Marked Ericales diversity in late Oligocene–Early Miocene palynofloras from northern Thailand suggests stratified mountain forests

Paranchai Malailkanok; Friðgeir Grímsson; Reinhard Zetter; Paul J. Grote; Thomas Denk; Wongkot Phuphumirat

doi:10.1111/jse.70010

Journal of Systematics and Evolution ›› 2025, Vol. 63 ›› Issue (6) :1458 -1480. DOI: 10.1111/jse.70010

Research Article

Marked Ericales diversity in late Oligocene–Early Miocene palynofloras from northern Thailand suggests stratified mountain forests

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Abstract

Fossil Ericales pollen from late Oligocene to Early Miocene sediments of the Ban Pa Kha Subbasin, Li Basin, northern Thailand, were examined using the single-grain method. A total of 24 different ericalean pollen types belonging to Ebenaceae (Diospyros), Ericaceae (Cassiope, Vaccinium, and Rhododendron), Pentaphylacaceae (Adinandra), Sapotaceae, Styracaceae (Rehderodendron and Styrax), and Symplocaceae (Symplocos) were identified. All the fossil pollen, except that of Sapotaceae, represent families/genera that are described for the first time from the Cenozoic of Thailand. By considering present terrestrial biome occupancy, Köppen–Geiger climate profiles, and vertical distributions of potential modern analogs of the parent plants producing the fossil pollen, the phytosociological and paleoecological preferences of the fossil taxa were assessed. Our results demonstrate that modern analogs of most of the ericalean taxa have wide ecological and climatic amplitudes with a broad zone of convergence in warm and cold temperate humid or seasonally dry climates. Exceptions are Sapotaceae, which rarely occur outside lowland tropical forests, and Cassiope, which at present occurs at high elevations and, besides Rehderodendron, is one of two modern analogs absent from the modern flora of Thailand. Along with a review of phytosociological studies in montane forests of northern Thailand and neighboring regions, this suggests that the assemblage of dispersed ericalean pollen of the Ban Pa Kha Subbasin likely derives from more than one vegetation type and possibly from different vertical zones.

Keywords

forest vegetation / Köppen signatures / paleoenvironment / palynology / scanning electron microscopy / single-grain method / terrestrial biomes

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Paranchai Malailkanok, Friðgeir Grímsson, Reinhard Zetter, Paul J. Grote, Thomas Denk, Wongkot Phuphumirat. Marked Ericales diversity in late Oligocene–Early Miocene palynofloras from northern Thailand suggests stratified mountain forests. Journal of Systematics and Evolution, 2025, 63(6): 1458-1480 DOI:10.1111/jse.70010

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References

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[1]	Adroit B, Grímsson F, Suc J, Escarguel G, Zetter R, Bouchal JM, Fauquette S, Zhuang X, Djamalli M. 2022. Are morphological characteristics of Parrotia (Hamamelidaceae) pollen species diagnostic? Review of Palaeobotany and Palynology 307: 104776.

[2]	Ahrendt H, Chonglakmany C, Hansen BT, Helmcke D. 1993. Geochronological cross section through Northern Thailand. Journal of Southeast Asian Earth Sciences 8: 207-217.

[3]	Aranha Filho JLM, Fritsch PW, Almeda F, Martins AB. 2009. Cryptic dioecy is widespread in South American species of Symplocos section Barberina (Symplocaceae). Plant Systematics and Evolution 277: 99-104.

[4]

Bansal M, Nagaraju SK, Mishra AK, Selvaraj J, Patnaik R, Prasad V. 2021. Fossil pollen from early Palaeogene sediments in western India provides phylogenetic insights into divergence history and pollen character evolution in the pantropical family Ebenaceae. Botanical Journal of the Linnean Society 197: 147-169.

[5]	Barth OM. 1979. Pollen morphology of Brazilian Symplocos species (Symplocaceae). Grana 18: 99-107.

[6]	Bouchal JM, Grímsson F, Zetter R, Denk T. 2024. The late middle Eocene palynoflora of Hareø, West Greenland: Polar forests in a vanishing greenhouse world. Grana 63: 71-159.

[7]	Bouchal JM, Güner TH, Velitzelos D, Velitzelos E, Denk T. 2020. Messinian vegetation and climate of the intermontane Florina–Ptolemais–Servia Basin, NW Greece inferred from palaeobotanical data: How well do plant fossils reflect past environments? Royal Society Open Science 7: 192067.

[8]	Bouchal JM, Mayda S, Zetter R, Grímsson F, Akgün F, Denk T. 2017. Miocene palynofloras of the Tınaz lignite mine, Muğla, southwest Anatolia: Taxonomy, palaeoecology and local vegetation change. Review of Palaeobotany and Palynology 243: 1-36.

