REFERENCES

1. United Nations Environment Programme. Blue carbon: the role of healthy oceans in binding carbon. 2009. Available from: https://wedocs.unep.org/handle/20.500.11822/7772 [Last accessed on 28 Jul 2023].

2. Donato DC, Kauffman JB, Murdiyarso D, Kurnianto S, Stidham M, Kanninen M. Mangroves among the most carbon-rich forests in the tropics. Nat Geosci 2011;4:293-97.

3. Alongi DM. Carbon sequestration in mangrove forests. Carbon Manag 2012;3:313-22.

4. Alongi DM. Carbon cycling and storage in mangrove forests. Ann Rev Mar Sci 2014;6:195-219.

5. Kauffman JB, Adame MF, Arifanti VB, et al. Total ecosystem carbon stocks of mangroves across broad global environmental and physical gradients. Ecol Monogr 2020;90:e01405.

6. Bird E. Mangroves, geomorphology. In: Schwartz ML, editor. Encyclopedia of coastal science. Dordrecht: Springer; 2005. pp. 611-3.

7. Ellison JC, Stoddart DR. Mangrove ecosystem collapse during predicted sea-level rise: holocene analogues and implications. J Coast Res 1991;7:151-65. Available from: https://www.jstor.org/stable/4297812 [Last accessed on 31 Jul 2023].

8. Ward RD, Friess DA, Day RH, Mackenzie RA. Impacts of climate change on mangrove ecosystems: a region by region overview. Ecosyst Health Sustain 2016;2:e01211.

9. Fujimoto K, Miyagi T, Kikuchi T, Kawana T. Mangrove habitat formation and response to Holocene sea-level changes on Kosrae Island, Micronesia. Mangr Salt Marsh 1996;1:47-57.

10. Fujimoto K, Ono K, Tabuchi R, Lihpai S. Findings from long-term monitoring studies of Micronesian mangrove forests with special reference to carbon sequestration and sea-level rise. Ecol Res 2023;38:494-507.

11. Twilley RR, Chen RH, Hargis T. Carbon sinks in mangroves and their implications to carbon budget of tropical coastal ecosystems. Water Air Soil Pollut 1992;64:265-88.

12. Bouillon S, Borges AV, Castañeda-moya E, et al. Mangrove production and carbon sinks: a revision of global budget estimates. Global Biogeochem Cycles 2008;22:n/a.

13. Komiyama A, Ong JE, Poungparn S. Allometry, biomass, and productivity of mangrove forests: a review. Aquat Bot 2008;89:128-37.

14. Kristensen E, Bouillon S, Dittmar T, Marchand C. Organic carbon dynamics in mangrove ecosystems: a review. Aquat Bot 2008;89:201-19.

15. Putz F, Chan HT. Tree growth, dynamics, and productivity in a mature mangrove forest in Malaysia. For Ecol Manag 1986;17:211-30.

16. MacLean CD, Whitesell CD, Cole TG, McDuffie KE. Timber resources of Kosrae, Pohnpei, Truk, and Yap, Federated States of Micronesia. resource bulletin. Pacific Southwest Forest and Range Experiment Station, forest service, U.S. Department of Agriculture. 1988. Available from: https://archive.org/details/IND88026751/page/n17/mode/2up [Last accessed on 31 Jul 2023].

17. Komiyama A, Moriya H, Prawiroatmodjo S, Toma T, Ogino K. Forest primary productivity. In: Ogino K, Chihara M, editors. Biological system of mangrove. Japan: Ehime University; 1988: pp. 97-117.

18. Clough BF, Scott K. Allometric relationships for estimating above-ground biomass in six mangrove species. For Ecol Manag 1989;27:117-27.

19. Fromard F, Puig H, Mougin E, Marty G, Betoulle JL, Cadamuro L. Structure, above-ground biomass and dynamics of mangrove ecosystems: new data from French Guiana. Oecologia 1998;115:39-53.

20. Ong JE, Gong WK, Wong CH. Allometry and partitioning of the mangrove, Rhizophora apiculata. For Ecol Manag 2004;188:395-408.

21. Komiyama A, Poungparn S, Kato S. Common allometric equations for estimating the tree weight of mangroves. J Trop Ecol 2005;21:471-7.

