{"id":27,"date":"2017-11-01T22:29:59","date_gmt":"2017-11-02T02:29:59","guid":{"rendered":"https:\/\/www2.whoi.edu\/staff\/template-blue-prepop\/?page_id=27"},"modified":"2025-12-31T20:01:43","modified_gmt":"2026-01-01T01:01:43","slug":"publications","status":"publish","type":"page","link":"https:\/\/www2.whoi.edu\/staff\/hsjiang\/publications\/","title":{"rendered":"Publications"},"content":{"rendered":"\n\n\t

PAPERS IN REFEREED JOURNALS<\/strong> (* denotes a student or postdoc as 1st author.)<\/h3>\n[76] *Jiang, X., Bai, X., Liu, H.-Y., Yan, Y. and Jiang, H.<\/strong> (2026) Variations in low-level temperature inversions over the marginal ice zone during cyclone passing: effects of abrupt sea ice transitions. Journal of Geophysical Research: Atmospheres<\/em> (in press).<\/p>\n[75] Zhu, Z., He, X., Jiang, H.<\/strong> and Liu, Q.-X. (2025) Turbulent mixing through aggregation-driven bioconvection in Effrenium voratum<\/em>. Physics of Fluids<\/em>, 37, 075128, doi:10.1063\/5.0268880.<\/p>\n[74] Johnson, M. D., Hammar, K., Beaudoin, D., Jiang, H.<\/strong> and V\u010fa\u010dn\u00fd, P. (2025) High grazing rates of marine Askenasia<\/em> cf. stellaris<\/em> on Mesodinium rubrum<\/em> and insights into its taxonomic status. Journal of Eukaryotic Microbiology<\/em>, 72, e70014, doi:10.1111\/jeu.70014.<\/p>\n[73] Jiang,<\/strong>\u00a0H.<\/strong> and Buskey, E. J. (2024) Relating ciliary propulsion morphology and flow to particle acquisition in marine planktonic ciliates II: The oligotrich ciliate Strombidium capitatum<\/em>. Journal of Plankton Research<\/em>, 46, doi:10.1093\/plankt\/fbae011.<\/p>\n[72] Jiang,\u00a0H.<\/strong> and Buskey, E. J. (2024) Relating ciliary propulsion morphology and flow to particle acquisition in marine planktonic ciliates I: The tintinnid ciliate Amphorides quadrilineata<\/em>. Journal of Plankton Research<\/em>, 46, doi:10.1093\/plankt\/fbae012.<\/p>\n[71] Cenedese, C., Huang, S.-D., Jiang,\u00a0H.<\/strong>, Yuan, Y. and Zhou, S.-Q. (2024) Editorial: Multi-scale fluid physics in oceanic flows: new insights from laboratory experiments and numerical simulations. Frontiers in Marine Science<\/em>, 10, 1361265, doi:10.3389\/fmars.2023.1361265.<\/p>\n[70] Jiang, H.<\/strong> and Strickler, J. R. (2024) An invited reply to: A comment on: ‘The swim-and-sink behaviour of copepods: a revisit to mechanical power requirement and a new hypothesis on function’ (2023), by Jiang. Royal Society Open Science<\/em>, 11, 231753, doi:10.1098\/rsos.231753.<\/p>\n[69] Jiang, H.<\/strong> (2023) The swim-and-sink behavior of copepods: a revisit to mechanical power requirement and a new hypothesis on function. Royal Society Open Science<\/em>, 10, 230347, doi:10.1098\/rsos.230347.<\/p>\n[68] Jiang, H.<\/strong> and Pechenik, J. A. (2022) Hydrodynamic role of substrate attachment in shaping the suspension-feeding current created by the marine gastropod Crepidula fornicata<\/em>. Invertebrate Biology<\/em>, 141, e12383, doi:10.1111\/ivb.12383.<\/p>\n[67] Murphy, C. T., Marx, M., Martin, W. N.,\u00a0Jiang, H.<\/b>, Lapseritis, J. M., French, A. N., Simmons, N. B. and Moore, M. J. (2022) Feeling for food: can rostro-mental hair arrays sense hydrodynamic cues for foraging North Atlantic right whales?\u00a0The Anatomical Record<\/i>, 305, 577-591, doi:10.1002\/ar.24858.<\/p>\n[66]\u00a0Jiang, H.<\/strong>\u00a0(2021) Numerical simulation of self-propelled steady jet propulsion at intermediate Reynolds numbers: effects of orifice size on animal jet propulsion.