[1] M. Alford, M. Gregg, and M. Ilyas. Diapycnal mixing in the Banda Sea: Results of the first microstructure measurements in the Indonesian Throughflow. Geophys. Res. Lett., 26(17):2741–2744, 1999.

[2] M. Alford and R. Pinkel. Observations of overturning in the thermocline: The context of ocean mixing. J. Phys. Oceanogr., 30:805–832, 2000.

[3] M. Alford and R. Pinkel. Patterns of turbulent and double diffusive phenomena: Observations from a rapid profiling conductivity probe. J. Phys. Oceanogr., 30:833–854, 2000.

[4] M. H. Alford. Fine structure contamination: Observations and a model of a simple two-wave case. J. Phys. Oceanogr., 9:2645–2649, 2001.

[5] M. H. Alford. Internal swell generation: The spatial distribution of energy flux from the wind to mixed-layer near-inertial motions. J. Phys. Oceanogr., 31(8):2359–2368, 2001.

[6] M. H. Alford. Energy available for ocean mixing redistributed through long-range propagation of internal waves. Nature, 423:159–163, 2003.

[7] M. H. Alford. Improved global maps and 54-year history of wind-work on ocean inertial motions. Geophys. Res. Lett., 30(8):1424–1427, 2003.

[8] M. H. Alford. Internal swell: Distribution and redistribution of internal-wave energy. In P. Müller and D. Henderson, editors, Dynamics of Oceanic Internal Gravity Waves, II, Proceedings, ’Aha Huliko’a     Hawaiian Winter Workshop University of Hawaii at Manoa, January 13-18, 2003, pages 29–40. Hawaii Institute of Geophysics, 2003.

[9] M. H. Alford. Reply to comment by F. Feser et al. on “Improved global maps and 54-year history of wind-work on ocean inertial motions”. Geophys. Res. Lett., 30(22):doi:10.1029/2003GL018543, 2003.

[10] M. H. Alford. Reply to comment by M. Watanabe et al. on “improved global maps and 54-year history of wind-work on ocean inertial motions”: Time aliasing in estimating the wind-induced inertial energy. Geophys. Res. Lett., 32(8, L08604):10.1029/2005GL022630, April 2005.

[11] M. H. Alford. Observations of parametric subharmonic instability of the diurnal internal tide in the South China Sea. Geophys. Res. Lett., 35(L15602):doi:10.1029/2008GL034720, 2008.

[12] M. H. Alford. Sustained, full-water-column observations of internal waves and mixing near Mendocino Escarpment. J. Phys. Ocean., 40(12):2643–2660, 2010.

[13] M. H. Alford, M. F. Cronin, and J. M. Klymak. Annual cycle and depth penetration of wind-generated near-inertial internal waves at Ocean Station Papa in the sub-Arctic Pacific. J. Phys. Ocean., in press, 2011.

[14] M. H. Alford, D. W. Gerdt, and C. M. Adkins. An ocean refractometer: Resolving millimeter-scale turbulent density fluctuations via the refractive index. J. Atmos. Ocean. Tech., 23(1):121–137, 2006.

[15] M. H. Alford and M. Gregg. Near-inertial mixing: Modulation of shear, strain and microstructure at low latitude. J. Geophys. Res., 106(C8):16947–16968, 2001.

[16] M. H. Alford, M. C. Gregg, and E. D’Asaro. Mixing, 3-D mapping and Lagrangian evolution of a thermohaline intrusion. J. Phys. Oceanogr., 35:1689–1711, 2005.

[17] M. H. Alford, M. C. Gregg, and M. A. Merrifield. Structure, propagation and mixing of energetic baroclinic tides in Mamala Bay, Oahu, Hawaii. J. Phys. Oceanogr., 36(6):997–1018, 2006.

[18] M. H. Alford, M. C. Gregg, V. Zervakis, and H. Kontoyiannis. Internal wave measurements on the Cycladic Plateau of the Aegean Sea. Journal of Marine Systems, in press, 2011.

[19] M. H. Alford, R. Lien, H. Simmons, J. M. Klymak, Y. Yang, D. Tang, and M. Huei Chang. Speed and evolution of nonlinear internal waves transiting the South China Sea. J. Phys. Ocean., 40(6):1338–1355, 2010.

[20] M. H. Alford, R. Lukas, B. Howe, A. Pickering, and F. Santiago-Mandujano. Moored observations of episodic abyssal flow and mixing at station ALOHA. Geophys. Res. Lett., 38(L15606):1–6, 2011.

[21] M. H. Alford, J. A. MacKinnon, J. D. Nash, H. L. Simmons, A. Pickering, J. M. Klymak, R. Pinkel, O. Sun, L. Rainville, R. Musgrave, T. Beitzel, K. Fu, and C. Lu. Energy flux and dissipation in Luzon Strait: two tales of two ridges. J. Phys. Ocean., in press, 2011.

