasma and trimethylaluminum (Al(CH$_3$)$_3$, TMA). ALE was observed at temperatures greater than 200 $^\circ$C, with a maximum etch rate of 1.9 \r{A}/cycle observed at 300 $^\circ$C as measured using ex-situ ellipsometry. After ALE, the etched surface was found to contain a lower concentration of oxygen compared to the original surface and exhibited a $\sim 35$% decrease in surface roughness. These findings have relevance for applications of AlN in nonlinear photonics and wide bandgap semiconductor devices.

Published

2022

5. Atomic layer etching of SiO2 using sequential exposures of Al(CH3)3 and H2/SF6 plasma.

Author

Catherall, David S., Hossain, Azmain A., Ardizzi, Anthony J., and Minnich, Austin J.

Subjects

CHEMICAL vapor deposition, SURFACE roughness, QUALITY factor, SURFACE scattering, OPTICAL devices, GYROSCOPES

Abstract

On-chip photonic devices based on SiO 2 are of interest for applications such as microresonator gyroscopes and microwave sources. Although SiO 2 microdisk resonators have achieved quality factors exceeding one billion, this value remains an order of magnitude less than the intrinsic limit due to surface roughness scattering. Atomic layer etching (ALE) has potential to mitigate this scattering because of its ability to smooth surfaces to sub-nanometer length scales. While isotropic ALE processes for SiO 2 have been reported, they are not generally compatible with commercial reactors, and the effect on surface roughness has not been studied. Here, we report an ALE process for SiO 2 using sequential exposures of Al(CH3)3 (trimethylaluminum) and Ar/H2/SF6 plasma. We find that each process step is self-limiting, and that the overall process exhibits perfect synergy, with neither isolated half-cycle resulting in etching. We observe etch rates up to 0.58 Å per cycle for thermally grown SiO 2 and higher rates for ALD, plasma enhanced chemical vapor deposition, and sputtered SiO 2 up to 2.38 Å per cycle. Furthermore, we observe a decrease in surface roughness by 62% on a roughened film. The residual concentration of Al and F is around 1%–2%, which can be further decreased by O2 plasma treatment. This process could find applications in smoothing of SiO 2 optical devices and thereby enabling device quality factors to approach limits set by intrinsic dissipation. [ABSTRACT FROM AUTHOR]

Published

2024

6. Isotropic plasma-thermal atomic layer etching of superconducting titanium nitride films using sequential exposures of molecular oxygen and SF6/H2 plasma

Author

Hossain, Azmain A., primary, Wang, Haozhe, additional, Catherall, David S., additional, Leung, Martin, additional, Knoops, Harm C. M., additional, Renzas, James R., additional, and Minnich, Austin J., additional

Published

2023

7. Isotropic plasma-thermal atomic layer etching of superconducting titanium nitride films using sequential exposures of molecular oxygen and SF6/H2 plasma.

Author

Hossain, Azmain A., Wang, Haozhe, Catherall, David S., Leung, Martin, Knoops, Harm C. M., Renzas, James R., and Minnich, Austin J.

Subjects

TITANIUM nitride films, SUPERCONDUCTING transition temperature, OXYGEN plasmas, SUPERCONDUCTING films, ETCHING, COPPER oxide films, TITANIUM hydride

Abstract

Microwave loss in superconducting TiN films is attributed to two-level systems in various interfaces arising in part from oxidation and microfabrication-induced damage. Atomic layer etching (ALE) is an emerging subtractive fabrication method which is capable of etching with angstrom-scale etch depth control and potentially less damage. However, while ALE processes for TiN have been reported, they either employ HF vapor, incurring practical complications, or the etch rate lacks the desired control. Furthermore, the superconducting characteristics of the etched films have not been characterized. Here, we report an isotropic plasma-thermal TiN ALE process consisting of sequential exposures to molecular oxygen and an SF 6 /H 2 plasma. For certain ratios of SF 6 :H 2 flow rates, we observe selective etching of TiO 2 over TiN, enabling self-limiting etching within a cycle. Etch rates were measured to vary from 1.1 Å/cycle at 150 ° C to 3.2 Å/cycle at 350 ° C using ex situ ellipsometry. We demonstrate that the superconducting critical temperature of the etched film does not decrease beyond that expected from the decrease in film thickness, highlighting the low-damage nature of the process. These findings have relevance for applications of TiN in microwave kinetic inductance detectors and superconducting qubits. [ABSTRACT FROM AUTHOR]

