{"id":23,"date":"2022-02-25T16:22:47","date_gmt":"2022-02-25T20:22:47","guid":{"rendered":"http:\/\/www.personal-site.dev\/?page_id=23"},"modified":"2023-04-26T12:14:43","modified_gmt":"2023-04-26T16:14:43","slug":"papers","status":"publish","type":"page","link":"https:\/\/www2.whoi.edu\/site\/piecuch\/papers\/","title":{"rendered":"Papers"},"content":{"rendered":"\n\n\t

PAPERS<\/p>\n\t\t\t\t\n\t\t\t\t\"PNAS\n\t\t\t\t<\/a>\n\t

River-discharge effects on United States Atlantic and Gulf coast sea-level changes<\/p>\n\t\t\t\t\n\t\t\t\t\"Nature\"\n\t\t\t\t<\/a>\n\t

Origin of spatial variation in US East Coast sea-level trends during 1900-2017<\/p>\n\t\t\t\t\n\t\t\t\t\"Nature\n\t\t\t\t<\/a>\n\t

Climate did not drive Common Era Maldivian sea-level lowstands<\/p>\n\t\t\t\t\n\t\t\t\t\"Nature\n\t\t\t\t<\/a>\n\t

Persistent acceleration in global sea-level rise since the 1960s<\/p>\n\t

Our findings are summarized in dozens of papers published in a variety of journals including Nature<\/em>, Nature Climate Change<\/em>, Nature Geoscience<\/em>, and the Proceedings of the National Academy of Sciences<\/em>.<\/p>\n\t

65<\/strong><\/p>\n\tYesterday’s high tide is today’s new normal<\/strong>
\nPiecuch, C. G., B. D. Hamlington, under review at AGU Adv.<\/em>, 2023.\n

submitted<\/h5>\n\t

64<\/strong><\/p>\n\tCompounding of sea-level processes during high-tide flooding along the U.S. coastline<\/strong>
\nLi, S., T. Wahl, C. Piecuch<\/strong>, S. Dangendorf, P. Thompson, L. Liu, under review at J. Geophys. Res.-Oceans, <\/em>2023.\n

submitted<\/h5>\n\t

63<\/strong><\/p>\n\tInfluence of Deep-Ocean Warming on Coastal Sea-Level Trends in the Gulf of Mexico<\/strong><\/a>
\nSteinberg, J. M., C. G. Piecuch<\/strong>, B. D. Hamlington, P. R. Thompson, S. Coats, under review at J. Geophys. Res.-Oceans<\/em>. 2023.\n

submitted<\/h5>\n\t

62<\/strong><\/p>\n\tRiver effects on sea-level rise in the R\u00edo de la Plata estuary during the past century<\/strong><\/a>
\nPiecuch, C. G.<\/strong>, Ocean Sci.<\/em>, 19(1), https:\/\/doi.org\/10.5194\/os-19-57-2023, 2023.\n\t

61<\/strong><\/p>\n\tThrough an ice sheet, darkly<\/strong><\/a>
\nPiecuch, C. G.<\/strong>, S. B. Das, Earth’s Future<\/em>, 10, https:\/\/doi.org\/10.1029\/2022EF003310, 2022.\n\t

60<\/strong><\/p>\n\tLow-frequency dynamic ocean response to barometric-pressure loading<\/strong><\/a>
\nPiecuch, C. G.<\/strong>, I. Fukumori, R. M. Ponte, M. Schindelegger, O. Wang, M. Zhao, J. Phys. Oceanogr.<\/em>, 52, https:\/\/doi.org\/10.1175\/JPO-D-22-0090.1, 2022.\n\t

59<\/strong><\/p>\n\tThe importance of non-tidal water-level variability for reconstructing Holocene relative sea level<\/strong><\/a>
\nKemp, A. C., T. A. Shaw, C. G. Piecuch<\/strong>, Quat. Sci. Rev.<\/em>, 290, https:\/\/doi.org\/10.1016\/j.quascirev.2022.107637, 2022.\n\t

58<\/strong><\/p>\n\tContributions of different sea-level processes to high-tide flooding along the U.S. coastline<\/strong><\/a>
\nLi. S., T. Wahl, A. Barroso, S. Coats, S. Dangendorf, A. R. Enr\u00edquez, F. W. Landerer, L. Liu, C. G. Piecuch<\/strong>, J. T. Reager, P. R. Thompson, J. Geophys. Res.-Oceans<\/em>, 127, https:\/\/doi.org\/10.1029\/2021JC018276, 2022.\n\t

