| 18.4% organic solar cells using a high ionization energy self‐assembled monolayer as hole‐extraction interlayer Y Lin, A Magomedov, Y Firdaus, D Kaltsas, A El‐Labban, H Faber, ... ChemSusChem 14 (17), 3569-3578, 2021 | 146 | 2021 |
| High-performance solar-blind flexible deep-UV photodetectors based on quantum dots synthesized by femtosecond-laser ablation S Mitra, A Aravindh, G Das, Y Pak, I Ajia, K Loganathan, E Di Fabrizio, ... Nano Energy 48, 551-559, 2018 | 84 | 2018 |
| Enhanced Performance of MoS2 Photodetectors by Inserting an ALD‐Processed TiO2 Interlayer Y Pak, W Park, S Mitra, AA Sasikala Devi, K Loganathan, Y Kumaresan, ... Small 14 (5), 1703176, 2018 | 63 | 2018 |
| Wirelessly powered large-area electronics for the Internet of Things L Portilla, K Loganathan, H Faber, A Eid, JGD Hester, MM Tentzeris, ... Nature Electronics 6 (1), 10-17, 2023 | 59 | 2023 |
| 100 GHz zinc oxide Schottky diodes processed from solution on a wafer scale DG Georgiadou, J Semple, AA Sagade, H Forstén, P Rantakari, YH Lin, ... Nature Electronics 3 (11), 718-725, 2020 | 53 | 2020 |
| Novel P‐Type Wide Bandgap Manganese Oxide Quantum Dots Operating at Deep UV Range for Optoelectronic Devices S Mitra, Y Pak, N Alaal, MN Hedhili, DR Almalawi, N Alwadai, ... Advanced Optical Materials 7 (21), 1900801, 2019 | 39 | 2019 |
| Low‐voltage heterojunction metal oxide transistors via rapid photonic processing E Yarali, H Faber, E Yengel, A Seitkhan, K Loganathan, GT Harrison, ... Advanced Electronic Materials 6 (6), 2000028, 2020 | 31 | 2020 |
| Colossal tunneling electroresistance in co‐planar polymer ferroelectric tunnel junctions M Kumar, DG Georgiadou, A Seitkhan, K Loganathan, E Yengel, H Faber, ... Advanced Electronic Materials 6 (2), 1901091, 2020 | 17 | 2020 |
| A Low‐Power CuSCN Hydrogen Sensor Operating Reversibly at Room Temperature V Kabitakis, E Gagaoudakis, M Moschogiannaki, G Kiriakidis, A Seitkhan, ... Advanced Functional Materials 32 (7), 2102635, 2022 | 12 | 2022 |
| Rapid and up-scalable manufacturing of gigahertz nanogap diodes K Loganathan, H Faber, E Yengel, A Seitkhan, A Bakytbekov, E Yarali, ... Nature Communications 13 (1), 3260, 2022 | 11 | 2022 |
| 14 GHz Schottky Diodes Using a p‐Doped Organic Polymer K Loganathan, AD Scaccabarozzi, H Faber, F Ferrari, Z Bizak, E Yengel, ... Advanced Materials 34 (22), 2108524, 2022 | 10 | 2022 |
| Printed memtransistor utilizing a hybrid perovskite/organic heterojunction channel C Ma, H Chen, E Yengel, H Faber, JI Khan, MC Tang, R Li, K Loganathan, ... ACS Applied Materials & Interfaces 13 (43), 51592-51601, 2021 | 9 | 2021 |
| ChemSusChem 2021 Y Lin, A Magomedov, Y Firdaus, D Kaltsas, A El-Labban, H Faber, ... DOI, 0 | 6 | |
| Fully Sprayed Metal Oxide Transistors Utilizing Ti3C2Tx MXene Contacts E Yarali, JK El-Demellawi, H Faber, D Naphade, Y Lin, K Loganathan, ... ACS Applied Electronic Materials 5 (2), 784-793, 2023 | 2 | 2023 |
| Methods for producing nanoscale patterns, nano-fluidic devices, and nanogap electrochemical devices TD Anthopoulos, K Loganathan, U Buttner, E Yengel, HA Faber US Patent App. 17/640,890, 2022 | | 2022 |
| Self-forming nanogap method and device TD Anthopoulos, K Loganathan, E Yarali, E Yengel, HA Faber US Patent App. 17/640,886, 2022 | | 2022 |
| Nanoscale soft-stamp and nanofluidic channel fabrication using nanogap metal electrodes made via adhesion lithography K Loganathan, U Butner, F Pisig Jr, A Syed, D Naphade, H Faber, ... Novel Patterning Technologies 2022, PC120540N, 2022 | | 2022 |
| Large Area Nanostructured Electronics Enabled Via Adhesion Lithography K Loganathan | | 2022 |
| Self-forming nanogap diodes operate beyond 10 GHz enabled via adhesion lithography (Conference Presentation) K Loganathan, E Yengel, H Faber, A Seitkhan, E Yarali, B Adilbekova, ... Novel Patterning Technologies for Semiconductors, MEMS/NEMS and MOEMS 2020 …, 2020 | | 2020 |
Thomas AnthopoulosProfessor of Emerging Optoelectronics, The University of Manchester (UK)Verified email at manchester.ac.uk
