Refereed Papers

Articles in Refereed Journals, Transactions or Archives (see ORCID for more recent update)

ORCiD http://orcid.org/0000-0001-8704-6199

1. M. Budak, A. Sasmal, K. Grosh, G. Corfas, V. Booth, M. Zhochowski. Contrasting mechanisms for hidden hearing loss: synaptopathy vs myelin defects. PLoS Comput. Biol., in press (2020).

2. A. Nankali, Y. Wang, C.E. Strimbu, E. S. Olson, and K. Grosh. A role for the tectorial membrane in activating the cochlear amplifier. Scientific Reports, 17620, 10(1) (2020).

3. A. Hake, C. Zhao, L. C. Ping, and K. Grosh. Ultraminiature AlN diaphragm acoustic sensor. Applied Phys. Letters, 117(14) (2020).

4. A. Sasmal, Geib, N Popa, B-I, Grosh, K, Broadband nonreciprocal linear acoustics through a non-local active metamaterial. New J. of Physics 22(6) (2020).

5. A. Sasmal and K. Grosh. A unified cochlear model for low- and high-frequency mammalian hearing. Proc. Natl. Acad. of Sci. USA. 116(28) 13983-13988 (2019).

6. C. Zhao, K. E. Knisely, K. Grosh. Design and fabrication of a piezoelectric MEMS xylophone transducer with a flexible electrical connection, Sensors & Actuators: A. Physical. 275:29-36, (2018).

7. A. Sasmal and K. Grosh. The competition between the noise and shear motion sensitivity of cochlear inner hair cell stereocilia. Biophysical J. 114: 474-483, (2018).

8. A. Nankali and K. Grosh. Simulating the Chan-Hudspeth experiment on an active excised cochlear segment. J. Acoust. Soc. Amer. 142(1), pp. 215-227. (2017)

9. X. Zhao, G. Liu, C. Zhao, C, K. Grosh. Broadband noise attenuation using a variable locally reacting impedance. J. Acoust. Soc. Amer. 141(1): 157-158 (2017).

10. Y. Li and K. Grosh. The Coda of the Transient Response in a Sensitive Cochlea: A Computational Modeling Study. PLoS Comput. Biol .12(7): e1005015. doi: 10.1371/journal.pcbi.1005015 PMID 27380177 (2016).

11. K. E. Knisely and K. Grosh, Effect of AC Target Power on AlN Film Quality. J. Vac. Sci. Tech. A 32(5):051504 - 051504-5, 2014.

12. T.Y. Ren, W. He, Y. Li, K. Grosh, A. Fridberger, Light-induced vibration in the hearing organ. Scientific Reports, 4(5941) (2014).

13. Meaud, J and Grosh K. Effect of the attachment of the tectorial membrane on cochlear micromechanics and two-tone suppression. Biophys. J. 106:398–1405 (2014).

14. J. Meaud and K. Grosh. Response to a pure tone in a nonlinear mechanical-electrical-acoustical model of the cochlea. Biophys. J., 102(6), pp. 1237-1246, (2012).

15. Y. Li and K. Grosh. Direction of wave propagation in the cochlea for internally excited basilar membrane. J. Acoust. Soc. Amer. 131(6) pp. 4710-4721 (2012).

16. V. Singh, K. Knisely, S. Yonak, K. Grosh, and D. Dowling. Non-line-of-sight sound source localization using matched-field processing. J. Acoust. Soc. Amer. 131(1) pp. 292-302 (2012).

17. R. J. Littrell and K. Grosh. Modeling and characterization of cantilever-based MEMS piezoelectric sensors and actuators. J. MEMS 21(2) pp. 406-413, (2012).

18. J. Meaud and K. Grosh. Coupling active hair bundle mechanics, fast adaptation, and somatic motility in a cochlear model. Biophysical J., 100(11), (2011).

19. S. Calve, I. F. Lytle, K. Grosh, D. L. Brown, and E. M. Arruda. Implantation increases Tensile Strength and Collagen Content of Self-Assembled Tendon Constructs. J. Appl. Physiology 148(4), pp. 875-881, (2010).