57<\/strong><\/p>\n\tLocal and remote forcing of interannual sea-level variability at Nantucket Island<\/a><\/strong>
\nWang, O., T. Lee, C. G. Piecuch<\/strong>, I. Fukumori, I. Fenty, T. Frederikse, D. Menemenlis, R. Ponte, H. Zhang, J. Geophys. Res.-Oceans<\/em>, 127, https:\/\/doi.org\/10.1029\/2021JC018275, 2022.\n\t

56<\/strong><\/p>\n\tHigh-Tide Floods and Storm Surges During Atmospheric Rivers on the US West Coast<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, S. Coats, S. Dangendorf, F. W. Landerer, J. T. Reager, P. R. Thompson, T. Wahl, Geophys. Res. Lett.<\/em>, 49, https:\/\/doi.org\/10.1029\/2021GL096820, 2022.\n\t

55<\/strong><\/p>\n\tInfluence of Nonseasonal River Discharge on Sea Surface Salinity and Height<\/a><\/strong>
\nChandanpurkar, H., T. Lee, X. Wang, H. Zhang, S. Fournier, I. Fenty, I. Fukumori, D. Menemenlis, C. Piecuch<\/strong>, J. Reager, O. Wang, J. Worden, J. Adv. Model. Earth Syst., 13, https:\/\/doi.org\/10.1029\/2021MS002715, 2022.\n\t

54<\/strong><\/p>\n\tOcean mass, sterodynamic effects, and vertical land motion largely explain US coast relative sea level rise<\/a><\/strong>
\nHarvey, T. C., B. D. Hamlington, T. Frederikse, R. S. Nerem, C. G. Piecuch<\/strong>, W. C. Hammond, G. Blewitt, P. R. Thompson, D. P. S. Bekaert, F. W. Landerer, J. T. Reager, R. E. Kopp, I. Fenty, D. Trossman, J. Walker, C. Boening, Commun. Earth Environ.<\/em>, 2, 233, doi:10.1038\/s43247-021-00300-w, 2021.\n\t

53<\/strong><\/p>\n\tNorth American East Coast Sea Level Exhibits High Power and Spatiotemporal Complexity on Decadal Timescales<\/a><\/strong>
\nLittle, C. M., C. G. Piecuch<\/strong>, R. Ponte, Geophys. Res. Lett.<\/em>, 48, doi:10.1029\/2021GL093675, 2021.\n\t

52<\/strong><\/p>\n\tClimate did not drive Common Era Maldivian sea-level lowstands<\/a><\/strong>
\nPiecuch, C. G<\/strong>., A. C. Kemp, G. Gebbie, A. Meltzner, Nat. Geosci.<\/em>, 14, 273-275, doi:10.1038\/s41561-021-00731-2, 2021.\n\t

51<\/strong><\/p>\n\tIntraseasonal Sea-Level Variability in the Persian Gulf<\/a><\/strong>
\nPiecuch, C. G., <\/strong>I. Fukumori,R. M. Ponte, J. Phys. Oceanogr.<\/em>, 51, 1687-1704, doi:10.1175\/JPO-D-20-0296.1, 2021.\n\t

50<\/strong><\/p>\n\tMeridional Assymetry in Recent Decadal Sea-Level Trends in the Subtropical Pacific Ocean<\/a><\/strong>
\nSchloesser, P. R. Thompson, C. G. Piecuch<\/strong>, Geophys. Res. Lett.<\/em>, 48, doi:10.1029\/2020GL091959, 2021.\n\t

49<\/strong><\/p>\n\tLikely weakening of the Florida Current during the past century revealed by sea level observations<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, Nat. Commun.<\/em>, 11, 3973, doi:10.1038\/s41467-020-17761-w, 2020.\n\t

48<\/strong><\/p>\n\tOrigin of Interannual Variability in Global Mean Sea Level<\/a><\/strong>
\nHamlington, B. D., C. G. Piecuch<\/strong>, J. T. Reager, H. Chandanpurkar, T. Frederikse, R. S. Nerem, J. T. Fasullo, S.-H. Cheon, Proc. Natl. Acad. Sci. U.S.A.<\/em>, doi:10.1073\/pnas.1922190117, 2020.\n\t