[9]	Bouchal JM, Zetter R, Denk T. 2016a. Pollen and spores of the uppermost Eocene Florissant Formation, Colorado: A combined light and scanning electron microscopy study. Grana 55: 179-245.

[10]	Bouchal JM, Zetter R, Grímsson F, Denk T. 2016b. The middle Miocene palynoflora and palaeoenvironments of Eskihisar (Yatağan basin, south-western Anatolia): A combined LM and SEM investigation. Botanical Journal of the Linnean Society 182: 14-79.

[11]	Chantaranothai P. 2014. Sapotaceae. In: T Santisuk, H Balslev eds. Flora of Thailand. Bangkok: Forest Herbarium, Royal Forest Department. 11(part 4): 610-655.

[12]	Chartier M, Von Balthazar M, Sontag S, Löfstrand S, Palme T, Jabbour F, Sauquet H, Schönenberger J. 2021. Global patterns and a latitudinal gradient of flower disparity: Perspectives from the angiosperm order Ericales. New Phytologist 230: 821-831.

[13]	Charusiri P, Pongsapitch W, Kanthaprab C. 1991. Granite belts in Thailand: New evidences from 40Ar/39Ar dating. Mineral Resource Gazette 36: 43-62.

[14]	Chase MW, Christenhusz MJM, Fay MF, Byng JW, Judd WS, Soltis DE, Mabberley DJ, Sennikov AN, Soltis PS, Stevens PF. 2016. An update of the Angiosperm Phylogeny Group classification for the orders and families of flowering plants: APG IV. Botanical Journal of the Linnean Society 181: 1-20.

[15]	Christenhusz MJM, Byng JW. 2016. The number of known plant species in the world and its annual increase. Phytotaxa 261: 201-217.

[16]	Corbett SL, Manchester SR. 2004. Phytogeography and fossil history of Ailanthus (Simaroubaceae). International Journal of Plant Sciences 165: 671-690.

[17]	Cui D, Liang S, Wang D, Liu Z. 2021. A 1 km global dataset of historical (1979–2013) and future (2020–2100) Köppen–Geiger climate classification and bioclimatic variables. Earth System Science Data 13: 5087-5114.

[18]	Denk T, Bouchal JM. 2021a. Dispersed pollen and calyx remains of Diospyros (Ebenaceae) from the middle Miocene “Plant beds” of Søby, Denmark. GFF 143: 292-304.

[19]	Denk T, Bouchal JM. 2021b. New Fagaceous pollen taxa from the Miocene Søby flora of Denmark and their biogeographic implications. American Journal of Botany 108: 1500-1524.

[20]	Denk T, Bouchal JM, Güner HT, Coiro M, Butzmann R, Pigg KB, Tiffney BH. 2023a. Cenozoic migration of a desert plant lineage across the North Atlantic. New Phytologist 238: 2668-2684.

[21]	Denk T, Grimm GW, Hipp AL, Bouchal JM, Schulze ED, Simeone MC. 2023b. Niche evolution in a northern temperate tree lineage: Biogeographical legacies in cork oaks (Quercus section Cerris). Annals of Botany 131: 769-787.

[22]	Denk T, Grímsson F, Zetter R, Símonarson LA. 2011. Late Cainozoic floras of Iceland: 15 million years of vegetation and climate history in the northern North Atlantic. Dordrecht: Springer.

[23]	Denk T, Velitzelos D, Güner HT, Ferrufino-Acosta L. 2015. Smilax (Smilacaceae) from the Miocene of western Eurasia with Caribbean biogeographic affinities. American Journal of Botany 102: 423-438.

[24]

Dinerstein E, Olson D, Joshi A, Vynne C, Burgess ND, Wikramanayake E, Hahn N, Palminteri S, Hedao P, Noss R, Hansen M, Locke H, Ellis EC, Jones B, Barber CV, Hayes R, Kormos C, Martin V, Crist E, Sechrest W, Price L, Baillie JEM, Weeden D, Suckling K, Davis C, Sizer N, Moore R, Thau D, Birch T, Potapov P, Turubanova S, Tyukavina A, De Souza N, Pintea L, Brito JC, Llewellyn OA, Miller AG, Patzelt A, Ghazanfar SA, Timberlake J, Klöser H, Shennan-Farpón Y, Kindt R, Lillesø J-PB, Van Breugel P, Graudal L, Voge M, Al-Shammari KF, Saleem M. 2017. An ecoregion-based approach to protecting half the terrestrial realm. BioScience 67: 534-545.

[25]	e-Flora of Thailand. 2024. Flora of Thailand. Forest Herbarium, Department of National Parks, Wildlife and Plant Conservation [online]. Available from https://www.dnp.go.th/botany/eflora/aboutus.html [accessed 16 June 2024].

