| Circadian and menstrual rhythms in frequency variations of spontaneous otoacoustic emissions from human ears A Bell Hearing research 58 (1), 91-100, 1992 | 117 | 1992 |
| Diffraction corrections in radiometry WH Steel, M De, JA Bell JOSA 62 (9), 1099-1103, 1972 | 61 | 1972 |
| Dichoptic multifocal pupillography reveals afferent visual field defects in early type 2 diabetes A Bell, AC James, M Kolic, RW Essex, T Maddess Investigative Ophthalmology & Visual Science 51 (1), 602-608, 2010 | 55 | 2010 |
| The cochlear amplifier as a standing wave:“Squirting” waves between rows of outer hair cells? A Bell, NH Fletcher The Journal of the Acoustical Society of America 116 (2), 1016-1024, 2004 | 52 | 2004 |
| A resonance approach to cochlear mechanics A Bell PLOS ONE 7 (11), e47918, 2012 | 47 | 2012 |
| Hearing: travelling wave or resonance? A Bell PLoS Biology 2 (10), e337, 2004 | 44 | 2004 |
| Comparing multifocal pupillographic objective perimetry (mfPOP) and multifocal visual evoked potentials (mfVEP) in retinal diseases F Sabeti, AC James, CF Carle, RW Essex, A Bell, T Maddess Scientific Reports 7, 45847, 2017 | 40 | 2017 |
| The pipe and the pinwheel: Is pressure an effective stimulus for the 9+ 0 primary cilium? A Bell Cell Biology International 32 (4), 462-468, 2008 | 35 | 2008 |
| How do middle ear muscles protect the cochlea? Reconsideration of the intralabyrinthine pressure theory A Bell Journal of Hearing Science 1 (2), 9-23, 2011 | 30 | 2011 |
| The underwater piano: a resonance theory of cochlear mechanics JA Bell Australian National University, 2005 | 22 | 2005 |
| Time–frequency analysis of linear and nonlinear otoacoustic emissions and removal of a short-latency stimulus artifact WW Jedrzejczak, A Bell, PH Skarzynski, K Kochanek, H Skarzynski The Journal of the Acoustical Society of America 131 (3), 2200-2208, 2012 | 20 | 2012 |
| Sensors, motors, and tuning in the cochlea: interacting cells could form a surface acoustic wave resonator A Bell Bioinspiration & Biomimetics 1 (3), 96, 2006 | 20 | 2006 |
| Detection without deflection? A hypothesis for direct sensing of sound pressure by hair cells A Bell Journal of Biosciences 32 (2), 385-404, 2007 | 17 | 2007 |
| Tuning the cochlea: wave-mediated positive feedback between cells A Bell Biological Cybernetics 96 (4), 421-438, 2007 | 13 | 2007 |
| ARE OUTER HAIR CELLS PRESSURE SENSORS? BASIS OF A SAW MODEL OF THE COCHLEAR AMPLIFIER A Bell Biophysics of the cochlea: from molecules to models, 429-431, 2003 | 12 | 2003 |
| Muscles in and around the ear as the source of “physiological noise” during auditory selective attention: A review and novel synthesis A Bell, WW Jedrzejczak European Journal of Neuroscience 53 (8), 2726-2739, 2021 | 11 | 2021 |
| The vibrating reed frequency meter: digital investigation of an early cochlear model A Bell, HP Wit PeerJ 3, e1333, 2015 | 11 | 2015 |
| Variations in the width of the nightglow OI ë6300 line during the magnetic storm of October 30–November 2, 1968 EB Armstrong, JA Bell Planetary and Space Science 18 (5), 784-789, 1970 | 11 | 1970 |
| Cochlear impulse responses resolved into sets of gammatones: the case for beating of closely spaced local resonances A Bell, HP Wit PeerJ 6, e6016, 2018 | 9 | 2018 |
| Annoyance from wind turbines: role of the middle ear muscles (L) A Bell Acoustics Australia 42 (1), 57, 2014 | 9 | 2014 |
Ted MaddessAustralian National UniversityVerified email at anu.edu.au