\u00a0Fluids,\u00a0<\/em>6, 230, doi:10.3390\/fluids6060230.<\/p>\n[65]\u00a0Jiang, H.<\/b> and Johnson, M. D. (2021) Swimming behavior of cryptophyte prey affects prey preference of the ambush-feeding ciliate Mesodinium rubrum<\/i>. Aquatic Microbial Ecology,\u00a0<\/i>86, 169-184.<\/p>\n[64] Nayak, A. R., Jiang, H.<\/strong>, Byron, M. L., Sullivan, J. M., McFarland, M. N. and Murphy, D. W. (2021) Editorial: Small scale spatial and temporal patterns in particles, plankton, and other organisms. Frontiers in Marine Science,\u00a0<\/em>8, 669530, doi:10.3389\/fmars.2021.669530.<\/p>\n[63]\u00a0*Tyrell, A. S., Jiang, H.<\/b> and Fisher, N. S. (2021) Effects of seawater viscosity and temperature on the movement of the marine dinoflagellate\u00a0Prorocentrum minimum<\/i>. Aquatic Microbial Ecology,\u00a0<\/i>86, 21-28.<\/p>\n[62]\u00a0Jiang, H.<\/b>, Costello, J. H. and Colin, S. P. (2021) Fluid dynamics and efficiency of colonial swimming via multijet propulsion at intermediate Reynolds numbers. Physical Review Fluids,\u00a0<\/i>6, 013103, doi:10.1103\/PhysRevFluids.6.013103.<\/p>\n[61]\u00a0Alkhafaji, A. A., Selim, O. M., Amano, R. S., Strickler, J. R., Hinow, P., Jiang, H.<\/b>, Sikkel, P. C., and Kohls, N. (2021) Mass transfer performance of a marine zooplankton olfactometer. Journal of Energy Resources Technology<\/i>, 143, 112102.<\/p>\n[60] Pratt, L. J., Albright, E. J., Rypina, I. and Jiang, H.<\/strong> (2020) Eulerian and Lagrangian comparison of wind jets in the Tokar Gap region. Fluids<\/i>, 5, 193, doi:10.3390\/fluids5040193.<\/p>\n[59] Jiang, H.<\/b> (2020) An elastic collision model for impulsive jumping by small planktonic organisms. Fluids<\/i>, 5, 154, doi:10.3390\/fluids5030154.\n[58] *Tyrell, A. S., Jiang, H.<\/b> and Fisher, N. S. (2020) Copepod feeding strategy determines response to seawater viscosity: videography study of two calanoid copepod species. Journal of Experimental Biology<\/i>, 223, jeb220830, doi:10.1242\/jeb.220830.\n[57] Jiang, H.<\/b> and Paffenh\u00f6fer G.-A. (2020) Vortical feeding currents in nauplii of the calanoid copepod Eucalanus pileatus<\/i>. Marine Ecology Progress Series<\/i>, 638, 51-63.\n[56]\u00a0Jiang, H.<\/b>\u00a0and Edson, J. B. (2020) Characterizing marine atmospheric boundary layer to support offshore wind energy research. J. Phys.: Conf. Ser.<\/i>, 1452, 012027, doi:10.1088\/1742-6596\/1452\/1\/012027.\n[55] Davis, S. R., Farrar, J. T., Weller, R. A., Jiang, H.<\/b> and Pratt, L. J. (2019) The land-sea breeze of the Red Sea: Observations, simulations, and relationships to regional moisture transport. Journal of Geophysical Research: Atmospheres<\/i>, 124, 13803-13825, https:\/\/doi.org\/10.1029\/2019JD031007.\n[54] Giuffre, C., Hinow, P., Jiang, H.<\/b> and Strickler, J. R. (2019) Oscillations in the near-field feeding current of a calanoid copepod are useful for particle sensing. Scientific Reports<\/i>, 9, 17742, doi:10.1038\/s41598-019-54264-1.\n[53] Carrillo, A., Van Le, D., Byron, M., Jiang, H.<\/strong> and McHenry, M. (2019) Canal neuromasts enhance foraging in zebrafish (Danio rerio<\/em>). Bioinspiration and Biomimetics<\/em>, 14, 035003, https:\/\/doi.org\/10.1088\/1748-3190\/ab0eb5.<\/p>\n[52] Zhao, L., Zhang, W., He, Z., Tan, L. and Jiang, H.<\/b> (2019) The process of mass transport for a buoyant plume in linearly stratified environment. Journal of Shanghai Jiao Tong University<\/i>, 53, 473-479 (in Chinese with an abstract in English).