22. Salum RB, Souza-filho PWM, Simard M, et al. Improving mangrove above-ground biomass estimates using LiDAR. Estuar Coast Shelf Sci 2020;236:106585.

23. Jones AR, Raja Segaran R, Clarke KD, Waycott M, Goh WSH, Gillanders BM. Estimating mangrove tree biomass and carbon content: a comparison of forest inventory techniques and drone imagery. Front Mar Sci 2020;6:784.

24. Yanagisawa H, Miyagi T. A study on the structural characteristics of prop root of mangrove trees using the 3-D laser scanner. Mangr Sci 2020;11:23-26.

25. Yamamoto A, Miyagi T, Baba S, Furukawa K, Unome S. Preliminary study of understanding the structure of mangrove forests by LiDAR-SLAM. Mangr Sci 2023;14:3-8.

26. Komiyama A, Ogino K, Aksornkoae S, Sabhasri S. Root biomass of a mangrove forest in southern Thailand. 1. Estimation by the trench method and the zonal structure of root biomass. J Trop Ecol 1987;3:97-108.

27. Komiyama A, Havanond S, Srisawatt W, et al. Top/root biomass ratio of a secondary mangrove (Ceriops tagal (Perr.) C. B. Rob.) forest. For Ecol Manag 2000;139:127-34.

28. Gleason SM, Ewel KC. Organic matter dynamics on the forest floor of a Micronesian mangrove forest: an investigation of species composition shifts. Biotropica 2006;34:190-8.

29. Cormier N, Twilley RR, Ewel KC, Krauss KW. Fine root productivity varies along nitrogen and phosphorus gradients in high-rainfall mangrove forests of Micronesia. Hydrobiologia 2015;750:69-87.

30. Noguchi K, Poungparn S, Umnouysin S, et al. Biomass and production rates of fine roots in two mangrove stands in southern Thailand. Jpn Agric Res Q 2020;54:349-60.

31. Fujimoto K, Ono K, Watanabe S, et al. Estimation of probable annual fine root production and missing dead roots associated with the ingrowth core method: attempt with major mangrove species on Iriomote Island, southwestern Japan, situated in the subtropics. Mangr Sci 2021;12:11-24.

32. Ono K, Fujimoto K, Hirata Y, et al. Estimation of total fine root production using continuous inflow methods in tropical mangrove forest on Pohnpei Island, Micronesia: fine root necromass accumulation is a substantial contributor to blue carbon stocks. Ecol Res 2022;37:33-52.

33. Xiong Y, Liu X, Guan W, et al. Fine root functional group based estimates of fine root production and turnover rate in natural mangrove forests. Plant Soil 2017;413:83-95.

34. Thom BG, Wright LD, Coleman JM. Mangrove ecology and deltaic-estuarine geomorphology: cambridge gulf-ord river, Western Australia. J Ecol 1975;63:203-32.

35. Thom BG. Mangrove ecology: a geomorphological perspective. In: Clough BF, editor. Mangrove ecosystems in Australia, structure, function and management. Canberra: Australian National University Press; 1982: pp. 3-17.

36. Thom BG. Coastal landforms and geomorphic processes. In: Snedaker SC, Snedaker JG, editors. The mangrove ecosystem: research method. Paris: UNESCO; 1984: pp. 3-17. Available from: https://unesdoc.unesco.org/ark:/48223/pf0000063028 [Last accessed on 28 July 2023].

37. Miyagi T. Land conservation for sustainable land use of mangrove habitat. Japan: Japanese Geomorphological Union; 1992;13:325-31. (In Japanese with English abstract). Available from: https://drive.google.com/file/d/0B51ucf8P4DCJbHIxNzByVUxrQk0/view?resourcekey=0--N6SiELIHChWcgIQFcD7OA [Last accessed on 31 Jul 2023].

38. Woodroffe C. Mangrove sediments and geomorpholigy. In: Robertson AI, Alongi DM, editors. Tropical mangrove ecosystems. Washington DC: American Geophysical Union; 1992: pp. 7-41.

39. Fujimoto K, Ohnuki Y. Developmental processes of mangrove habitat related to relative sea-level changes at the mouth of the Urauchi River, Iriomote Island, Southwestern Japan. Q J Geogr 1995;47:1-12.

