Your search keyword '"Athle, Robin"' showing total 4 results

1. A method for estimating defects in ferroelectric thin film MOSCAPs.

Author

Persson, Anton E. O., Athle, Robin, Svensson, Johannes, Borg, Mattias, and Wernersson, Lars-Erik

Subjects

*FERROELECTRIC thin films, *METAL oxide semiconductor field-effect transistors, *FIELD-effect transistors, *SEMICONDUCTOR thin films, *WIDE gap semiconductors, *FERROELECTRICITY

Abstract

We propose a capacitance measurement scheme that enables quantitative characterization of ferroelectric thin films integrated on semiconductors. The film defect density is estimated by measurements of the CV hysteresis and frequency dispersion, whereas important device parameters such as memory window and endurance can be extracted by a unidirectional CV method. The simple measurement scheme and the usage of metal-oxide-semiconductor capacitors rather than MOSFETs make the proposed methods suitable for the future optimization of ferroelectric field effect transistor and negative capacitance field effect transistor gate stacks. Specifically, we present data for the narrow bandgap semiconductor InAs and show that low temperature characterization is critical to reduce the influence of the minority carrier response; however, the methods should be transferrable to room temperature for semiconductors with a wider bandgap. Our results clearly indicate that the defect density of the HfxZr1−xO2 (HZO) films increases at the crystallization temperature, but the increase is modest and remains independent of the annealing temperature at even more elevated temperatures. It is also shown that the shrinkage of the memory window caused by field cycling is not accompanied by an increase in defect density. [ABSTRACT FROM AUTHOR]

Published

2020

2. Reduced annealing temperature for ferroelectric HZO on InAs with enhanced polarization.

Author

Persson, Anton E. O., Athle, Robin, Littow, Pontus, Persson, Karl-Magnus, Svensson, Johannes, Borg, Mattias, and Wernersson, Lars-Erik

Subjects

*FERROELECTRIC thin films, *SEMICONDUCTOR thin films, *ATOMIC layer deposition, *CAPACITANCE-voltage characteristics, *TRANSMISSION electron microscopy

Abstract

Deposition, annealing, and integration of ferroelectric Hf x Zr 1 − x O 2 (HZO) thin films on the high-mobility semiconductor InAs using atomic layer deposition are investigated. Electrical characterization reveals that the HZO films on InAs exhibit an enhanced remanent polarization compared to films formed on a reference TiN substrate, exceeding 20 μ C / cm 2 even down to an annealing temperature of 370 ° C. For device applications, the thermal processes required to form the ferroelectric HZO phase must not degrade the high-κ/InAs interface. We find by evaluation of the capacitance–voltage characteristics that the electrical properties of the high-κ/InAs are not significantly degraded by the annealing process, and high-resolution transmission electron microscopy verifies a maintained sharp high-κ/InAs interface. [ABSTRACT FROM AUTHOR]

Published

2020

3. Improved quality of InSb-on-insulator microstructures by flash annealing into melt.

Author

Menon, Heera, Södergren, Lasse, Athle, Robin, Johansson, Jonas, Steer, Matthew, Thayne, Iain, and Borg, Mattias

Subjects

*RAPID thermal processing, *BACKSCATTERING, *SEMICONDUCTOR technology, *DIGITAL electronics, *DIFFRACTIVE scattering, *ELECTRICAL resistivity, *COMPLEMENTARY metal oxide semiconductors

Abstract

Monolithic integration of III–V semiconductors with Silicon technology has instigated a wide range of new possibilities in the semiconductor industry, such as combination of digital circuits with optical sensing and high-frequency communication. A promising CMOS compatible integration process is rapid melt growth (RMG) that can yield high quality single crystalline material at low cost. This paper represents the study on ultra-thin InSb-on-insulator microstructures integrated on a Si platform by a RMG-like process. We utilize flash lamp annealing (FLA) to melt and recrystallize the InSb material for an ultra-short duration (milliseconds), to reduce the thermal budget necessary for integration with Si technology. We compare the result from FLA to regular rapid thermal annealing (seconds). Recrystallized InSb was characterized using electron back scatter diffraction which indicate a transition from nanocrystalline structure to a crystal structure with grain sizes exceeding 1 μm after the process. We further see a 100× improvement in electrical resistivity by FLA annealed sample when compared to the as-deposited InSb with an average Hall mobility of 3100 cm2 V−1 s−1 making this a promising step towards realizing monolithic mid-infrared detectors and quantum devices based on InSb. [ABSTRACT FROM AUTHOR]

Published

2021

4. Fabrication of Single‐Crystalline InSb‐on‐Insulator by Rapid Melt Growth.

Author

Menon, Heera, Morgan, Nicholas Paul, Hetherington, Crispin, Athle, Robin, Steer, Matthew, Thayne, Iain, Fontcuberta i Morral, Anna, and Borg, Mattias

Subjects

*ELECTRON mobility, *MELTING, *PHOTODETECTORS

Abstract

InSb has the smallest bandgap and highest electron mobility among III‐V semiconductors and is widely used for photodetectors and high‐frequency electronic applications. Integration of InSb directly on Si would drastically reduce the fabrication cost and enable new applications, however, it is very challenging due to its 19% lattice mismatch with Si. Herein, the integration of single‐crystalline InSb microstructures on insulator‐covered Si through rapid melt growth (RMG) is reported and specifically provides details on the fabrication process. The importance of achieving high‐quality conformal capping layers at low thermal budget to contain the InSb melt is assessed when the sample is annealed. The importance of ensuring a pristine Si seed area to achieve single‐crystalline InSb is illustrated and demonstrated here for the first time. [ABSTRACT FROM AUTHOR]

Published

2022