[26]	Endo S. 1963. Some older tertiary plants from Northern Thailand. Japanese Journal of Geology and Geography 34: 177-180.

[27]	Endo S. 1967. A supplementary note on the Palaeogene Li Flora in North Thailand. Geology and Palaeontology of Southeast Asia 3: 165-169.

[28]	Fang MY, Fang RC, He MY, Hu LZ, Yang HB, Qin HN, Min TL, Chamberlain DF, Stevens PF, Wallace GD, Anderberg AA. 2005. Ericaceae. In: ZY Wu, PH Raven, DY Hong eds. Flora of China. Beijing: Science Press; St Louis: Missouri Botanical Garden Press. 14: 242-517.

[29]	Fritsch PW. 2001. Phylogeny and biogeography of the flowering plant genus Styrax (Styracaceae) based on chloroplast DNA restriction sites and DNA sequences of the internal transcribed spacer region. Molecular Phylogenetics and Evolution 19: 387-408.

[30]	Fritsch PW, Manchester SR, Stone RD, Cruz BC, Almeda F. 2015. Northern Hemisphere origins of the amphi-Pacific tropical plant family Symplocaceae. Journal of Biogeography 42: 891-901.

[31]	Gardner S, Sidisunthorn P, Anusarnsunthorn V. 2007. A field guide to forest trees of northern Thailand. Bangkok: Kobfai Publishing Project.

[32]	Geeraerts A, Raeymaekers JAM, Vinckier S, Pletsers A, Smets E, Huysmans S. 2009. Systematic palynology in Ebenaceae with focus on Ebenoideae: Morphological diversity and character evolution. Review of Palaeobotany and Palynology 153: 336-353.

[33]	Geier C, Bouchal JM, Ulrich S, Gross M, Zetter R, Denk T, Grímsson F. 2022. Paleovegetation and paleoclimate inferences of the early late Sarmatian palynoflora from the Gleisdorf Fm. at Gratkorn, Styria, Austria. Review of Palaeobotany and Palynology 307: 104767.

[34]	Geier C, Bouchal JM, Ulrich S, Uhl D, Wappler T, Wedmann S, Zetter R, Schönenberger J, Grímsson F. 2023. Potential pollinators and paleoecological aspects of Eocene Ludwigia (Onagraceae) from Eckfeld, Germany. Palaeoworld 33: 1079-1104.

[35]	Goldy RG, Munoz CE, Lyrene PM. 1984. Pollen morphology of some Vaccinium species and their hybrids. Journal of the American Society for Horticultural Science 109: 237-244.

[36]	Grímsson F, Bouchal JM, Xafis A, Zetter R. 2020. Combined LM and SEM study of the middle Miocene (Sarmatian) palynoflora from the Lavanttal Basin, Austria: Part V. Magnoliophyta 3—Myrtales to Ericales. Grana 59: 127-193.

[37]	Grímsson F, Grimm GW, Meller B, Bouchal JM, Zetter R. 2016. Combined LM and SEM study of the middle Miocene (Sarmatian) palynoflora from the Lavanttal Basin, Austria: Part IV. Magnoliophyta 2—Fagales to Rosales. Grana 55: 101-163.

[38]	Grímsson F, Grimm GW, Potts AJ, Zetter R, Renner SS. 2018. A Winteraceae pollen tetrad from the early Paleocene of western Greenland, and the fossil record of Winteraceae in Laurasia and Gondwana. Journal of Biogeography 45: 567-581.

[39]	Grímsson F, Zetter R, Grimm GW, Pedersen GK, Pedersen AK, Denk T. 2015. Fagaceae pollen from the early Cenozoic of West Greenland: Revisiting Engler's and Chaney's Arcto-Tertiary hypotheses. Plant Systematics and Evolution 301: 809-832.

[40]

Grote PJ. 2005. Use of leaf architecture and anatomy in the study of plant diversity in the Tertiary and Recent of Thailand (Report No. SUT1-104-43-12-08). Nakhon Ratchasima: School of Biology, Institute of Science, Suranaree University of Technology. [Online]. Available from http://sutir.sut.ac.th:8080/jspui/handle/123456789/2250 [accessed 7 May 2024].

[41]	Grote PJ. 2015. Paleobiogeographic and paleoenvironmental changes in Thailand since the Miocene: Evidence from plant fossils [online]. Available from http://sutir.sut.ac.th:8080/jspui/handle/123456789/5802 [accessed 16 June 2024].

[42]	Grote PJ, Srisuk P. 2021. Fossil Pinus from the Cenozoic of Thailand. Review of Palaeobotany and Palynology 295: 104501.