[22] M. H. Alford, J. A. MacKinnon, Z. Zhao, R. Pinkel, J. Klymak, and T. Peacock. Internal waves across the Pacific. Geophys. Res. Lett., 34(L24601):doi:10.1029/2007GL031566, 2007.

[23] M. H. Alford and M. Whitmont. Seasonal and spatial variability of near-inertial kinetic energy from historical moored velocity records. J. Phys. Oceanogr., 37(8):2022–2037, 2007.

[24] M. H. Alford and Z. Zhao. Global patterns of low-mode internal-wave propagation, Part I: Energy and energy flux. J. Phys. Ocean., 37(7):1829–1848, 2007.

[25] M. H. Alford and Z. Zhao. Global patterns of low-mode internal-wave propagation, Part II: Group velocity. J. Phys. Ocean., 37(7):1849–1858, 2007.

[26] M. H. Alford, Z. X. Zhao, J. A. MacKinnon, R. Pinkel, and J. M. Klymak. Internal tide refraction and attenuation in the North Pacific. J. Phys. Ocean., in preparation, 2011.

[27] B. Chinn, M. H. Alford, and J. B. Girton. Observations of internal waves and parametric subharmonic instability in the Philippines archipelago. J. Geophys. Res., submitted, 2011.

[28] M. L. Eich, M. A. Merrifield, and M. H. Alford. Structure and variability of semidiurnal internal tides in Mamala Bay, Hawaii. J. Geophys. Res., 109(C5):DOI10.1029/2003JC00204, 2004.

[29] D. M. Farmer, M. H. Alford, Y. Yang, M. Huei Chang, and Q. Li. Nonlinear Internal Waves in the South China Sea. Oceanography, in press, 2011.

[30] J. B. Girton, B. Chinn, and M. H. Alford. Internal Wave Climates of the Philippine Seas. Oceanography, 24(1):100–111, 2011.

[31] M. C. Gregg, M. H. Alford, H. Kontoyiannis, and V. Zervakis. Mixing on steep sides of the Cycladic Plateau of the Aegean Sea. Journal of Marine Systems, in press, 2011.

[32] M. C. Gregg, G. Carter, M. Alford, D. Winkel, L. Rainville, J. Small, and J. Mickett. Hawaii Ocean Mixing Experiment (HOME), leg 2 R/V Revelle, 4 October to 6 November, 2000: Preliminary data report, December 19, 2000. Technical report, APL/UW, 2000.

[33] M. C. Gregg, R. A. Hall, G. S. Carter, M. H. Alford, R. Lien, D. P. Winkel, and D. J. Wain. Flow and mixing in Ascension, a steep, narrow canyon. J. Geophys. Res., 116(C07016), 2011.

[34] P. Hosegood, M. C. Gregg, and M. H. Alford. Sub-mesoscale lateral density structure in the oceanic surface mixed layer. Geophys. Res. Lett., 33(L22604):doi:10.1029/2006GL026797, 2006.

[35] P. J. Hosegood, M. C. Gregg, and M. H. Alford. Restratification of the surface mixed layer with submesoscale lateral density gradients: Diagnosing the importance of the horizontal dimension. J. Phys. Ocean., 38:2438–2460, 2008.

[36] S. Kelly, J. D. Nash, K. I. Martini, M. H. Alford, and E. Kunze. Tide-topography coupling along a continental margin: Internal-tide generation and scattering. J. Geophys. Res., in preparation:1, 16 2011.

[37] J. M. Klymak, M. H. Alford, R. Pinkel, R. C. Lien, and Y. J. Yang. The breaking and scattering of the internal tide on a continental slope. J. Phys. Ocean., 41(5):926–945, 2011.

[38] J. A. MacKinnon, M. H. Alford, P. Bouruet-Aubertot, N. Bindoff, S. Gille, J. Girton, M. C. Gregg, R. Hallberg, E. Kunze, A. Naveira Garabato, H. Phillips, R. Pinkel, K. Polzin, T. B. Sanford, H. L. Simmons, and K. G. Speer. Using global arrays to investigate internal-waves and mixing. In J. Hall, D. Harrison, and D. Stammer, editors, Proceedings of the “OceanObs ’09: Sustained Ocean Observations and Information for Society" Conference, Venice, Italy, 21-25 September 2009, volume 2 of ESA Publication WPP-306, 2011.

[39] J. A. MacKinnon, M. H. Alford, R. Pinkel, J. Klymak, and Z. Zhao. Mixing across the Pacific. J. Phys. Oceanogr., submitted, 2011.

[40] J. A. MacKinnon, M. H. Alford, R. Pinkel, Z. Zhao, J. M. Klymak, and O. Sun. Parametric subharmonic instability and turbulence along an internal tide path. J. Phys. Ocean., in preparation, 2010.