40. Mochida Y, Fujimoto K, Miyagi T, et al. A phytosociological study of the mangrove vegetation in the Malay Peninsula. TROPICS 1999;8:207-20.

41. Lo J, Quoi LP, Visal S. Some preliminary observations on peat-forming mangroves in Botum Sakor, Cambodia. Mires Peat 2018;22:1-10. Available from: http://mires-and-peat.net/media/map22/map_22_03.pdf [Last accessed on 28 Jul 2023].

42. Mckee KL, Faulkner PL. Mangrove peat analysis and reconstruction of vegetation history at the Pelican Cays, Belize. Atoll Res Bull 2000;468:47-58. Available from: https://repository.si.edu/handle/10088/5001 [Last accessed on 28 Jul 2023].

43. Ezcurra P, Ezcurra E, Garcillán PP, Costa MT, Aburto-Oropeza O. Coastal landforms and accumulation of mangrove peat increase carbon sequestration and storage. Proc Natl Acad Sci USA 2016;113:4404-9.

44. Fujimoto K, Miyagi T. Development process of tidal-flat type mangrove habitats and their zonation in the Pacific Ocean. Vegetatio 1993;106:137-46.

45. Fujimoto K, Tabuchi R, Mori T, Murofushi T. Site environments and stand structure of the mangrove forests on pohnpei island, micronesia. JARQ 1995;29:275-84. Available from: https://www.jircas.go.jp/sites/default/files/publication/jarq/29-4-275-284_0.pdf [Last accessed on 31 Jul 2023].

46. Fujimoto K, Imaya A, Tabuchi R, Kuramoto S, Utsugi H, Murofushi T. Belowground carbon storage of Micronesian mangrove forests. Ecol Res 1999;14:409-13.

47. Ono K, Hiradate S, Morita S, et al. Assessing the carbon compositions and sources of mangrove peat in a tropical mangrove forest on Pohnpei Island, Federated States of Micronesia. Geoderma 2015;245-6:11-20.

48. Matsui N. Estimated stocks of organic carbon in mangrove roots and sediments in Hinchinbrook Channel, Australia. Mangr Salt Marsh 1998;4:199-204.

49. Wang G, Guan D, Peart MR, Chen Y, Peng Y. Ecosystem carbon stocks of mangrove forest in Yingluo Bay, Guangdong Province of South China. For Ecol Manag 2013;310:539-46.

50. Murdiyarso D, Purbopuspito J, Kaufman JB, et al. The potential of Indonesian mangrove forests for global climate change mitigation. Nat Clim Chang 2015;5:1089-92.

51. Fujimoto K, Miyagi T, Murofushi T, et al. Evaluation of the belowground carbon sequestration of estuarine mangrove habitats, Southwestern Thailand. In: Mkiyagi T, editor. Organic material and sea-level change in mangrove habitat. Sendai: Tohoku Gakuin University; 2000. pp. 101-9.

52. Fujimoto K, Ishihara S, Yukino I, et al. Evaluation of carbon sequestration in mangrove ecosystem with its habitat dynamics in Iriomote Island, Southwestern Japan. In Proceedings of the general meeting of the Association of Japanese Geographers. 2000; pp. 60-1. (In Japanese).

53. Fujimoto K, Miyagi T, Kawaguchi S, et al. Carbon sequestration in mangrove ecosystems with its habitat dynamics in Iriomote Island, Southwestern Japan. In: Research report on mangroves. Naha: Research Institute for Subtropical Regions. 2002; pp. 309-19. (In Japanese with English abstract)

54. Fujimoto K, Sakai H, Imaya A. Evaluation of carbon accumulation function in sediments of mangrove forests: a case study in Iriomote Island, Japan. In Proceedings of the general meeting of the Association of Japanese Geographers. 1996; pp. 128-9. (In Japanese).

55. Ishihara S, Fujimoto K, Kawanishi M, Watanabe R, Tanaka S. Relationship between mangrove vegetation and micro-topography and carbon storage of Kandelia candel (L.) Druce forests in Amani-ohshima Island, southwestern Japan. Jpn J For Environ 2004;46:9-14. (In Japanese with English abstract). Available from: https://www.jstage.jst.go.jp/article/jjfe/46/1/46_KJ00005291914/_pdf/-char/ja [Last accessed on 31 Jul 2023].

