| Pyroelectric materials and devices for energy harvesting applications CR Bowen, J Taylor, E LeBoulbar, D Zabek, A Chauhan, R Vaish Energy & Environmental Science 7 (12), 3836-3856, 2014 | 789 | 2014 |
| Modelling and fabrication of porous sandwich layer barium titanate with improved piezoelectric energy harvesting figures of merit JI Roscow, RWC Lewis, J Taylor, CR Bowen Acta Materialia 128, 207-217, 2017 | 123 | 2017 |
| Micropatterning of flexible and free standing polyvinylidene difluoride (PVDF) films for enhanced pyroelectric energy transformation D Zabek, J Taylor, EL Boulbar, CR Bowen Advanced Energy Materials 5 (8), 1401891, 2015 | 104 | 2015 |
| Multiple-electrode nerve cuffs for low-velocity and velocity-selective neural recording J Taylor, N Donaldson, J Winter Medical and Biological Engineering and Computing 42, 634-643, 2004 | 100 | 2004 |
| Design of a low-noise preamplifier for nerve cuff electrode recording R Rieger, J Taylor, A Demosthenous, N Donaldson, PJ Langlois IEEE Journal of Solid-State Circuits 38 (8), 1373-1379, 2003 | 100 | 2003 |
| Porous ferroelectrics for energy harvesting applications J Roscow, Y Zhang, J Taylor, CR Bowen The European Physical Journal Special Topics 224 (14), 2949-2966, 2015 | 92 | 2015 |
| A modified figure of merit for pyroelectric energy harvesting CR Bowen, J Taylor, E Le Boulbar, D Zabek, VY Topolov Materials Letters 138, 243-246, 2015 | 91 | 2015 |
| Freeze cast porous barium titanate for enhanced piezoelectric energy harvesting JI Roscow, Y Zhang, MJ Kraśny, RWC Lewis, J Taylor, CR Bowen Journal of Physics D: Applied Physics 51 (22), 225301, 2018 | 72 | 2018 |
| AC electrical properties of TiO2 and Magnéli phases, TinO2n− 1 D Regonini, V Adamaki, CR Bowen, SR Pennock, J Taylor, ACE Dent Solid State Ionics 229, 38-44, 2012 | 72 | 2012 |
| A CMOS analog winner-take-all network for large-scale applications A Demosthenous, S Smedley, J Taylor IEEE Transactions on Circuits and Systems I: Fundamental Theory and …, 1998 | 72 | 1998 |
| A 230-nW 10-s time constant CMOS integrator for an adaptive nerve signal amplifier R Rieger, A Demosthenous, J Taylor IEEE Journal of Solid-State Circuits 39 (11), 1968-1975, 2004 | 70 | 2004 |
| Very low-noise ENG amplifier system using CMOS technology R Rieger, M Schuettler, D Pal, C Clarke, P Langlois, J Taylor, ... IEEE Transactions on Neural Systems and Rehabilitation Engineering 14 (4 …, 2006 | 68 | 2006 |
| Manufacture and characterization of porous ferroelectrics for piezoelectric energy harvesting applications JI Roscow, J Taylor, CR Bowen Ferroelectrics 498 (1), 40-46, 2016 | 62 | 2016 |
| An adaptive sampling system for sensor nodes in body area networks R Rieger, JT Taylor IEEE Transactions on Neural Systems and Rehabilitation Engineering 17 (2 …, 2009 | 56 | 2009 |
| An improved configuration for the reduction of EMG in electrode cuff recordings: a theoretical approach M Rahal, J Winter, J Taylor, N Donaldson IEEE transactions on biomedical engineering 47 (9), 1281-1284, 2000 | 55 | 2000 |
| Fibre-selective recording from the peripheral nerves of frogs using a multi-electrode cuff M Schuettler, N Donaldson, V Seetohul, J Taylor Journal of neural engineering 10 (3), 036016, 2013 | 53 | 2013 |
| Commercialisation of CMOS integrated circuit technology in multi-electrode arrays for neuroscience and cell-based biosensors AHD Graham, J Robbins, CR Bowen, J Taylor Sensors 11, 4943-4971, 2011 | 53 | 2011 |
| A 100-Mb/s 2.8-V CMOS current-mode analog Viterbi decoder A Demosthenous, J Taylor IEEE Journal of Solid-State Circuits 37 (7), 904-910, 2002 | 53 | 2002 |
| CRC handbook of electrical filters J Taylor, Q Huang CRC Press, 2020 | 52 | 2020 |
| Noise and selectivity of velocity-selective multi-electrode nerve cuffs N Donaldson, R Rieger, M Schuettler, J Taylor Medical & biological engineering & computing 46, 1005-1018, 2008 | 50 | 2008 |
Chris BowenUniversity of Bath; Twitter: @BowenNEMESISBestätigte E-Mail-Adresse bei bath.ac.uk