<\/p>\n[51] Lou, Y., He, Z., Jiang, H.<\/strong> and Han, X. (2019) Numerical simulation of two coalescing turbulent forced plumes in linearly stratified fluids. Physics of Fluids<\/em>, 31, 037111, doi:10.1063\/1.5087534.<\/p>\n[50] Uttieri, M., Nihongi, A., Hinow, P., Motschman, J., Jiang, H.<\/strong>, Alcaraz, M. and Strickler, J. R. (2019) Copepod manipulation of oil droplet size distribution. Scientific Reports<\/em>, 9, 547, doi:10.1038\/s41598-018-37020-9.<\/p>\n[49]\u00a0*Zhang, X., Lin, J. and Jiang, H.<\/strong> (2018) Time-dependent variations in vertical fluxes of hydrothermal plumes at mid-ocean ridges. Marine Geophysical Research<\/em>, https:\/\/doi.org\/10.1007\/s11001-018-9364-5.<\/p>\n[48]\u00a0He, Z., *Zhang, W., Jiang, H.<\/strong>, Zhao, L. and Han, X. (2018) Dynamic interaction and mixing of two turbulent forced plumes in linearly stratified ambience. Journal of Hydraulic Engineering<\/em>, 144(12), 04018072.<\/p>\n[47] Jiang, H.<\/strong>, Kulis, D. M., Brosnahan, M. L. and Anderson, D. M. (2018)\u00a0Behavioral and mechanistic characteristics of the predator-prey interaction between the dinoflagellate Dinophysis acuminata<\/em> and the ciliate Mesodinium rubrum<\/em>. Harmful Algae<\/em>, 77, 43-54.<\/p>\n[46] Du Clos, K. and Jiang, H.<\/strong> (2018) Overcoming hydrodynamic challenges in suspension feeding by juvenile Mya arenaria<\/em> clams. Journal of the Royal Society Interface<\/em>,\u00a015, 20170755, http:\/\/dx.doi.org\/10.1098\/rsif.2017.0755.<\/p>\n[45] *Zhang, W., He, Z. and Jiang, H.<\/strong> (2017) Scaling for turbulent viscosity of buoyant plumes in stratified fluids: PIV measurement with implications for submarine hydrothermal plume turbulence. Deep-Sea Research Part I: Oceanographic Research Papers<\/em>, 129, 89-98.<\/p>\n[44] Jiang, H.<\/strong> and Johnson, M. D. (2017) Jumping and overcoming diffusion limitation of nutrient uptake in the photosynthetic ciliate Mesodinium rubrum<\/em>. Limnology and Oceanography<\/em>, 62, 421-436.<\/p>\n[43] *Zhang, W., Zhao, L., He, Z., Lin, T., Tan, L. and Jiang, H.<\/strong> (2016) Characteristics of plumes in linearly stratified salt-water. Advances in Water Science<\/em>, 27, 602-608 (in Chinese with an abstract in English).<\/p>\n[42] Paffenh\u00f6fer, G.-A. and Jiang, H.<\/strong> (2016) Comment: On phytoplankton perception by calanoid copepods. Limnology and Oceanography<\/em>, 61, 1163-1168.<\/p>\n[41] Gemmell, B. J., Jiang, H.<\/strong> and Buskey, E. J. (2015) A tale of the ciliate tail: investigation into the adaptive significance of this sub-cellular structure. Proceedings of the Royal Society B<\/em>, 282, 20150770, https:\/\/doi.org\/10.1098\/rspb.2015.0770.<\/p>\n[40] *Katija, K., Colin, S. P., Costello, J. H. and Jiang, H.<\/strong> (2015) Ontogenetic propulsive transitions by medusae Sarsia tubulosa<\/em>. Journal of Experimental Biology<\/em>, 218, 2333-2343.<\/p>\n[39] *Davis, S. R., Pratt, L. J. and Jiang, H.<\/strong> (2015) The Tokar Gap jet: regional circulation, diurnal variability and moisture transport based on numerical simulations. Journal of Climate<\/em>, 28, 5885-5907.<\/p>\n[38] Reed, D. C., Breier, J. A., Jiang, H.<\/strong>, Anantharaman, K., Klausmeier, C. A., Toner, B. M., Hancock, C., Speer, K., Thurnherr, A. M. and Dick, G. J. (2015) Predicting the response of the deep-ocean microbiome to geochemical perturbations by hydrothermal vents. The ISME Journal<\/em>, 9, 1857-1869.