47<\/strong><\/p>\n\tUnderstanding of Contemporary Regional Sea-Level Change and the Implications for the Future<\/a><\/strong>
\nHamlington, B. D., 50 others (including C. G. Piecuch<\/strong>), Rev. Geophys.<\/em>, 58, doi:10.1029\/2019RG000627, 2020.\n\t

46<\/strong><\/p>\n\tA Pre-Industrial Sea-Level Rise Hotspot Along the Atlantic Coast of North America<\/a><\/strong>
\nGehrels, W. R., S. Dangendorf, N. Barlow, M. Saher, A. Long, P. Woodworth, C. Piecuch<\/strong>, K. Berk, Geophys. Res. Lett.<\/em>, 47, doi:10.1029\/2019GL085814, 2020.\n\t

45<\/strong><\/p>\n\tDynamic Sea Level Variability due to Seasonal River Discharge: A Preliminary Global Ocean Model Study<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, R. Wadehra, Geophys. Res. Lett.<\/em>, 47, doi:10.1029\/2020GL086984, 2020.\n\t

44<\/strong><\/p>\n\tThe Mean State and Variability of the North Atlantic Circulation: A Perspective from Reanalyses<\/a><\/strong>
\nJackson, L., 18 others (including C. G. Piecuch<\/strong>), J. Geophys. Res.-Oceans<\/em>, 124, doi:10.1029\/2019JC015210, 2019.\n\t

43<\/strong><\/p>\n\tWhat Caused Recent Shifts in Tropical Pacific Sea-Level Trends?<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, P. R. Thompson, R. M. Ponte, M. A. Merrifield, B. D. Hamlington, J. Geophys. Res.-Oceans<\/em>, 124, doi:10.1029\/2019JC015339, 2019.\n\t

42<\/strong><\/p>\n\tThe Relationship between United States East Coast Sea Level and the Atlantic Meridional Overturning Circulation: A Review<\/a><\/strong>
\nLittle, C., A. Hu, C. Hughes, G. McCarthy, C. Piecuch<\/strong>, R. Ponte, M. Thomas, J. Geophys. Res.-Oceans<\/em>, 124, doi:10.1029\/2019JC015152, 2019.\n\t

41<\/strong><\/p>\n\tPersistent acceleration in global sea-level rise since the 1960s<\/a><\/strong>
\nDangendorf, S., C. Hay, F. M. Calafat, M. Marcos, C. G. Piecuch<\/strong>, K. Berk, J. Jensen, Nature Clim. Change<\/em>, 9, 705-710, doi:10.1038\/s41558-019-0531-8, 2019.\n\t

40<\/strong><\/p>\n\tHow is New England coastal sea level related to the Atlantic Meridional Overturning Circulation at 26\u00b0N?<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, Dangendorf, S., G. G. Gawarkiewicz, C. M. Little, R. M. Ponte, J. Yang, Geophys. Res. Lett.<\/em>, 46, 5351-5360, doi:10.1029\/2019GL083073, 2019.\n\t

39<\/strong><\/p>\n\tImpact of Continental Freshwater Runoff on Coastal Sea Level<\/a><\/strong>
\nDurand, F., C. Piecuch<\/strong>, M. Becker, F. Papa, S. V. Raju, J. U. Khan, R. M. Ponte, Surv. Geophys.<\/em>, 40(6), 1437-1466, doi:10.1007\/s10712-019-09536-w, 2019.\n\t

38<\/strong><\/p>\n\tThe Ability of Barotropic Models to Simulate Historical Sea Level Changes from Coastal Tide Gauges<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, F. M. Calafat, S. Dangendorf, G. Jord\u00e0, Surv. Geophys.<\/em>, 40(6), 1399-1435, doi:10.1007\/s10712-019-09537-9, 2019.\n\t

37<\/strong><\/p>\n\tThe Dominant Global Modes of Recent Internal Sea Level Variability<\/a><\/strong>
\nHamlington, B. D., S. H. Cheon, C. G. Piecuch<\/strong>, K. B. Karnauskas, P. R. Thompson, K.-Y. Kim, J. T. Reager, F. W. Landerer, T. Frederikse, J. Geophys. Res.-Oceans<\/em>, 124, 2750-2768, doi:10.1029\/2018JC014635, 2019.\n\t