20. J. Meaud and K. Grosh. The effect of tectorial membrane and basilar membrane longitudinal coupling in cochlear mechanics. J. of the Acoust. Soc. of Amer., 127(3), pp. 1411-1421, (2010).

21. J. Ashmore, P. Avan, W.E. Brownell, P. Dallos, K. Dierkes, R. Fettiplace, K. Grosh, C.M. Hackney, A.J. Hudspeth, F. Julicher, B. Linder, P. Martin, J. Meaud, C. Petit, J.R.S. Santos-Sacchi, and B. Canlon. The remarkable cochlear amplifier. Hearing Research 266(1-2), pp. 1-17, (2010)

22. X. Jiang and K. Grosh. Including physiologically-based nonlinearity in a cochlear model. ASME J. of Vibrations and Acoustics, 132(2), (2010)

23. H. Narayanan, E. M. Arruda, K. Grosh, K. Garkipati. The micromechanics of fluid-solid interactions during growth in porous soft biological tissue. Biomechanics and Modeling in Mechanobiology, 8(3) pages 167-181, (2009).

24. L. Cheng, R. D. White, and K. Grosh. Three-dimensional viscous finite element formulation for acoustic fluid-structure interaction. Computer Methods in Applied Mechanics and Engineering, 197(49-50), pp 4160-4172, (2008).

25. L. Cheng and K. Grosh The trapped fluid transducer: modeling and approximation. J. Acoust. Soc. Amer., 123(6) pp. 4152-4164 (2008).

26. C. J. Gailbraith, R. D. White, L. Cheng, K. Grosh, and G. M. Rebeiz. Cochlea-based RF channelizing filters. IEEE Trans. On Circuits and Systems, 55(4), pp 969-979, (2008).

27. W. He, A. Friderberger, E. Porsov, K. Grosh, and T. Ren, Reverse wave propagation in the cochlea. Proc. National Acad. of Sci. USA, 105(7), pp. 2729-2733, (2008).

28. R. D. White, L. Cheng, and K. Grosh. Microfabrication of coupled fluid-structure systems with applications in acoustic sensing. Sensors and Actuators A: Physical. 141(2), pp. 288-298, (2008).

29. S. Ramamoorthy, N. V. Deo, and K. Grosh. A mechano-electro-acoustical model for the cochlea: Response to acoustic stimuli. J. Acoust. Soc. Amer., 121(5), pp. 2758-2773, (2007).

30. J. Zheng, N. V. Deo, Y. Zou, K. Grosh, and A. L. Nuttall. Chlorpromazine alters cochlear mechanics and amplification: in vivo evidence for organ of Corti stiffness modulation. J. of Neurophysiology 97(2), pp. 994-1004 (2007).

31. J. E. Olberding, H. Narayanan, E. M. Arruda, K. Grosh, S. Calve. Biological Remodelling: Stationary Energy, configuration change, internal variables and dissipation. J. Mechs. and Physics of Solids, 54 (7), pp 1493-1515, (2006).

32. A. A. Spector, N. Deo, K. Grosh, J. Tilak Ratnanather, R. M. Raphael. Electromechanical models of the outer hair cell composite membrane.J. Membrane Biology, 209 (2-3), pp 135-152 (2006).

33. K. Halsey, K. Fegelman, K. Grosh, and D. F. Dolan. Long term effects of acoustic trauma on the electrically evoked otoacoustic emission. J. Assoc. for Res. in Otolaryngology, 6(4), pp 324-340, (2005).

34. E. K. Kuhl, K. Garikipati, E. M. Arruda, and K. Grosh. Remodeling of biologic tissue: Mechanically induced reorientation of a transversely isotropic network model. J. Mechs. and Physics of Solids, 53(7), pp 1552-1573 (2005).

35. R. D. White and K. Grosh. Microengineered hydrodynamical cochlear model.Proc. of the National Acad. of Sci., 102 (5), pp 1296-1301 (2005).