[43]	Grygorieva O, Brindza J, Ostrolucká MG, Ostrovský R, Klymenko S, Nôžková J, Tóth D. 2010. Pollen characteristics in some persimmon species (Diospyros spp.). Agriculture (Pol′nohospodárstvo) 56: 121-130.

[44]	Grygorieva O, Brindza J, Ostrovský R, Klymenko S, Grabovetska O. 2013. Pollen characteristics in some Diospyros species. Modern Phytomorphology 3: 45-50.

[45]	Hackl H. 2017. Pollenmorphologische Untersuchung (LM, REM) an ausgewählten Gattungen der Fundstelle Brandon Lignite, Vermont, USA. Master's Thesis. Vienna: University of Vienna.

[46]	Halbritter H, Auer W. 2021. Rhododendron luteum. In: PalDat – A palynological database [online]. Available from https://www.paldat.org/pub/Rhododendron_luteum/305511 [accessed 7 May 2024].

[47]	Halbritter H, Berger A 2018. Vaccinium poasanum. In: PalDat—A Palynological Database [online]. Available from https://www.paldat.org/pub/Vaccinium_poasanum/303128 [accessed 7 May 2024].

[48]	Halbritter H, Heigl H 2021. Vaccinium myrtillus. In: PalDat—A Palynological Database [online]. Available from https://www.paldat.org/pub/Vaccinium_myrtillus/304305 [accessed 7 May 2024].

[49]	Halbritter H, Heigl H, Auer W, Berger A 2021. Vaccinium uliginosum. In: PalDat—A Palynological Database [online]. Available from https://www.paldat.org/pub/Vaccinium_uliginosum/306206 [accessed 7 May 2024].

[50]	Halbritter H, Heigl H, Sonnleitner M 2020. Vaccinium vitis-idaea. In: PalDat—A Palynological Database [online]. Available from https://www.paldat.org/pub/Vaccinium_vitis-idaea/304304 [accessed 7 May 2024].

[51]	Halbritter H, Ulrich S, Grímsson F, Weber M, Zetter R, Hesse M, Buchner R, Svojtka M, Frosch-Radivo A. 2018. Illustrated pollen terminology. Vienna: Springer.

[52]	Harley MM. 1986. Distinguishing pollen characters for the Sapotaceae. Canadian Journal of Botany 64: 3091-3100.

[53]	Harley MM. 1991. The pollen morphology of the Sapotaceae. Kew Bulletin 46: 379-491.

[54]	Hofmann CC. 2010. Microstructure of Fagaceae pollen from Austria (Paleocene/Eocene boundary) and Hainan Island (? middle Eocene). In: 8th European Palaeobotany–Palynology Conference. Budapest: Hungarian Natural History Museum. 6-19.

[55]	Hofmann CC. 2018. Light and scanning electron microscopic investigations of pollen of Ericales (Ericaceae, Sapotaceae, Ebenaceae, Styracaceae and Theaceae) from five lower and mid-Eocene localities. Botanical Journal of the Linnean Society 187: 550-578.

[56]

Hofmann CC, Kodrul TM, Liu X, Jin J. 2019. Scanning electron microscopy investigations of middle to late Eocene pollen from the Changchang Basin (Hainan Island, South China)—Insights into the paleobiogeography and fossil history of Juglans, Fagus, Lagerstroemia, Mortoniodendron, Cornus, Nyssa, Symplocos and some Icacinaceae in SE Asia. Review of Palaeobotany and Palynology 265: 41-61.

[57]

Hofmann CC, Sachse M. 2023. SEM pollen analysis of Miocene deposits of Entrischenbrunn (Bavaria, Germany) reveal considerable amounts of pollen of subhumid and sclerophyllous together with azonal water plants reflecting the vegetation mosaic of a braided river system. Review of Palaeobotany and Palynology 308: 104787.

[58]	Hofmann CC, Zhao W. 2022. Unravelling the palaeobiogeographical history of the living fossil genus Rehderodendron (Styracaceae) with fossil and extant pollen and fruit data. BMC Ecology and Evolution 22: 145.

[59]	Huang H, Pérez-Pinedo D, Morley RJ, Dupont-Nivet G, Philip A, Win Z, Aung DW, Licht A, Jardine PE, Hoorn C. 2021. At a crossroads: The late Eocene flora of central Myanmar owes its composition to plate collision and tropical climate. Review of Palaeobotany and Palynology 291: 104441.

[60]	Jiang Y, Zang R, Letcher SG, Ding Y, Huang Y, Lu X, Huang J, Liu W, Zhang Z. 2016. Associations between plant composition/diversity and the abiotic environment across six vegetation types in a biodiversity hotspot of Hainan Island, China. Plant and Soil 403: 21-35.