<\/p>\n[37] Stewart, W. J., Nair, A., Jiang, H.<\/strong> and McHenry, M. J. (2014) Prey fish escape by sensing the bow wave of a predator. Journal of Experimental Biology<\/em>, 217, 4328-4336.<\/p>\n[36] Jiang, H.<\/strong> and Breier, J. A. (2014) Physical controls on mixing and transport within rising submarine hydrothermal plumes: a numerical simulation study. Deep-Sea Research Part I: Oceanographic Research Papers<\/em>, 92, 41-55.<\/p>\n[35] Ki\u00f8rboe, T., Jiang, H.<\/strong>, Gon\u00e7alves, R. J., Nielsen, L. T. and Wadhwa, N. (2014) Flow disturbances generated by feeding and swimming zooplankton. Proceedings of the National Academy of Sciences of the USA<\/em>, 111, 11738-11743.<\/p>\n[34] Gemmell, B. J., Jiang, H.<\/strong> and Buskey, E. J. (2014) A new approach to micro-scale particle image velocimetry (\u00b5PIV) for quantifying flows around free-swimming zooplankton. Journal of Plankton Research<\/em>, 36, 1396-1401.<\/p>\n[33] Chen, C., Li, R., Pratt, L., Limeburner, R., Beardsley, R.C., Bower, A., Jiang, H.<\/strong>, Abualnaja, Y., Xu, Q., Lin, H., Liu, X., Lan, J. and Kim, T. (2014) Process modeling studies of physical mechanisms of the formation of an anticyclonic eddy in the central Red Sea. Journal of Geophysical Research: Oceans<\/em>, 119, 1445-1464.<\/p>\n[32] *Chan, K. Y. K., Jiang, H.<\/strong> and Padilla, D. K. (2013) Swimming speed of larval snail does not correlate with size and ciliary beat frequency. PLoS ONE<\/em> 8(12): e82764. doi:10.1371\/journal.pone.0082764.<\/p>\n[31] *Katija, K. and Jiang, H.<\/strong> (2013) Swimming by medusae Sarsia tubulosa<\/em> in the viscous vortex ring limit. Limnology and Oceanography: Fluids and Environments<\/em>, 3, 103-118.<\/p>\n[30] Ralston, D. K., Jiang, H.<\/strong> and Farrar, J. T. (2013) Waves in the Red Sea: response to monsoonal and mountain gap winds. Continental Shelf Research<\/em>, 65, 1-13.<\/p>\n[29] Ki\u00f8rboe, T. and Jiang, H.<\/strong> (2013) To eat and not be eaten: optimal foraging behavior in suspension feeding copepods. Journal of the Royal Society Interface<\/em>, 10, no. 78 20120693, doi:10.1098\/rsif.2012.0693.<\/p>\n[28] Gemmell, B. J., Jiang, H.<\/strong>, Strickler, J. R. and Buskey, E. J. (2012) Plankton reach new heights in effort to avoid predators. Proceedings of the Royal Society B<\/em>, 279, 2786-2792.<\/p>\n[27] Jiang, H.<\/strong> (2011) Why does the jumping ciliate Mesodinium rubrum<\/em> possess equatorially located propulsive ciliary belt? Journal of Plankton Research<\/em>, 33, 998-1011 (Featured article).<\/p>\n[26] Jiang, H.<\/strong> and Ki\u00f8rboe, T. (2011) The fluid dynamics of swimming by jumping in copepods. Journal of the Royal Society Interface<\/em>, 8, 1090-1103.<\/p>\n[25] Jiang, H.<\/strong> and Ki\u00f8rboe, T. (2011) Propulsion efficiency and imposed flow fields of a copepod jump. Journal of Experimental Biology<\/em>, 214, 476-486.<\/p>\n[24] Cardenas, M. B. and Jiang, H.<\/strong> (2011) Wave-driven porewater and solute circulation through rippled elastic sediment under highly transient forcing. Limnology and Oceanography: Fluids and Environments<\/em>, 1, 23-37.<\/p>\n[23] Ki\u00f8rboe, T., Jiang, H.<\/strong> and Colin, S. P. (2010) Danger of zooplankton feeding: the fluid signal generated by ambush-feeding copepods. Proceedings of the Royal Society B<\/em>, 277, 3229-3237.