36<\/strong><\/p>\n\tTowards Comprehensive Observing and Modeling Systems for Monitoring and Predicting Regional to Coastal Sea Level<\/a><\/strong>
\nPonte, R. M., 52 others (including C. G. Piecuch<\/strong>), Front. Mar. Sci.<\/em>, 6, 437, 2019.\n\t

35<\/strong><\/p>\n\tAtlantic Meridional Overturning Circulation: Observed Transports and Variability<\/a><\/strong>
\nFrajka-Williams, E., 39 others (including C. G. Piecuch<\/strong>), Front. Mar. Sci.<\/em>, 6, 260, 2019.\n\t

34<\/strong><\/p>\n\tPutting It All Together: Enhancing the Global Ocean and Climate Observing Systems With Complete Self-Consistent Ocean State and Parameter Estimates<\/strong><\/a>
\nHeimbach, P., 18 others (including C. G. Piecuch<\/strong>), Front. Mar. Sci.<\/em>, 6, 55, 2019.\n\t

33<\/strong><\/p>\n\tOrigin of spatial variation in United States East Coast sea level trends during 1900-2017<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, P. Huybers, C. C. Hay, A. C. Kemp, C. M. Little, J. X. Mitrovica, R. M. Ponte, M. P. Tingley, Nature<\/em>, 564, 400-404, doi:10.1038\/s41586-018-0787-6, 2018.\n\t

32<\/strong><\/p>\n\tGlobal Sea Level Budget 1993-Present<\/a><\/strong>
\nThe WCRP Global Sea Level Budget Group (Cazenave, A., 84 others, including C. G. Piecuch<\/strong>), Earth Syst. Sci. Data<\/em>, 10, 1551-1590, doi:10.5194\/essd-10-1551-2018, 2018.\n\t

31<\/strong><\/p>\n\tRiver-discharge effects on United States Atlantic and Gulf coast sea-level changes<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, K. Bittermann, A. C. Kemp, R. M. Ponte, C. M. Little, S. E. Engelhart, S. J. Lentz, Proc. Natl. Acad. Sci. U.S.A.<\/em>, 115, 30, 7729-7734, doi:10.1073\/pnas.1805428115, 2018.\n\t

30<\/strong><\/p>\n\tTide Gauge Records Reveal Improved Processing of Gravity Recovery and Climate Experiment Time-Variable Mass Solutions over the Coastal Ocean<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, F. W. Landerer, R. M. Ponte, Geophys. J. Int.<\/em>, 214, 2, 1401-1412, 2018.\n\t

29<\/strong><\/p>\n\tMechanisms Controlling Global Mean Sea Surface Temperature From a State Estimate<\/a><\/strong>
\nPonte, R. M., C. G. Piecuch<\/strong>, Geophys. Res. Lett.<\/em>, 45, 3221-3227, 2018.\n\t

28<\/strong><\/p>\n\tAccounting for Gravitational Attraction and Loading Effects from Land Ice on Absolute Sea Level<\/a><\/strong>
\nPonte, R. M., K. J. Quinn, C. G. Piecuch<\/strong>, J. Atmos. Ocean. Tech.<\/em>, 35(2), 405-410, 2018.\n\t

27<\/strong><\/p>\n\tObservation-Driven Estimation of the Spatial Variability of 20th Century Sea Level Rise<\/a><\/strong>
\nHamlington, B., A. Burgos, P. Thompson, F. Landerer, C. Piecuch<\/strong>, S. Adhikari, L. Caron, J. Reager, E. Ivins, J. Geophys. Res.-Oceans<\/em>., 123, doi:10.1002\/2017JC013486, 2018.\n\t

26<\/strong><\/p>\n\tMechanisms underlying recent decadal changes in subpolar North Atlantic Ocean heat content<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, R. M. Ponte, C. M. Little, M. W. Buckley, I. Fukumori, J. Geophys. Res.-Oceans<\/em>, 122, doi:10.1002\/2017JC012845, 2017.\n\t

25<\/strong><\/p>\n\tOn the relationship between the meridional overturning circulation, alongshore wind stress, and United States East Coast sea level in the Community Earth System Model Large Ensemble<\/a><\/strong>
\nLittle, C. M., C. G. Piecuch<\/strong>, R. M. Ponte, J. Geophys. Res.-Oceans<\/em>, 122, 4554-4568, doi:10.1002\/2017JC012713, 2017.\n\t