36. N. Deo and K. Grosh. Simplified nonlinear outer hair cell models. J. Acoust. Soc. Amer.117(4), pp. 2141-2146 (2005).

37. J.-B. Park, K. Grosh, Y.-H Kim. A dimensionless analysis to investigate the effect of a periodic absorptive strip arrangement on an interior sound field. J. Acoust. Soc. Amer. 117 (2), pp. 763-770, (2005).

38. J. E. Bischoff, E. M. Arruda, K. Grosh. A rheological network formulation for orthotropic viscoelasticity in soft tissue. Biomechanics and Modeling in Mechanobiology,3(1), pp. 56-65(2004).

39. A. L. Nuttall, K. Grosh, Zheng, J., de Boer, E., Ren, T., Zhao. Spontaneous basilar membrane oscillationand otoacoustic emission at 15 kHz in a guinea pig. J. Assoc. Res. Otolaryngology, 5 (4), pp 337-348, (2004).

40. S. Calve, R. G. Dennis, P. E. Kosnik II, K. Baar, K. Grosh, and E. M. Arruda. Engineering of functional tendon.Tissue Engineering 10 (5-6), pp 755-761 (2004).

41. K. Garikipati, Arruda, E. M., Grosh, K., Narayanan, H., Calve, S., A continuum treatment of growth in biological tissue: The coupling of mass transport and growth. J. Mechs. Phys. of Solids, 52(7), pp 1595-1625, (2004)

42. N. Deo and K. Grosh, A modified area motor model for outer hair cell mechanics. Biophys. J., 86(6), 2004.

43. K. Grosh, J. Zheng, E. deBoer, A. L. Nuttall. High frequency electromotility of the cochlea.J. Acoust. Soc. of Amer, 115, 2178-2184, (2004).

44. Sripriya Ramamoorthy, K. Grosh, and Tony Nawar. Structural acoustic silencers-Design and experiment. J. Acoust. Soc. Amer., 114 (5), pp. 2812-2824, (2003).

45. Yuan Lin and K. Grosh.Iterative solution strategies for three-dimensional high frequency response of fluid-loaded piezoelectric transducers. Finite Element Analysis and Design 39 (10): 951-964, (2003).

46. James R. Barber, Karl Grosh and Sejoong Oh, Energy considerations in systems with varying stiffness.ASME, J. Appl. Mech., 70 (4), pp. 465-469, (2003).

47. Kelly Bailo, Diann Brei and Karl Grosh. Investigation of piezoelectric polymeric active diaphragms for sound sources. ASME J. Vib. Acoust., 125 (2): 145-154, (2003).

48. Anand A. Parthasarathi, Karl Grosh, Alfred L. Nuttall, and Jiefu Zheng. Influence of direct current stimulation on the in vivo basilar membrane velocity response. J. Acoust. Soc. Amer., 113, pp. 442-452, (2003).

49. Yuan Lin and Karl Grosh.Topology optimization of the kerf filling in ultrasonic phased arrays. J. Acoust. Soc. Amer., 112 (5) pp 1968-1979, (2002).

50. Yuan Lin and K. Grosh.Iterative solution strategies for three-dimensional high frequency response of fluid-loaded piezoelectric transducers. Finite Element Method Analysis and Design, 38 (10): 983-998 (2002).

51. Jeffery E. Bischoff, Ellen M. Arruda, and Karl Grosh. A microstructurally based orthotropic hyperelastic constitutive law. ASME J. Appl. Mech., 69 (5), pp. 570-579, (2002).

52. Sripriya Ramamoorthy, Karl Grosh, John M. Dodson. A theoretical study of structural acoustic silencers for hydraulic systems.J. Acoust. Soc. Amer., 111 (5), pp. 2097-2108, (2002).

53. Pete Halliday and K. Grosh.Maximum likelihood estimation of structural wave components from noisy data. J. Acoust. Soc. Amer. 111 (4), pp. 1709-1717 (2002).