<\/p>\n[22] Jiang, H.<\/strong>, Farrar, J. T., Beardsley, R. C., Chen, R. and Chen, C. (2009) Zonal surface wind jets across the Red Sea due to mountain gap forcing along both sides of the Red Sea. Geophysical Research Letters<\/em>, 36, L19605, doi:10.1029\/2009GL040008.<\/p>\n[21] *Rapo, M. A., Jiang, H.<\/strong>, Grosenbaugh, M. A. and Coombs, S. (2009) Using computational fluid dynamics to calculate the stimulus to the lateral line of a fish in still-water. Journal of Experimental Biology<\/em>, 212, 1494-1505.<\/p>\n[20] Jiang, H.<\/strong> and Paffenh\u00f6fer G.-A. (2008) Hydrodynamic signal perception by the copepod Oithona plumifera<\/em>. Marine Ecology Progress Series<\/em>, 373, 37-52.<\/p>\n[19] Cardenas, M. B., Cook, P. L. M., Jiang, H.<\/strong> and Traykovski, P. (2008) Constraining denitri\ufb01cation in permeable wave-in\ufb02uenced marine sediment using linked hydrodynamic and biogeochemical modeling. Earth and Planetary Science Letters<\/em>, 275, 127-137.<\/p>\n[18] Jiang, H.<\/strong> and Strickler, J. R. (2007) Copepod flow modes and modulation: a modelling study of the water currents produced by an unsteadily swimming copepod. Philosophical Transactions of the Royal Society B: Biological Sciences<\/em>, 362, 1959-1971.<\/p>\n[17] Jiang, H.<\/strong> and Grosenbaugh, M. A. (2006) Numerical simulation of vortex ring formation in the presence of background flow with implications for squid propulsion. Theoretical and Computational Fluid Dynamics<\/em>, 20, 103-123.<\/p>\n[16] Jiang, H.<\/strong> and Strickler, J. R. (2005) Mass density contrast in relation to the feeding currents in calanoid copepods. Journal of Plankton Research<\/em>, 27, 1003-1012.<\/p>\n[15] Jiang, H.<\/strong> and Osborn, T. R. (2004) Hydrodynamics of copepods: a review. Surveys in Geophysics<\/em>, 25, 339-370.<\/p>\n[14] Jiang, H.<\/strong> and Paffenh\u00f6fer, G.-A. (2004) Relation of behavior of copepod juveniles to potential predation by omnivorous copepods: an empirical-modeling study. Marine Ecology Progress Series<\/em>, 278, 225-239.<\/p>\n[13] Jiang, H.<\/strong>, Osborn, T. R. and Meneveau, C. (2002) Chemoreception and the deformation of the active space in freely swimming copepods: a numerical study. Journal of Plankton Research<\/em>, 24, 495-510.<\/p>\n[12] Jiang, H.<\/strong>, Osborn, T. R. and Meneveau, C. (2002) Hydrodynamic interaction between two copepods: a numerical study. Journal of Plankton Research<\/em>, 24, 235-253.<\/p>\n[11] Jiang, H.<\/strong>, Meneveau, C. and Osborn, T. R. (2002) The flow field around a freely swimming copepod in steady motion: Part II numerical simulation. Journal of Plankton Research<\/em>, 24, 191-213.<\/p>\n[10] Jiang, H.<\/strong>, Osborn, T. R. and Meneveau, C. (2002) The flow field around a freely swimming copepod in steady motion: Part I theoretical analysis. Journal of Plankton Research<\/em>, 24, 167-189.<\/p>\n[9] Jiang, H.<\/strong>, Meneveau, C. and Osborn, T. R. (1999) Numerical study of the feeding current around a copepod. Journal of Plankton Research<\/em>, 21, 1391-1421.<\/p>\n[8] L\u00fc, K. and Jiang, H.<\/strong> (2002) Effects of upper and low-level jets and condensation process of moisture on evolution of occluded frontal circulation. Acta Meteorologica Sinica<\/em>, 60, 660-667 (in Chinese with an abstract in English).<\/p>\n[7] Jiang, H.