24<\/strong><\/p>\n\tChange of the Global Ocean Vertical Heat Transport over 1993-2010<\/a><\/strong>
\nLiang, X., C. G. Piecuch<\/strong>, R. M. Ponte, G. Forget, C. Wunsch, P. Heimbach, J. Climate<\/em>, 30, 14, 5319-5327, 2017.\n\t

23<\/strong><\/p>\n\tComparison of full and empirical Bayes approaches for inferring sea level changes from tide gauge data<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, P. Huybers, M. Tingley, J. Geophys. Res.-Oceans<\/em>, 122, doi:10.1002\/2016012506, 2017.\n\t

22<\/strong><\/p>\n\tCauses of the regional variability in observed sea level, sea surface temperature, and ocean colour over the period 1993-2011<\/a><\/strong>
\nMeyssignac, B., C. G. Piecuch<\/strong>, C. J. Merchant, M.-F. Racault, H. Palanisamy, C. McIntosh, S. Sathyendranath, R. Brewin, Surv. Geophys.<\/em>, 38: 187-215, doi:10.1007\/s10712-016-9383-1, 2017.\n\t

21<\/strong><\/p>\n\tEl Ni\u00f1o, La Ni\u00f1a, and the global sea level budget<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, K. J. Quinn, Ocean Sci.<\/em>, 12, 1165-1177, doi:10.5194\/os-2016-66, 2016.\n\t

20<\/strong><\/p>\n\tAir pressure effects on sea level changes during the Twentieth Century<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, P. R. Thompson, K. A. Donohue, J. Geophys. Res.-Oceans<\/em>, 121, 7917-7930, doi:10.1002\/2016JC012131, 2016.\n\t

19<\/strong><\/p>\n\tForcing of recent decadal variability in the Equatorial and North Indian Ocean<\/a><\/strong>
\nThompson, P. R., C. G. Piecuch<\/strong>, M. A. Merrifield, J. McCreary, E. Firing, J. Geophys. Res.-Oceans<\/em>, 121, 6762-6778, doi:10.1002\/2016JC012132, 2016.\n\t

18<\/strong><\/p>\n\tAnnual Sea Level Changes on the North American Northeast Coast: Influence of Local Winds and Barotropic Motions<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, S. Dangendorf, R. M. Ponte, M. Marcos, J. Climate<\/em>, 29, 13, 4801-4816, 2016.\n\t

17<\/strong><\/p>\n\tQuantifying Greenland freshwater flux underestimates in climate models<\/a><\/strong>
\nLittle, C. M., C. G. Piecuch<\/strong>, A. H. Chaudhuri, Geophys. Res. Lett.<\/em>, 43, 5370-5377, doi:10.1002\/2016GL068878, 2016.\n\t

16<\/strong><\/p>\n\tSensitivity of contemporary sea level trends in a global ocean state estimate to effects of geothermal fluxes<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, P. Heimbach, R. M. Ponte, G. Forget, Ocean Model.<\/em>, 96, 214-220, doi:10.1016\/j.ocemod.2015.10.008, 2015.\n\t

15<\/strong><\/p>\n\tInverted barometer contributions to recent sea level changes along the northeast coast of North America<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, R. M. Ponte, Geophys. Res. Lett.<\/em>, 42, 5918-5925, doi:10.1002\/2015GL064580, 2015.\n\t

14<\/strong><\/p>\n\tBottom-pressure signature of annual baroclinic Rossby waves in the northeast tropical Pacific Ocean<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, J. Geophys. Res.-Oceans<\/em>, 120, 2449-2459, doi:10.1002\/2014JC010667, 2015.\n\t

13<\/strong><\/p>\n\tVertical Structure of Ocean Pressure Variations with Application to Satellite-Gravimetric Observations<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, I. Fukumori, R. M. Ponte, O. Wang, J. Atmos. Ocean. Tech.<\/em>, 32, 3, 603-613, 2015.\n\t

12<\/strong><\/p>\n\tA wind-driven nonseasonal barotropic fluctuation of the Canadian inland seas<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, R. M. Ponte, Ocean Sci.<\/em>, 11, 175-185, 2015.\n\t