54. Jeffery E. Bischoff, Ellen M. Arruda, and Karl Grosh. Finite element simulations of orthotropic hyperelasticity. Finite Element Analysis and Design, 38 (10), pp. 983-998, (2002)

55. Karen. J. L. Fegelman and K. Grosh. Dynamics of a flexible beam contacting a linear spring: experiment and analysis. ASME J. Vib. Acoust. 124 (2), pp. 237-249 (2002).

56. Alfred L. Nuttall, Tianying Ren, Egbert de Boer, Jiefu Zheng, Anand Parthasarathi, Karl Grosh, Menghe Guo, and David Dolan. In vivo micromechanical measurements of the organ of Corti in the basal cochlear turn. Audiology and Neuro-otology 7 (1) pp. 21-26, (2002)

57. Yuan Lin and K. Grosh. Design of ultrasonic array elements for acoustic power considerations.IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control. 2002. 49 (1) pp. 20-28 (2002).

58. Jeffery E. Bischoff, Ellen M. Arruda, and Karl Grosh.A new constitutive model for the compressibility of elastomers at finite deformations. J. Rubber Chem. and Tec, 74 (4), pp. 541-559, (2001).

59. Karl Grosh. Residual based methods for fluid-loaded beams. Computer Methods in Applied Mechanics and Engineering, 190, pp. 2543-2554, (2001).

60. Jeffery E. Bischoff, Ellen M. Arruda, and Karl Grosh.Nonlinear constitutive models for skin response. J. Biomech. 33, pp. 645-652, (2000).

61. Anand A. Parthasarathi , Karl Grosh and Alfred L. Nuttall. Three--dimensional numerical modeling for global cochlear dynamics. J. Acoust. Soc. Amer., 107(1), Jan. 2000, pp. 474-485 (2000).

62. Pete Halliday and K. Grosh.Dynamic response of complex structural intersections using hybrid methods. ASME J. Applied Mech. 66(3), pp 653-659, (1999).

63. Karl Grosh and Peter M. Pinsky.Galerkin generalized least squares finite element methods for time harmonic structural acoustics. Computer Methods in Applied Mechanics and Engineering, 154 (3-4), pp. 299-318, (1998).

64. John M. Dodson, David R. Dowling and Karl Grosh. Design and effectiveness of in-line tuning cables for quieting hydraulic power units. J. of Noise Control Engineering 46 (1), pp. 15-22, (1998).

65. Isaac Harari, Karl Grosh, Thomas J. R. Hughes, Manish Malhotra, Peter M. Pinsky, Lonny L. Thompson.Recent developments in finite element methods for structural acoustics. Archives of Computational Methods in Engineering, 3 (2-3), pp.131-309, (1996).

66. Karl Grosh and Peter M. Pinsky.Galerkin generalized least squares methods for Timoshenko beams. Computer Methods in Applied Mechanics and Engineering, 132, pp.1-16, (1996).

67. Karl Grosh, Peter M. Pinsky, Manish Malhotra, and Vinay S. Rao. Finite element formulation for a baffled, fluid--loaded, finite cylindrical shell. International Journal for Numerical Methods in Engineering, 37, pp. 2971-2985, (1994).

68. Karl Grosh and Peter M. Pinsky.Complex wave--numberdispersion analysis of Galerkin and Galerkin least squares methods for fluid-loaded plates. Computer Methods in Applied Mechanics and Engineering, 113, pp. 67-98, (1994).

69. Karl Grosh and Earl G. Williams. Complex wave--number decomposition of structural vibrations. Journal of the Acoustical Society of America, 93(2), pp.836-848, (1993).

70. Adin Mann III, Earl G. Williams, Karl B. Washburn, and Karl Grosh. Time domain analysis of the energy exchange between structural vibrations and acoustic radiation using near--field acoustical holography measurements. J. of the Acoust. Soc. of Amer., 90(3), pp. 1656-1665, (1991).

Shorter Communications, Letters, Notes or Briefs in Refereed Publications

1. Jeffery E. Bischoff, Ellen M. Arruda, and Karl Grosh.Orthotropic hyperelasticity in terms of an arbitrary molecular model. ASME J. Appl. Mech., 69 (2), pp. 198-201, (2002).