[61]	Jordan GJ, Bannister JM, Mildenhall DC, Zetter R, Lee DE. 2010. Fossil Ericaceae from New Zealand: Deconstructing the use of fossil evidence in historical biogeography. American Journal of Botany 97: 59-70.

[62]	Khadanga SS, Dar AA, Jaiswal N, Dash PK, Jayakumar S. 2023. Elevation patterns of tree diversity, composition and stand structure in Mahendragiri Hill Forest, Eastern Ghats of Odisha, India. Journal of Asia-Pacific Biodiversity 16: 391-405.

[63]	Kmenta M, Zetter R. 2013. Combined LM and SEM study of the upper Oligocene/lower Miocene palynoflora from Altmittweida (Saxony): Providing new insights into Cenozoic vegetation evolution of Central Europe. Review of Palaeobotany and Palynology 195: 1-18.

[64]	Kodela P. 2006. Pollen morphology of some rainforest taxa occurring in the Illawarra region of New South Wales, Australia. Telopea 11: 346-389.

[65]	Koksheeva I, Naryshkina N, Tvorogov S, Doudkin R, Kazarin V. 2019. Can pollen sculpture in Rhododendron subsec. Rhodorastra differentiate species? Grana 58: 350-362.

[66]	Kottek M, Grieser J, Beck C, Rudolf B, Rubel F. 2006. World map of the Köppen–Geiger climate classification updated. Meteorologische Zeitschrift 15: 259-263.

[67]	Kunasit P, Chantaranothai P. 2022. Pollen morphology of the Sapotaceae from Thailand and its taxonomic implications. Thai Forest Bulletin (Botany) 50: 120-134.

[68]	Li TQ, Cao HJ, Kang MS, Zhang ZX, Zhao N, Zhang H. 2011. Pollen flora of China woody plants by SEM. Beijing: Science Press.

[69]	Liang YH, Yu CH. 1985. Pollen morphology of Styracaceae and its taxonomic significance. Journal of Systematics and Evolution 23: 81-90.

[70]	Liu YS, Zetter R, Ferguson DK, Mohr BAR. 2007. Discriminating fossil evergreen and deciduous Quercus pollen: A case study from the Miocene of eastern China. Review of Palaeobotany and Palynology 145: 289-303.

[71]	Lombardi GC, Midgley JJ, Turner RC, Peter CI. 2021. Pollination biology of Erica aristata: First confirmation of long-proboscid fly-pollination in the Ericaceae. South African Journal of Botany 142: 403-408.

[72]	Lu L, Fritsch PW, Wang H, Li HT, Li DZ, Chen JQ. 2009. Pollen morphology of Gaultheria L. and related genera of subfamily Vaccinioideae: Taxonomic and evolutionary significance. Review of Palaeobotany and Palynology 154: 106-123.

[73]	Magallón S, Sánchez-Reyes LL, Gómez-Acevedo SL. 2019. Thirty clues to the exceptional diversification of flowering plants. Annals of Botany 123: 491-503.

[74]	Maity D. 2014. A new subspecies of Cassiope fastigiata (Wall.) D. Don (Ericaceae) from Sikkim Himalaya. Feddes Repertorium 125: 72-77.

[75]	Makino M, Hayashi R, Takahara H. 2009. Pollen morphology of the genus Quercus by scanning electron microscope. Scientific Reports of Kyoto Prefectural University, Life and Environmental Sciences 61: 53-81.

[76]	Malaikanok P, Grímsson F, Denk T, Phuphumirat W. 2023. Community assembly of tropical Fagaceae-dominated forests in Thailand dates back at least to the Late Palaeogene. Botanical Journal of the Linnean Society 202: 1-22.

[77]	Manchester SR, Grímsson F, Zetter R. 2015. Assessing the fossil record of asterids in the context of our current phylogenetic framework. Annals of the Missouri Botanical Garden 100: 329-363.

[78]	Mateus JE. 1989. Pollen morphology of Portuguese Ericales. Revista de Biologia 14: 135-208.

[79]	Morley CK, Sangkumarn N, Hoon TB, Chonglakmani C, Lambiase J. 2000. Structural evolution of the Li Basin, northern Thailand. Journal of the Geological Society 157: 483-492.

[80]	Morley CK, Woganan N, Sankumarn N, Hoon TB, Alief A, Simmons M. 2001. Late Oligocene–Recent stress evolution in rift basins of northern and central Thailand: Implications for escape tectonics. Tectonophysics 334: 115-150.

[81]	Morton CM, Dickison WC. 1992. Comparative pollen morphology of the Styracaceae. Grana 31: 1-15.

