Hannah J. Joyce

What is she best known for?

The fields of study she is best known for:

• Semiconductor
• Photon
• Optics

Hannah J. Joyce mainly investigates Nanowire, Optoelectronics, Nanotechnology, Photoluminescence and Terahertz radiation. Hannah J. Joyce performs integrative study on Nanowire and Wurtzite crystal structure. Her Optoelectronics study frequently intersects with other fields, such as Crystallographic defect.

Her biological study spans a wide range of topics, including Band gap and Semiconductor. Her studies deal with areas such as Gaas algaas, Heterojunction, Engineering physics and Gallium arsenide as well as Photoluminescence. Her work focuses on many connections between Terahertz radiation and other disciplines, such as Photoconductivity, that overlap with her field of interest in Graphene, Dirac fermion, Stimulated emission and Quantum Hall effect.

Her most cited work include:

• Phase Perfection in Zinc Blende and Wurtzite III-V Nanowires Using Basic Growth Parameters (369 citations)
• Twin-free uniform epitaxial GaAs nanowires grown by a two-temperature process (257 citations)
• III-V semiconductor nanowires for optoelectronic device applications (203 citations)

What are the main themes of her work throughout her whole career to date?

Hannah J. Joyce mostly deals with Nanowire, Optoelectronics, Nanotechnology, Semiconductor and Heterojunction. Her research in Nanowire intersects with topics in Metalorganic vapour phase epitaxy, Epitaxy, Chemical vapor deposition, Gallium arsenide and Photoluminescence. In the field of Optoelectronics, her study on Terahertz radiation, Terahertz spectroscopy and technology, Photoconductivity and Charge carrier overlaps with subjects such as Wurtzite crystal structure.

Many of her research projects under Nanotechnology are closely connected to Research council and Nucleation with Research council and Nucleation, tying the diverse disciplines of science together. The study incorporates disciplines such as Photonics and Condensed matter physics in addition to Semiconductor. Her Heterojunction study integrates concerns from other disciplines, such as Crystal growth, Quantum well, Superconductivity, Josephson effect and Wide-bandgap semiconductor.

She most often published in these fields:

• Nanowire (72.96%)
• Optoelectronics (67.35%)
• Nanotechnology (34.18%)

What were the highlights of her more recent work (between 2017-2021)?

• Optoelectronics (67.35%)
• Josephson effect (11.73%)
• Nanowire (72.96%)

In recent papers she was focusing on the following fields of study:

Her main research concerns Optoelectronics, Josephson effect, Nanowire, Semiconductor and Condensed matter physics. Her Optoelectronics research focuses on Perovskite and how it relates to Bifunctional. Her research on Josephson effect also deals with topics like

• Quantum well that intertwine with fields like Heterojunction, Critical field and Supercurrent,
• Integrated circuit that connect with fields like Field-effect transistor, Fermi gas, Diode and Laser.

Her Nanowire study necessitates a more in-depth grasp of Nanotechnology. In Semiconductor, Hannah J. Joyce works on issues like Photoluminescence, which are connected to Electronic band structure and Photocurrent. Her work in the fields of Terahertz radiation, such as Terahertz spectroscopy and technology, intersects with other areas such as Amplitude modulation.

Between 2017 and 2021, her most popular works were:

• Long-Range Charge Extraction in Back-Contact Perovskite Architectures via Suppressed Recombination (28 citations)
• Tin(iv) dopant removal through anti-solvent engineering enabling tin based perovskite solar cells with high charge carrier mobilities (14 citations)
• Integrated, Portable, Tunable, and Coherent Terahertz Sources and Sensitive Detectors Based on Layered Superconductors (9 citations)

In her most recent research, the most cited papers focused on:

• Semiconductor
• Optics
• Photon

Hannah J. Joyce mainly focuses on Optoelectronics, Josephson effect, Perovskite, Condensed matter physics and Quantum well. Her multidisciplinary approach integrates Optoelectronics and Photovoltaics in her work. Her studies in Josephson effect integrate themes in fields like Diode, Quantum information, Terahertz radiation, Quantum tunnelling and Laser.

The various areas that she examines in her Perovskite study include Tandem, Band gap and Charge carrier. Her Condensed matter physics research is multidisciplinary, incorporating elements of Photocurrent, Nanowire and Photoluminescence. Her work carried out in the field of Quantum well brings together such families of science as Superconductivity and Heterojunction.

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