11<\/strong><\/p>\n\tNonseasonal mass fluctuations in the midlatitude North Atlantic Ocean<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, R. M. Ponte, Geophys. Res. Lett.<\/em>, 41, 4261-4269, 2014.\n\t

10<\/strong><\/p>\n\tAnnual Cycle in Southern Tropical Indian Ocean Bottom Pressure<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, R. M. Ponte, J. Phys. Oceanogr.<\/em>, 44(6), 1605-1613, 2014.\n\t

9<\/strong><\/p>\n\tInterannual Bottom Pressure Signals in the Australian-Antarctic and Bellingshausen Basins<\/a><\/strong>
\nPonte, R. M., C. G. Piecuch<\/strong>, J. Phys. Oceanogr.<\/em>, 44(5), 1456-1465, 2014.\n\t

8<\/strong><\/p>\n\tMechanisms of Global-Mean Steric Sea Level Change<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, R. M. Ponte, J. Climate<\/em>, 27(2), 824-834, 2014.\n\t

7<\/strong><\/p>\n\tDynamics of satellite-derived interannual ocean bottom pressure variability in the western tropical North Pacific<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, J. Geophys. Res.<\/em>, 118, 5117-5128, doi:10.1002\/jgrc.20374, 2013.\n\t

6<\/strong><\/p>\n\tSatellite-derived interannual ocean bottom pressure variability and its relation to sea level<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, K. J. Quinn, R. M. Ponte, Geophys. Res. Lett.<\/em>, 40, 3106-3110, doi:10.1002\/grl.50549, 2013.\n\t

5<\/strong><\/p>\n\tBuoyancy-Driven Interannual Sea Level Changes in the Tropical South Atlantic<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, R. M. Ponte, J. Phys. Oceanogr.<\/em>, 43(3), 533-547, 2013.\n\t

4<\/strong><\/p>\n\tQuantifying dispersal and connectivity of surface waters using observational Lagrangian measurements<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, T. A. Rynearson, J. Atmos. Ocean. Tech.<\/em>, 29(8), 1127-1138, 2012.\n\t

3<\/strong><\/p>\n\tBuoyancy-driven interannual sea level changes in the southeast tropical Pacific<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, R. M. Ponte, Geophys. Res. Lett.<\/em>, 39, L05607, doi:10.1029\/2011GL051130, 2012.\n\t

2<\/strong><\/p>\n\tImportance of circulation changes to Atlantic heat storage rates on seasonal and interannual timescales<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, R. M. Ponte, J. Climate<\/em>, 25(1), 350-362, 2012.\n\t

1<\/strong><\/p>\n\tMechanisms of interannual steric sea level variability<\/a><\/strong>
\nPiecuch, C. G.<\/strong>, R. M. Ponte, Geophys. Res. Lett.<\/em>, 38, L15605, doi:10.1029\/2011GL048440, 2011.\n\n","protected":false},"excerpt":{"rendered":"

PAPERS River-discharge effects on United States Atlantic and Gulf coast sea-level changes Origin of spatial variation in US East Coast sea-level trends during 1900-2017 Climate did not drive Common Era Maldivian sea-level lowstands Persistent acceleration in global sea-level rise since the 1960s Our findings are summarized in dozens of papers published in a variety of…<\/p>\n","protected":false},"author":14,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":[],"_links":{"self":[{"href":"https:\/\/www2.whoi.edu\/site\/piecuch\/wp-json\/wp\/v2\/pages\/23"}],"collection":[{"href":"https:\/\/www2.whoi.edu\/site\/piecuch\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/www2.whoi.edu\/site\/piecuch\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/www2.whoi.edu\/site\/piecuch\/wp-json\/wp\/v2\/users\/14"}],"replies":[{"embeddable":true,"href":"https:\/\/www2.whoi.edu\/site\/piecuch\/wp-json\/wp\/v2\/comments?post=23"}],"version-history":[{"count":3,"href":"https:\/\/www2.whoi.edu\/site\/piecuch\/wp-json\/wp\/v2\/pages\/23\/revisions"}],"predecessor-version":[{"id":858,"href":"https:\/\/www2.whoi.edu\/site\/piecuch\/wp-json\/wp\/v2\/pages\/23\/revisions\/858"}],"wp:attachment":[{"href":"https:\/\/www2.whoi.edu\/site\/piecuch\/wp-json\/wp\/v2\/media?parent=23"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}