[82]	Nagamasu H. 1989a. Pollen morphology and relationship of Symplocos tinctoria (L.F.) L′Her. (Symplocaceae). Botanical Gazette 150: 314-318.

[83]	Nagamasu H. 1989b. Pollen morphology of Japanese Symplocos (Symplocaceae). The Botanical Magazine Tokyo 102: 149-164.

[84]	Nakamura T, Takahara H, Ohno K. 2012. Pollen-vegetation relationship of surface pollen assemblages and objective vegetation reconstruction in the Hakkoda Mountains, northeastern Japan. Quaternary International 254: 138-151.

[85]	Namgay S, Sridith K. 2021. The morphological variation of the genus Rhododendron (Ericaceae) in Himalayan Ranges of Bhutan. Tropical Natural History 21: 299-320.

[86]	Nichols G, Uttamo W. 2005. Sedimentation in a humid, interior, extensional basin: The Cenozoic Li Basin, northern Thailand. Journal of the Geological Society 162: 333-347.

[87]	Nooteboom HP. 1975. Revision of the Symplocaceae of the Old World, New Caledonia excepted. Leiden: Brill.

[88]	Park J, Song U. 2010. Pollen morphology of the genus Rhododendron (Ericaceae) in Korea. Journal of Korean Society of Forest Science 99: 663-672.

[89]	Peel MC, Finlayson BL, McMahon TA. 2007. Updated world map of the Köppen-Geiger climate classification. Hydrology and Earth System Sciences 11: 1633-1644.

[90]	Perveen A, Qaiser M. 2013. Pollen flora of Pakistan–LXXII. Ericaceae. Pakistan Journal of Botany 45: 977-979.

[91]	POWO. 2024. Plants of the World Online. The Royal Botanic Gardens, Kew [online]. Available from http://www.plantsoftheworldonline.org [accessed 16 June 2024].

[92]	Premathilake R, Epitawatta S, Nilsson S. 1999. Pollen morphology of some selected plant species from Horton Plains, Sri Lanka. Grana 38: 289-295.

[93]	Premathilake R, Nilsson S. 2001. Pollen morphology of endemic species of the Horton Plains National Park, Sri Lanka. Grana 40: 256-279.

[94]	Punt W, Hoen P, Blackmore S, Nilsson S, Thomas AL. 2007. Glossary of pollen and spore terminology. Review of Palaeobotany and Palynology 143: 1-81.

[95]	QGIS Development Team. 2023. QGIS Geographic Information System [online]. Available from https://qgis.org/en/site [accessed 16 June 2024].

[96]	Ratanasthien B. 1984. Spore and pollen dating of some tertiary coal and oil deposits in northern Thailand. In: N Thiramongkol, S Nakapadungrat, V Pisutha-Arnond eds. Proceedings of the Conference on Application of Geology and the National Development, 19–22 November, 1984. 273-280.

[97]	Ratanasthien B. 2002. Problems of Neogene biostratigraphic correlation in Thailand and surrounding areas. Revista Mexicana de Ciencias Geológicas 19: 235-241.

[98]	Rose JP, Kleist TJ, Löfstrand SD, Drew BT, Schönenberger J, Sytsma KJ. 2018. Phylogeny, historical biogeography, and diversification of angiosperm order Ericales suggest ancient Neotropical and East Asian connections. Molecular Phylogenetics and Evolution 122: 59-79.

[99]	Rubel F, Kottek M. 2010. Observed and projected climate shifts 1901–2100 depicted by world maps of the Köppen-Geiger climate classification. Meteorologische Zeitschrift 19: 135-141.

[100]

Sadowski EM, Hammel JU, Denk T. 2018. Synchrotron X-ray imaging of a dichasium cupule of Castanopsis from Eocene Baltic amber. American Journal of Botany 105: 2025-2036.

[101]

Sadowski EM, Hofmann CC. 2023. The largest amber-preserved flower revisited. Scientific Reports 13: 1-11.

[102]

Sadowski EM, Schmidt AR, Denk T. 2020. Staminate inflorescences with in situ pollen from Eocene Baltic amber reveal high diversity in Fagaceae (oak family). Willdenowia 50: 405-517.

[103]

Sadowski EM, Seyfullah LJ, Sadowski F, Fleischmann A, Behling H, Schmidt AR. 2015. Carnivorous leaves from Baltic amber. Proceedings of the National Academy of Sciences USA 112: 190-195.

[104]

Santisuk T. 2012. Forest of Thailand. Bangkok: Department of National Parks, Wildlife and Plant Conservation, Thailand.

[105]

Sarwar AKMG. 2007. Pollen morphology and its systematic significance in the Ericaceae. Ph.D. Dissertation. Hokkaido: Hokkaido University.