<\/strong> and L\u00fc, K. (2000) Occluded frontal circulation in upper and lower-level jets. Plateau Meteorology<\/em>, 19, 265-276 (in Chinese with an abstract in English).<\/p>\n[6] L\u00fc, K. and Jiang, H.<\/strong> (1999) Influences of upper and low-level jets and condensation process of moisture on evolution of warm front circulation. Acta Meteorologica Sinica<\/em>, 57, 681-693 (in Chinese with an abstract in English).<\/p>\n[5] Jiang, H.<\/strong> and L\u00fc, K. (1998) The nonlinear long-waves excited by topography in a shear flow. Plateau Meteorology<\/em>, 17, 231-244 (in Chinese with an abstract in English).<\/p>\n[4] L\u00fc, K. and Jiang, H.<\/strong> (1998) Influences of interaction of external source with solitary wave on blocking. Journal of Applied Meteorological Science<\/em>, 9, 431-440 (in Chinese with an abstract in English).<\/p>\n[3] L\u00fc, K. and Jiang, H.<\/strong> (1998) Localized thermal forcing and formation of large amplitude quasi-steady disturbances. Acta Meteorologica Sinica<\/em>, 56, 424-435 (in Chinese with an abstract in English).<\/p>\n[2] L\u00fc, K. and Jiang, H.<\/b>(1997) Interaction of topography with solitary Rossby waves in a near-resonant flow. Journal of Meteorological Research<\/em>, 11, 204-215.<\/p>\n[1] L\u00fc, K. and Jiang, H.<\/strong> (1996) Forced solitary Rossby waves in a near-resonant flow in the presence of topography. Acta Meteorologica Sinica<\/em>, 54, 142-153 (in Chinese with an abstract in English).<\/p>\n

BOOK CHAPTERS\u00a0AND CONFERENCE PAPERS (* denotes a student or postdoc as 1st<\/sup> author):<\/b><\/strong><\/h3>\n*Zhang, W., He, Z., Zhao, L. and Jiang, H.<\/b> (2016) Assessing the local isotropy of a turbulent plume in linearly stratified saltwater using PIV data. Paper submitted to 20th<\/sup> Australasian Fluid Mechanics Conference<\/i>, Perth, Australia, 5-8 December 2016.\n

Jiang, H.<\/strong> (2004) Numerical simulation of the flow field at the scale size of an individual copepod. In Handbook of scaling methods in aquatic ecology: measurement, analysis, simulation, Seuront, L.J. and Strutton, P.G., Eds., CRC Press, 479-491.<\/p>\n\n","protected":false},"excerpt":{"rendered":"

PAPERS IN REFEREED JOURNALS (* denotes a student or postdoc as 1st author.) [76] *Jiang, X., Bai, X., Liu, H.-Y., Yan, Y. and Jiang, H. (2026) Variations in low-level temperature inversions over the marginal ice zone during cyclone passing: effects of abrupt sea ice transitions. Journal of Geophysical Research: Atmospheres (in press). [75] Zhu, Z.,…<\/p>\n","protected":false},"author":136,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":[],"_links":{"self":[{"href":"https:\/\/www2.whoi.edu\/staff\/hsjiang\/wp-json\/wp\/v2\/pages\/27"}],"collection":[{"href":"https:\/\/www2.whoi.edu\/staff\/hsjiang\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/www2.whoi.edu\/staff\/hsjiang\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/www2.whoi.edu\/staff\/hsjiang\/wp-json\/wp\/v2\/users\/136"}],"replies":[{"embeddable":true,"href":"https:\/\/www2.whoi.edu\/staff\/hsjiang\/wp-json\/wp\/v2\/comments?post=27"}],"version-history":[{"count":4,"href":"https:\/\/www2.whoi.edu\/staff\/hsjiang\/wp-json\/wp\/v2\/pages\/27\/revisions"}],"predecessor-version":[{"id":368,"href":"https:\/\/www2.whoi.edu\/staff\/hsjiang\/wp-json\/wp\/v2\/pages\/27\/revisions\/368"}],"wp:attachment":[{"href":"https:\/\/www2.whoi.edu\/staff\/hsjiang\/wp-json\/wp\/v2\/media?parent=27"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}