Published

2023

8. Isotropic plasma-thermal atomic layer etching of aluminum nitride using SF6 plasma and Al(CH3)3

Author

Wang, Haozhe, primary, Hossain, Azmain, additional, Catherall, David, additional, and Minnich, Austin J., additional

Published

2023

9. Isotropic plasma-thermal atomic layer etching of superconducting titanium nitride films using sequential exposures of molecular oxygen and SF6/H2 plasma

Author

Hossain, Azmain A., Wang, Haozhe, Catherall, David S., Leung, Martin, Knoops, Harm C.M., Renzas, James R., Minnich, Austin J., Hossain, Azmain A., Wang, Haozhe, Catherall, David S., Leung, Martin, Knoops, Harm C.M., Renzas, James R., and Minnich, Austin J.

Abstract

Microwave loss in superconducting TiN films is attributed to two-level systems in various interfaces arising in part from oxidation and microfabrication-induced damage. Atomic layer etching (ALE) is an emerging subtractive fabrication method which is capable of etching with angstrom-scale etch depth control and potentially less damage. However, while ALE processes for TiN have been reported, they either employ HF vapor, incurring practical complications, or the etch rate lacks the desired control. Furthermore, the superconducting characteristics of the etched films have not been characterized. Here, we report an isotropic plasma-thermal TiN ALE process consisting of sequential exposures to molecular oxygen and an SF 6 /H 2 plasma. For certain ratios of SF 6 :H 2 flow rates, we observe selective etching of TiO 2 over TiN, enabling self-limiting etching within a cycle. Etch rates were measured to vary from 1.1 Å/cycle at 150 ° C to 3.2 Å/cycle at 350 ° C using ex situ ellipsometry. We demonstrate that the superconducting critical temperature of the etched film does not decrease beyond that expected from the decrease in film thickness, highlighting the low-damage nature of the process. These findings have relevance for applications of TiN in microwave kinetic inductance detectors and superconducting qubits.

Published

2023

10. Isotropic plasma-thermal atomic layer etching of aluminum nitride using SF6 plasma and Al(CH3)3.

Author

Wang, Haozhe, Hossain, Azmain, Catherall, David, and Minnich, Austin J.

Subjects

ALUMINUM nitride, WIDE gap semiconductors, THERMAL plasmas, ETCHING, SEMICONDUCTOR devices, SURFACE roughness

Abstract

We report the isotropic plasma atomic layer etching (ALE) of aluminum nitride using sequential exposures of SF6 plasma and trimethylaluminum [Al(CH3)3]. ALE was observed at temperatures greater than 200 ° C, with a maximum etch rate of 1.9 Å/cycle observed at 300 ° C as measured using ex situ ellipsometry. After ALE, the etched surface was found to contain a lower concentration of oxygen compared to the original surface and exhibited a ∼ 35 % decrease in surface roughness. These findings have relevance for applications of AlN in nonlinear photonics and wide bandgap semiconductor devices. [ABSTRACT FROM AUTHOR]

Published

2023

11. Dielectric Screening Modulates Semiconductor Nanoplatelet Excitons

Author

Shin, Ashley J., primary, Hossain, Azmain A., additional, Tenney, Stephanie M., additional, Tan, Xuanheng, additional, Tan, Lauren A., additional, Foley, Jonathan J., additional, Atallah, Timothy L., additional, and Caram, Justin R., additional

Published

2021

12. Dielectric Screening Modulates Semicondcutor Nanoplatelet Excitons

Author

Shin, Ashley, primary, Hossain, Azmain A., primary, Tenney, Stephanie M., primary, Tan, Xuanheng, primary, Tan, Lauren A., primary, Foley, Jonathan, primary, Atallah, Timothy L., primary, and Caram, Justin, primary

Published

2021