{"id":27,"date":"2018-10-04T16:34:22","date_gmt":"2018-10-04T20:34:22","guid":{"rendered":"https:\/\/www2.whoi.edu\/staff\/template-blue-prepop\/?page_id=27"},"modified":"2022-04-11T14:55:21","modified_gmt":"2022-04-11T18:55:21","slug":"publications","status":"publish","type":"page","link":"https:\/\/www2.whoi.edu\/staff\/vmenezes\/publications\/","title":{"rendered":"Publications"},"content":{"rendered":"\n\n\t

Publications<\/h1>\n\t

<\/h3>\n\n[20] Menezes, V. V.<\/strong>\u00a0(2021). Advective pathways and transit times of the Red Sea Overflow Water in the Arabian Sea from Lagrangian simulations<\/a>. Progress in Oceanography<\/em>, 199, 102697, doi: 10.1016\/j.pocean.2021.102697<\/p>\n[19] Phillips, H. E., Tandon, A., Furue, R., Hood, R., Ummenhofer, C., Benthuysen, J., Menezes, V. V.<\/strong>, Hu, S., Ben Webber, B. Sanchez-Franks, A., Cherian, D., Shroyer, E., Feng, M., Wijeskera, H., Chatterjee, A., Yu, L., Hermes, J., Murtugudde, R., Tozuka, T., Su, D., Singh, A., Centurioni, L., Prakash, S. and Wiggert, J. (2021). Progress in understanding of Indian Ocean circulation, variability, air-sea exchange and impacts on biogeochemistry<\/a>. Ocean Sci.<\/em>, 17, 1677-1751, doi:10.5194\/os-17-1677-2021<\/p>\n[18] Menezes, V. V. <\/strong>(2020) Statistical assessment of sea-surface salinity from SMAP: Arabian Sea, Bay of Bengal and a promising Red Sea application<\/a>. Remote Sensing<\/em>, 12, 447, doi: 10.3390\/rs12030447<\/p>\n[17] Menezes, V. V.<\/strong>, Vianna, M. L. (2019)\u00a0Quasi-biennial Rossby and Kelvin waves in the South Indian Ocean: Tropical and subtropical modes and the Indian Ocean dipole.<\/a> Deep Sea Research II<\/em>, 166, 43-63, doi: 10.1016\/j.dsr2.2019.05.002, 2019<\/p>\n[16] Menezes, V. V.<\/strong>, Bower, A. and Farrar, J. T. (2019).\u00a0Evaporative implications of dry-air outbreaks over the Northern Red Sea<\/a>. J. Geophys. Res – Atmosphere<\/em>, 124, 4829-4861, doi: 10.1029\/2018JD028853 (*JGR Atmosphere Cover)<\/p>\n[15] Al Senafi, F., Anis, A., Menezes, V. V.<\/strong>\u00a0(2019) Surface heat fluxes over the Northern Arabian Gulf and the Northern Red Sea: Evaluation of ECMWF-ERA5 and NASA-MERRA2 reanalyses<\/a>. Atmosphere<\/em>, 10, 504, doi: 10.3390\/atmos10090504<\/p>\n[14] Menezes, V. V.<\/strong>, Farrar, J. T., Bower, A. S. (2018). Westward mountain-gap wind jets off the Northern Red Sea as seen by QuikSCAT satellite<\/a>.\u00a0 Remote Sens. Environ.<\/em>, 209, 677-699, doi: 10.1016\/j.rse.2018.02.075<\/p>\n[13] Mazloff, M. R., Sallee, J. B., Menezes, V. V.<\/strong>, Macdonald A. M., Meredith, M., Newman, L., Pellichero V., Roquet F., Swart, S., Wahlin, A. (2017). \u00a0Southern Ocean [in “State of the Climate in 2016”]. Bull. Amer. Meteor. Soc., 98<\/em>, S166-S167, doi: 10.1175\/2017BAMSStateoftheClimate.1<\/p>\n[12] Menezes, V. V.<\/strong>, Macdonald, A., Schatzman, C. (2017). Accelerated freshening of Antarctic Bottom Water over the last decade in the Southern Indian Ocean<\/a>. Science Advances<\/em>, 1, e1601426, doi: 10.1126\/sciadv.1601426 (*US CLIVAR research highlights, February 2017)<\/p>\n[11] Menezes, V. V.