[106]

Sarwar AKMG, Ito T, Takahashi H. 2006. An overview of pollen morphology and its relevance to the sectional classification of Vaccinium L. (Ericaceae). Japanese Journal of Palynology 152: 15-34.

[107]

Sarwar AKMG, Takahashi H. 2013. Pollen morphology of Rhododendron L. and related genera and its taxonomic significance. Bangladesh Journal of Plant Taxonomy 20: 185-199.

[108]

Sarwar AKMG, Takahashi H. 2014a. Pollen morphology of Erica L. and related genera and its taxonomic significance. Grana 53: 221-231.

[109]

Sarwar AKMG, Takahashi H. 2014b. Pollen morphology of the tribe Phyllodoceae (Ericoideae, Ericaceae) and its taxonomic significance. Bangladesh Journal of Plant Taxonomy 21: 129-137.

[110]

Sattraburut T, Ratanasthien B, Thasod Y. 2021. Palaeovegetation and palaeoclimate of Tertiary sediments from Hongsa Coalfield, Xayabouly Province, Lao PDR—Implication from palynofloras. Songklanakarin Journal of Science & Technology 43: 648-659.

[111]

Sawangchote P, Grote PJ, Dilcher DL. 2009. Tertiary leaf fossils of Mangifera (Anacardiaceae) from Li Basin, Thailand as examples of the utility of leaf marginal venation characters. American Journal of Botany 96: 2048-2061.

[112]

Sawangchote P, Grote PJ, Dilcher DL. 2010. Tertiary leaf fossils of Semecarpus (Anacardiaceae) from Li Basin, Northern Thailand. Thai Forest Bulletin (Botany) 38: 8-22.

[113]

Sepulchre P, Jolly D, Ducrocq S, Chaimanee Y, Jaeger JJ, Raillard A. 2010. Mid-Tertiary paleoenvironments in Thailand: Pollen evidence. Climate of the Past 6: 461-473.

[114]

Sherman R, Mullen R, Haomin L, Zhendong F, Yi W. 2008. Spatial patterns of plant diversity and communities in Alpine ecosystems of the Hengduan Mountains, northwest Yunnan, China. Journal of Plant Ecology 1: 117-136.

[115]

Shi JP, Zhu H. 2009. Tree species composition and diversity of tropical mountain cloud forest in the Yunnan, southwestern China. Ecological Research 24: 83-92.

[116]

Smitinand T. 1966. The vegetation of Doi Chiengdao, a limestone massive in Chiengmai, north Thailand. Natural History Bulletin of The Siam Society 21: 93-128.

[117]

Soltis PS, Folk RA, Soltis DE. 2019. Darwin review: Angiosperm phylogeny and evolutionary radiations. Proceedings of the Royal Society B: Biological Sciences 286: 20190099.

[118]

Song X, Cao M, Li J, Kitching RL, Nakamura A, Laidlaw MJ, Tang Y, Sun Z, Zhang W, Yang J. 2021. Different environmental factors drive tree species diversity along elevation gradients in three climatic zones in Yunnan, southern China. Plant Diversity 43: 433-443.

[119]

Songtham W, Ratanasthien B, Mildenhall D, Singharajwarapan S, Kandharosa W. 2003. Oligocene–Miocene climatic changes in northern Thailand resulting from extrusion tectonics of Southeast Asian landmass. Science Asia 29: 221-233.

[120]

Songtham W, Ratanasthien B, Watanasak M, Mildenhall D, Singharajwarapan S, Kandharosa W. 2005. Tertiary basin evolution in northern Thailand: A palynological point of view. Natural History Bulletin of Siam Society 53: 17-32.

[121]

Songtham W, Watanasak M. 1999. Palynology, age, and paleoenvironment of Krabi Basin, southern Thailand. In: B Ratanasthien, SL Rieb eds. Proceedings of the International Symposium on Shallow Tethys (ST) 5. Chiang Mai: Department of Geological Science, Faculty of Science, Chiang Mai University. 426-439.

[122]

Stults DZ, Tiffney BH, Axsmith BJ. 2022. New observations on the last Pterocarya (Juglandaceae) occurrences in eastern North America. International Journal of Plant Sciences 183: 380-392.

[123]

Teejuntuk S, Sahunalu P, Sakurai K, Sungpalee W. 2003. Forest structure and tree species diversity along an altitudinal gradient in Doi Inthanon National Park, Northern Thailand. Tropics 12: 85-102.

[124]

Thongsangtum N, Huang J, Li SF, Thasod Y, Su T. 2024. Calophyllum (Calophyllaceae) from late Oligocene–Early Miocene of Li Basin, northern Thailand and its biogeographic and paleoclimatic implications. Palaeoworld 33: 1105-1118.