56. Atwood TB, Connolly RM, Almahasheer H, et al. Global patterns in mangrove soil carbon stocks and losses. Nature Clim Chang 2017;7:523-8.

57. MacKenzie R, Sharma S, Rovai AR. Environmental drivers of blue carbon burial and soil carbon stocks in mangrove forests. In: Sidik F, Friess DA, editors. Dynamic sedimentary environments of mangrove coasts. Amsterdam: Elsevier; 2021. pp. 275-94.

58. Ogawa H, Yoda K, Kira T. A preliminary survey on the vegetation of Thailand. Nat Life Southeast Asia 1961;1:21-157.

59. Ono K, Fujimoto K, Hiraide M, Lihpai S, Tabuchi R. Aboveground litter production, accumulation, decomposition, and tidal transportation of coral reef-type mangrove forest on Pohnpei Island, Federated States of Micronesia. TROPICS 2006;15:75-84.

60. Mazda Y, Wolanski E, Ridd PV. The role of physical processes in mangrove environments: manual for the preservation and utilization of mangrove ecosystems. Tokyo: TERRAPUB; 2007. p. 598.

61. Wolanski E, Elliott M. Estuarine ecohydrology: an introduction, 2nd ed. Amsterdam: Elsevier; 2015.

62. Mazda Y, Kanazawa N, Wolanski E. Tidal asymmetry in mangrove creeks. Hydrobiologia 1995;295:51-8.

63. Wolanski E. Transport of sediment in mangrove swamps. Hydrobiologia 1995;295:31-42.

64. Furukawa K, Wolanski E, Mueller H. Currents and sediment transport in mangrove forests. Estuar Coast Shelf Sci 1997;44:301-10.

65. Krauss K, Allen J, Cahoon D. Differential rates of vertical accretion and elevation change among aerial root types in Micronesian mangrove forests. Estuar Coast Shelf Sci 2003;56:251-9.

66. Horstman E, Dohmen-janssen C, Bouma T, Hulscher S. Tidal-scale flow routing and sedimentation in mangrove forests: combining field data and numerical modelling. Geomorphology 2015;228:244-62.

67. Chen Y, Li Y, Thompson C, Wang X, Cai T, Chang Y. Differential sediment trapping abilities of mangrove and saltmarsh vegetation in a subtropical estuary. Geomorphology 2018;318:270-82.

68. Willemsen P, Horstman E, Borsje B, Friess D, Dohmen-janssen C. Sensitivity of the sediment trapping capacity of an estuarine mangrove forest. Geomorphology 2016;273:189-201.

69. Weisscher SAH, Van den Hoven K, Pierik HJ, Kleinhans MG. Building and raising land: mud and vegetation effects in infilling estuaries. J Geophys Res Earth Surf 2022;127:e2021JF006298.

70. Wolanski E. Mangrove hydrodynamics. In: Robertson AI, Alongi DM, editors. Tropical mangrove ecosystems. Washington DC: American Geophysical Union; 1992. pp 43-62.

71. Mazda Y, Wolanski E, King B, Sase A, Ohtsuka D, Magi M. Drag force due to vegetation in mangrove swamps. Mangr Salt Marsh 1997;1:193-9.

72. Massel SR, Furukawa K, Brinkman RM. Surface wave propagation in mangrove forests. Fluid Dyn Res 1999;24:219.

73. Yoshikai M, Nakamura T, Herrera EC, et al. Representing the impact of Rhizophora mangroves on flow and sediment transport in a hydrodynamic model (COAWST_rh v1.0): the importance of three-dimensional root system structures. Available from: https://egusphere.copernicus.org/preprints/2023/egusphere-2022-1350/ [Last accessed on 28 July 2023].

74. Best ÜSN, van der Wegen M, Dijkstra J, Reyns J, van Prooijen BC, Roelvink D. Wave attenuation potential, sediment properties and mangrove growth dynamics data over Guyana's intertidal mudflats: assessing the potential of mangrove restoration works. Earth Syst Sci Data 2022;14:2445-62.

75. Fujimoto K, Miyagi T, Murofushi T, et al. Mangrove habitat dynamics and Holocene sea-level changes in the southwestern coast of Thailand. TROPICS 1999;8:239-55.