2. Sejoong Oh, Karl Grosh and J. R. Barber. Energy conserving equations for gear systems. ASME J. Vib. Acous. to appear.

Chapters in Books:

J. Meaud, Y. Li, and K. Grosh. The generation of harmonic distortion and distortion products in a computational model of the cochlea. C. A. Shera and E. S. Olson, eds., in Mechanics of Hearing. American Institute of Physics (2011).

Y. Li, J. Meaud, and K. Grosh. Coupling the sub-tectorial fluid with the tectorial membrane and hair bundles of the cochlea. C. A. Shera and E. S. Olson, eds., in Mechanics of Hearing. American Institute of Physics (2011).

K. Grosh, N. Deo, A. A. Parthasarathi, J. Zheng, A. L. Nuttall and T. Y. Ren.Modeling electrically evoked otoacoustic emissions. in Biophysics of the Cochlea: from Molecules to Models, Ed. A.W Gummer, World Scientific, New Jersey,page 539-546, 2003.

A. Nuttall, K. Grosh, et al., High frequency electromotile responses in the cochlea. in Biophysics of the Cochlea: from Molecules to Models, Ed. A.W Gummer, World Scientific, New Jersey, page 539-546, 2003.

Patents:

“Method of sensing an amount of moisture on a surface of a substrate with temperature compensation” (US Patent US 7,696,710 accessible at www.google.com/patents/US7696710). Inventors: Colin J. Byrne, K. Grosh, Brent W. Pankey, and Mitchell M. Rohde (AGCA, Inc.)

“A Piezoelectric MEMS Microphone” (US Utility Patents 8,896,184 and 8,531,088 accessible at www.google.com/patents/US20100254547). Inventors: Robert J. Littrell and Karl Grosh. (U of M)

“Trapped fluid microsystems for acoustic sensing” (US Utility Patent 8,130,986 accessible at www.google.com/patents/US20070230721). Inventors: Robert D. White and Karl Grosh (U of M).

“Acoustic transducer with gap-controlling geometry and method of manufacturing an acoustic transducer”. Inventors: Karl Grosh and Robert J. Littrell. US 9,055,372 Utility Patent (2015) plus continuation in part (CIP) 10,284,960 (2019). (Vesper MEMS).

"A Flexible, MEMS-Based Cochlear Implant" Karl Grosh and Katherine Knisley. US 9,937,345 (U of M). (2018)

“Adjusting resonant frequencies based on feedback networks” R. Littrell, and K. Grosh. US 10,001,391 (Vesper MEMS) (2018)

"Piezoelectric micro-electro-mechanical systems (MEMS) device with a beam strengthening physical element," R. Littrell, K. Grosh, C. Core, Y. Hui, W.-K. Sung as U.S. Patent No. 10,825,982 (Vesper MEMS) (2020).

“Staggering of openings in electrodes for crack mitigation”. Robert J. Littrell and Karl Grosh. U.S. Patent No. 10,566,517 (Vesper MEMS) (2020)

“Piezoelectric MEMS device for producing a signal indicative of detection of an acoustic stimulus” R. Littrell, R. Gagnon, and K. Grosh. U.S. Patent No. 10,715,922 (Vesper MEMS) (2020)

Patent Application

“Vibration sensor” A. E. Hake and K. Grosh. PCT/US2020/32914 (U of M) (2020).

“A Piezoelectric MEMS Microphone” (US Patent Application 20100254547 accessible at www.google.com/patents/US20100254547). Inventors: Robert J. Littrell and Karl Grosh.

“Trapped fluid microsystems for acoustic sensing” (US Patent Application 20070230721 accessible at www.google.com/patents/US20070230721). Inventors: Robert D. White and Karl Grosh

“Method of sensing an amount of moisture on a surface of a substrate with temperature compensation” (US Patent US7,696,710 accessible at www.google.com/patents/US7696710). Inventors: Colin J. Byrne, K. Grosh, Brent W. Pankey, and Mitchell M. Rohde