<\/strong>, Phillips, H. E., Vianna, M. L., Bindoff, N. L. (2016). Interannual variability of the South Indian Countercurrent<\/a>. J. Geophys. Res. Oceans<\/em>, 121, 3465-3487, doi: 10.1002\/2015JC011417<\/p>\n[10] Menezes, V. V.<\/strong>, Phillips, H. E., Schiller, A., Bindoff, N. L., Domingues, C. M., Vianna, M. L. (2014). South Indian Countercurrent and associated fronts<\/a>. J. Geophys. Res. Oceans<\/em>, 119, 6763-6791, doi: 10.1002\/2014JC010076<\/p>\n[9] \u00a0Menezes, V. V.<\/strong>, Vianna, M. L., Phillips, H. E. (2014) Aquarius sea surface salinity in the South Indian Ocean: Revealing annual-period planetary waves.<\/a> J. Geophys. Res. Oceans<\/em>, 119, 3883-3908, doi: 10.1002\/2014JC009935 (*AGU publications highlights, AGUniverse, July 10, volume 5, issue 14)<\/p>\n[8] Menezes, V. V.<\/strong>, Phillips, H., Schiller, A., Domingues, C. M., Bindoff, N. L. (2013) Salinity dominance on the Indian Ocean Eastern Gyral Current<\/a>. Geophys. Res. Lett.<\/em>, 40, 5716-5721, doi:10.1002\/2013GL057887<\/p>\n[7] Vianna, M. L, Menezes, V. V. <\/strong>(2013) Bidecadal sea level modes in the North and South Atlantic Oceans<\/a>. Geophys. Res. Lett.<\/em>, 40, 5926-5931, doi:10.1002\/2013GL058162<\/p>\n[6] Vianna, M. L., Menezes, V. V.<\/strong>\u00a0(2011) Double-celled subtropical gyre in the South Atlantic Ocean: Means, trends and interannual changes<\/a>. J. Geophys. Res. Oceans<\/em>, 116, C03024, doi: 10.1029\/2010JC006574<\/p>\n[5] Vianna, M. L., Menezes, V. V.<\/strong>, Pezza, A. B., Simmonds, I. (2010). Interaction between Hurricane Catarina (2004) and warm core rings in the South Atlantic Ocean<\/a>. J. Geophys. Res. Oceans<\/em>, 115, C07002, doi: 10.1029\/2009JC005974<\/p>\n[4] Vianna, M. L., Menezes, V. V. <\/strong>(2010) Mean mesoscale global ocean currents from geodetic pre-GOCE MDTs with a synthesis of the North Pacific circulation<\/a>. J. Geophys. Res. Oceans<\/em>, 115, C02016, doi: 10.1029\/2009JC005494<\/p>\n[3] Vianna, M. L., Menezes, V. V.<\/strong>, Chambers, D. (2007). A high-resolution satellite-only GRACE-based mean dynamic topography of the South Atlantic Ocean<\/a>. Geophys. Res. Lett.<\/em>, 34, L24604, doi: 10.1029\/2007GL031912<\/p>\n[2] Vianna, M. L., Menezes, V. V. <\/strong>(2006) Singular spectrum analysis of non-stationary tidal currents applied to ADCP data from the northeast Brazilian shelf.<\/a> J. Atmos. Oceanic Technol.<\/em>, 23, 138-151, doi: 10.1175\/JTECH1824.1<\/p>\n[1] Vianna, M. L., Menezes, V. V. <\/strong>(2003) A seasonal and interannual study of the western Equatorial Atlantic upper thermocline circulation variability. Interhemispheric Water Exchange in the Atlantic Ocean<\/em>, G. Goni and P. Malanotte-Rizzolli, eds. Elsevier Oceanography Series, 68, Elsevier, 137-174, doi: 10.1016\/S0422-9894(03)80145-9, 2003<\/p>\n\t

Highlighted publications<\/h3>\n