[41] J. A. MacKinnon, M. H. Alford, O. Sun, R. Pinkel, Z. Zhao, and J. Klymak. Parametric Subharmonic Instability of the internal tide at 29N. J. Phys. Ocean., submitted, 2011.

[42] K. I. Martini, M. H. Alford, S. Kelly, and J. D. Nash. Observations of remotely-generated internal tides breaking on the Oregon continental slope. J. Phys. Ocean., submitted, 2011.

[43] K. I. Martini, M. H. Alford, S. Kelly, and J. D. Nash. Observations of remotely incident, critically reflecting waves on the Oregon Continental Slope. J. Phys. Ocean., 41(9): 1772-1794, 2011.

[44] K. I. Martini, M. H. Alford, J. D. Nash, E. Kunze, and M. A. Merrifield. Diagnosing a partly standing internal wave in Mamala Bay, Oahu. Geophys. Res. Lett., 34(L17604):doi:10.1029/2007GL029749, 2007.

[45] J. B. Mickett, M. H. Alford, and A. H. Devol. Observations of energetic sub-inertial internal waves in a washington fjord. (in prep.), 2010.

[46] J. B. Mickett, Y. L. Serra, M. F. Cronin, and M. H. Alford. Resonant forcing of mixed layer inertial motions by atmospheric easterly waves in the Northeast tropical Pacific. J. Phys. Oceanogr., 40(2):401–416, 2010.

[47] J. D. Nash, M. H. Alford, and E. Kunze. Estimating internal-wave energy fluxes in the ocean. J. Atmos. Ocean. Tech., 22(10):1551–1570, 2005.

[48] J. D. Nash, M. H. Alford, E. Kunze, K. Martini, and S. Kelly. Hotspots of deep ocean mixing on the Oregon continental slope. Geophys. Res. Lett., 34(L01605):doi:10.1029/2006GL028170, 2007.

[49] A. Pickering, M. H. Alford, Z. Zhao, J. A. MacKinnon, R. Pinkel, and J. M. Klymak. Near-Inertial Waves During the Internal Waves Across the Pacific Experiment. J. Phys. Ocean., submitted, 2011.

[50] R. Pinkel and M. H. Alford. Internal wave energetics at a seamount on the California Continental Borderland. In P. Müller and D. Henderson, editors, Dynamics of Oceanic Internal Gravity Waves, II, Proceedings, ’Aha Huliko’a Hawaiian Winter Workshop University of Hawaii at Manoa, January 18–22, 1999, pages 21–28, 1999.

[51] J. Pullen, A. L. Gordon, J. Sprintall, C. Lee, M. Alford, J. D. Doyle, and P. May. Atmospheric and oceanic processes in the vicinity of an island strait. Oceanography, 24(1):112–121, 2011.

[52] P. J. Rusello, E. Siegel, and M. H. Alford. High resolution doppler profiler measurements of turbulence from a profiling body. Journal of Ocean Technology, in press:1–2, 2011.

[53] P. J. Rusello, E. Siegel, and M. H. Alford. High resolution doppler profiler measurements of turbulence from a profiling body. IEEE Current, Waves and Turbulence Workshop, submitted:1–7, 2011.

[54] A. Shcherbina, M. C. Gregg, M. H. Alford, and R. Harcourt. Characterizing thermohaline intrusions in the North Pacific subtropical frontal zone. J. Phys. Ocean., 39(11):2735–2756, 2009.

[55] A. Y. Shcherbina, M. C. Gregg, M. H. Alford, and R. R. Harcourt. Three-dimensional structure and temporal evolution of submesoscale thermohaline intrusions in the north pacific subtropical frontal zone. J. Phys. Oceanogr., 40(8):1669–1689, 2010.

[56] H. Simmons, M. H. Alford, C. Jackson, J. A. M. J. D. Nash, A. Pickering, and L. C. St. Laurent. Dynamic modeling of internal tides in the Luzon Straits. Ocean Modelling, in prep., 2011.

[57] Z. Zhao and M. H. Alford. Source and propagation of nonlinear internal waves in the northeastern South China Sea. J. Geophys. Res., 111(C11012):doi:10.1029/2006JC003644, 2006.

[58] Z. Zhao and M. H. Alford. New altimetric estimates of mode-one M2 internal tides in the Central North Pacific Ocean. J. Phys. Ocean., 39:1669–1684, 2009.

[59] Z. Zhao, M. H. Alford, J. Girton, S. T. M. Johnston, and G. S. Carter. Internal Tides around the Hawaiian Ridge estimated from Multi-Satellite Altimetry. J. Geophys. Res., 116, C12039, 2011.

[60] Z. Zhao, M. H. Alford, J. A. MacKinnon, and R. Pinkel. Long-range propagation of the semidiurnal internal tide from the Hawaiian Ridge. J. Phys. Oceanogr., 40(4):713–736, 2010.