76. Krauss KW, Cahoon DR, Allen JA, Ewel KC, Lynch JC, Cormier N. Surface elevation change and susceptibility of different mangrove zones to sea-level rise on Pacific high islands of Micronesia. Ecosystems 2010;13:129-43.

77. Saintilan N, Khan NS, Ashe E, et al. Thresholds of mangrove survival under rapid sea level rise. Science 2020;368:1118-21.

78. Parkinson RW, DeLaune RD, White JR. Holocene sea-level rise and the fate of mangrove forests within the wider Caribbean region. J Coast Res 1994;10:1077-86. Available from: https://www.jstor.org/stable/4298297 [Last accessed on 31 Jul 2023].

79. Macintyre LG, Littler MM, Littler DS. Holocene history of Tabacco Range, Belize, central America. Atoll Res Bull 1995;430:1-18.

80. Miyagi T, Kikuchi T, Fujimoto K. Late Holocene sealevel changes and the mangrove peat accumulation/habitat dynamics in the western pacific area. In: Kikuchi T, editor. Rapid sea level rise and mangrove habitat. Gifu: Institute for Basin Ecosystem Studies, Gifu University; 1995. pp. 19-26.

81. McKee KL, Cahoon DR, Feller IC. Caribbean mangroves adjust to rising sea level through biotic controls on change in soil elevation. Global Ecol Biogeogr 2007;16:545-56.

82. IPCC. Climate change 2021: The physical science basis. Available from: https://www.ipcc.ch/report/ar6/wg1/ [Last accessed on 28 July 2023].

83. IPCC. Climate change 2013: The physical science basis. Available from: https://www.ipcc.ch/report/ar5/wg1/ [Last accessed on 28 July 2023].

84. Krauss KW, McKee KL, Lovelock CE, et al. How mangrove forests adjust to rising sea level. New Phytol 2014;202:19-34.

85. Mckee KL, Krauss KW, Cahoon DR. Does geomorphology determine vulnerability of mangrove coasts to sea-level rise? In: Sidik F, Friess DA, editors. Dynamic sedimentary environments of mangrove coasts. Amsterdam: Elsevier; 2021. pp. 255-72.

86. Fujimoto K, Mochida Y, Kikuchi T, Tabuchi R, Hirata Y, Lihpai S. The relationships among community type, peat layer thickness, belowground carbon storage and habitat age of mangrove forests in Pohnpei Island, Micronesia. Open J For 2015;5:48-56.

87. Hemminga MA, Slim FJ, Kazungu J, Ganssen GM, Nieuwenhuize J, Kruyt NM. Carbon outwelling from a mangrove forest with adjacent seagrass beds and coral reefs (Gazi Bay, Kenya). Mar Ecol Prog Ser 1994;106:291-301.

88. Alongi DM, Ayukai T, Brunskill GJ, Clough BF, Wolanski E. Sources, sinks, and export of organic carbon through a tropical, semi-enclosed delta (Hinchinbrook Channel, Australia). Mangr Salt Marsh 1998;2:237-42.

89. Adame MF, Lovelock CE. Carbon and nutrient exchange of mangrove forests with the coastal ocean. Hydrobiologia 2011;663:23-50.

90. Chen G, Azkab MH, Chmura GL, et al. Mangroves as a major source of soil carbon storage in adjacent seagrass meadows. Sci Rep 2017;7:42406.

91. Huxham M, Whitlock D, Githaiga M, Dencer-brown A. Carbon in the coastal seascape: how interactions between mangrove forests, seagrass meadows and tidal marshes influence carbon storage. Curr For Rep 2018;4:101-10.

92. Pirasteh S, Zenner EK, Mafi-Gholami D, et al. Modeling mangrove responses to multi-decadal climate change and anthropogenic impacts using a long-term time series of satellite imagery. Int J Appl Earth Obs Geoinf 2021;102:102390.

93. Chaudhuri P, Chaudhuri S, Ghosh R. The role of mangroves in coastal and estuarine sedimentary accretion in Southeast Asia. In: Aiello G, editor. Sedimentary processes -examples from Asia, Turkey and Nigeria. London: IntechOpen; 2019.

94. Buffington KJ, MacKenzie RA, Carr JA, Apwong M, Krauss KW, Thorne KM. Mangrove species’ response to sea-level rise across Pohnpei, Federated States of Micronesia. U.S. Geological Survey Open-File Report 2021; 1002p.