[125]

Tissot C, Chikhi H, Nayar TS. 1994. Pollen of wet evergreen forests of the Western Ghats, India. France: French Institute of Pondicherry.

[126]

Tolangay D, Pradhan B, Moktan S. 2024. Estimating tree species diversity and composition in temperate forests of Darjeeling Himalaya, India. The Journal of the Indian Botanical Society 104: 13-20.

[127]

Tosal A, Vicente A, Denk T. 2025. Cenozoic Ampelopsis and Nekemias leaves (Vitaceae, Ampelopsideae) from Eurasia: Paleobiogeographic and paleoclimatic implications. Journal of Systematics and Evolution 63: 379-400.

[128]

Turner RC, Midgley JJ, Johnson SD. 2011. Evidence for rodent pollination in Erica hanekomii (Ericaceae). Botanical Journal of the Linnean Society 166: 163-170.

[129]

Utsunomiya N, Subhadrabandhu S, Yonemori K, Oshida M, Kanzaki S, Nakatsubo F, Sugiura A. 1998. Diospyros species in Thailand: Their distribution, fruit morphology and uses. Economic Botany 52: 343-351.

[130]

Vieira M, Poças E, Pais J, Pereira DI. 2011. Pliocene flora from S. Pedro da Torre deposits (Minho, NW Portugal). Geodiversitas 33: 71-85.

[131]

Vieira M, Zetter R, Grímsson F, Denk T. 2023. Niche evolution versus niche conservatism and habitat loss determine persistence and extirpation in late Neogene European Fagaceae. Quaternary Science Reviews 300: 107896.

[132]

Watanasak M. 1990. Mid tertiary palynostratigraphy of Thailand. Journal of Southeast Asian Earth Sciences 4: 203-218.

[133]

Van Welzen PC, Svengsuksa BKK, Chayamarit K. 2019. Styracaceae. In: T Santisuk, K Chayamarit, H Balslev eds. Flora of Thailand, Vol. 14, part 2. Bangkok: Forest Herbarium, Royal Forest Department. 339-355.

[134]

WFO. 2024. World Flora Online Kew [online]. Available from http://www.worldfloraonline.org [accessed 16 June 2024].

[135]

Wu YH, Chao CT, Tseng YH. 2015. Eurya lui (Pentaphylacaceae), a new species in Taiwan. Quarterly Journal of Forest Research 37: 219-228.

[136]

Yabe A. 2002. Paleoclimatic condition inferred from the Tertiary plant megafossil assemblages from Northern Thailand. Primate Research 18: 143-157.

[137]

Yao YF, Zhao Q, Bera S, Li X, Li C. 2012. Pollen morphology of selected tundra plants from the high Arctic of Ny-Ålesund, Svalbard. Advances in Polar Science 23: 103-115.

[138]

Yumoto T, Momose K, Nagamasu H. 2000. A new pollination syndrome—Squirrel pollination in a tropical rain forest in Lambir Hills National Park, Sarawak, Malaysia. Tropics 9: 147-151.

[139]

Zetter R. 1989. Methodik und Bedeutung einer routinemäßig kombinierten lichtmikroskopischen und rasterelektronenmikroskopischen Untersuchung fossiler Mikrofloren. Courier Forschungsinstitut Senckenberg 109: 41-50.

[140]

Zetter R, Hesse M. 1996. The morphology of pollen tetrads and viscin threads in some Tertiary, Rhododendron-like Ericaceae. Grana 35: 285-294.

[141]

Zhao WY, Fritsch PW, Truong DOV, Fan Q, Yin QY, Penneys DS, Swenson U, Liao WB. 2019. Rehderodendron truongsonense (Styracaceae), a new species from Vietnam. Journal of the Botanical Research Institute of Texas 13: 157-171.

[142]

Zhou BF, Yuan S, Crowl AA, Liang YY, Shi Y, Chen XY, An QQ, Kang M, Manos PS, Wang B. 2022. Phylogenomic analyses highlight innovation and introgression in the continental radiations of Fagaceae across the Northern Hemisphere. Nature Communications 13: 1320.

[143]

Zhu H. 2016. Biogeographical evidences help revealing the origin of Hainan Island. PLoS One 11: e0151941.

[144]

Zhu H. 2019. Floristic divergence of the evergreen broad-leaved forests in Yunnan, southwestern China. Phytotaxa 393: 1-20.

[145]

Zhu H, Yong C, Zhou S, Wang H, Yan L. 2015. Vegetation, floristic composition and species diversity in a tropical mountain nature reserve in southern Yunnan, SW China, with implications for conservation. Tropical Conservation Science 8: 528-546.

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