Encyclopedia of Bromeliads

Bromeliaceae Literature: Ecology

Index: - A - B - C - D - E - F - G - H - I - J - L - M - N - O - P - R - S - T - U - V - W -

Titles are ordered by Genus or Subject, or look under 'Miscellaneous'.

Abiotic factors (1)

Göttlinger & Lohaus Influence of light, dark, temperature, and drought on metabolite and ion composition in nectar and nectaries of an epiphytic bromeliad species (Aechmea fasciata). Plant Biology n/a(n/a): -.

Aechmea (28)

Barberis 2020 (2020) Ramet demography of Aechmea distichantha (Bromeliaceae) in two contrasting years in the understory and open areas of a South American xerophytic forest. Rodriguésia 71: e00262018 (online).
Barberis et al. 2014 (2014) Two bromeliad species with contrasting functional traits partition the understory space in a South American xerophytic forest: correlative evidence of environmental control and limited dispersal. Plant Ecology 215(2): 143-153.
Barberis et al. 2021 (2021) Biogeography of different life forms of the southernmost neotropical tank bromeliad. Journal of Biogeography 2021(00): 1–13.
Barberis et al. 2022 (2022) Biogeography of different life forms of the southernmost neotropical tank bromeliad. Dryad x69p8czhw online.
Canela et al. 2003 (2003) Revision of the Aechmea multiflora complex (Bromeliaceae). Botanical journal of the Linnean Society 143: 189–196..
Cavallero et al. 2009 (2009) Morphological variation of Aechmea distichantha (Bromeliaceae) in a Chaco forest: habitat and size-related effects. Plant Biology 11(3): 379-391.
Cavallero et al. 2011 (2011) Morphological variation of the leaves of Aechmea distichantha Lem. plants from contrasting habitats of a Chaco forest: a trade-off between leaf area and mechanical support. Brazilian Journal of Biosciences 9(4): 455-464.
Ceusters et al. 2009 (2009) Differential usage of storage carbohydrates in the CAM bromeliad Aechmea ?Maya? during acclimation to drought and recovery from dehydration. Physiologia Plantarum 135(2): 174-184.
Costa et al 2022 (2022) Hybridization and species boundaries between three sympatric bromeliads from the Brazilian Atlantic Forest. Botanical Journal of the Linnean Society 198(4): 438-455.
Dejean & Olmsted 1997 (1997) Ecological studies on Aechmea bracteata (Swartz) (Bromeliaceae). Journal of Natural History 31: 1313-1334.
Dézerald et al. 2014 (22014013) Environmental determinants of macroinvertebrate diversity in small water bodies: insights from tank-bromeliads. Hydrobiologia 723: 77–86.
DUARTE et al. 2002 (2002) Acclimation or stress symptom? An integrated study of intraspecific variation in the clonal plant Aechmea bromeliifolia, a widespread CAM tank-bromeliad. Botanical Journal of the Linnean Society 140(4): 391-401.
Fernandes et al. 2015 (2015) Richness and abundance of Aechmea and Hohenbergia (Bromeliaceae) in forest fragments and shade cocoa plantations in two contrasting landscapes in Southern Bahia, Brazil. Tropical Conservation, Science 8: 58–75.
Goetze et al. 2015 (2015) Diversification of Bromelioideae in the Atlantic rainforest: a case study of Aechmea subgenus Ortgiesia. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.
Goetze et al. 2015 (2015) Phylogeography and population differentiation of seven Aechmea species from the Atlantic Rainforest. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.
Goetze et al. 2015 (2015) Genetic variation in Aechmea winkleri, a bromeliad from an inland Atlantic rainforest fragment in Southern Brazil. Biochemical Systematics and Ecology 58: 204-210.
Griffiths 1988 (1988) Carbon balance during CAM: an assessment of respiratory CO2 recycling in the epiphytic bromeliads Aechmea nudicaulis and Aechmea fendleri. Plant, Cell & Environment 11(7): 603-611.
Guimaraes-Souza et al. 2006 (2006) Limnological parameters in the water accumulated in tropical bromeliads. Acta Limnol. Bras 18(1): 47-53.
Lima et al. 2009 (2009) Survey of Invertebrates Associated with Bromeliads in a Conservation Unit of the Brazilian Atlantic Rainforest, and its Relevance for Environmental Risk Studies. Journal of the Bromeliad Society Int 59(6): 260-272.
Loh et al. 2015 (2015) Clonality strongly affects the spatial genetic structure of the nurse species Aechmea nudicaulis (L.) Griseb. (Bromeliaceae). Botanical Journal of the Linnean Society 178(2): 329-341.
Maciel et al. 2015d (2015) The Wallacean Shortfall in Aechmea. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.
Maciel et al. 2017 (2017) Palaeodistribution of epiphytic bromeliads points to past connections between the Atlantic and Amazon forests. Botanical Journal of the Linnean Society 183: 348–359.
Neves et al. 2015 (2015) Aechmea and allied genera (Bromelioideae, Bromeliaceae) from Serra dos Órgãos National Park, Rio de Janeiro, Brazil. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.
Petit et al. 2014 (2014) Are ontogenetic shifts in foliar structure and resource acquisition spatially conditioned in tank-bromeliads?. Botanical Journal of the Linnean Society 175(2): 299-312.
Pico-V 2020 (2018) First Record of Aechmea nallyi L.B.Sm. in Colombia. Journal of the Bromeliad Society 69(4): 188-197.
Talaga et al. 2015 (2015) A Bromeliad Species Reveals Invasive Ant Presence in Urban Areas of French Guiana. Ecological Indicators 58 (2015): 1–7. online.
Tarre et al. 2007 (2007) Germinability after desiccation, storage and cryopreservation of seeds from endemic Encholirium Mart. ex Schult. & Schult. f. and Dyckia Schult. & Schult. f. species (Bromeliaceae). Acta bot. bras 21(4): 777-783.
Winkler & Zotz 2009 (2009) Highly efficient uptake of phosphorus in epiphytic bromeliads. Annals of Botany 103 : 477–484.

Alcantarea (6)

Barbara et al. 2007 (2007) Population differentiation and species cohesion in two closely related plants adapted to neotropical high-altitude ‘inselbergs’, Alcantarea imperialis and Alcantarea geniculata (Bromeliaceae). Molecular Ecology 16: 1981–1992.
Barbara et al. 2008 (2008) Within-population spatial genetic structure in four naturally fragmented species of a neotropical inselberg radiation, Alcantarea imperialis, A. geniculata, A. glaziouana and A. regina (Bromeliaceae). Heredity 2008: 1-12 (online).
Barbara et al. 2009 (2009) Genetic relationships and variation in reproductive strategies in four closelyrelated bromeliads dapted to neotropical ‘inselbergs’: Alcantarea glaziouana, A. regina, A. geniculata and A. imperialis (Bromeliaceae). Annals of Botany 103(1): 65-77.
Lehmann et al. 2021 Using drone imagery to upscale estimates of water capacity in tank bromeliads on steep neotropical inselbergs. Austral Ecology 2021: 1-7 (online).
Mollo et al. 2011 (2011) Effects of low temperature on growth and non-structural carbohydrates of the imperial bromeliad Alcantarea imperialis cultured in vitro. Plant Cell Tiss Organ Cult 107: 141–149.
Mollo et al. 2019 (2019) Drought survival strategies of juvenile bromeliads of Alcantarea imperialis (Carrière) Harms. Plant Cell, Tissue and Organ Culture 139: 295–304.

Amazon (1)

Carvalho et al. 2024b (2024) Pitcairnia L' Hér (Bromeliaceae-Pitcairnioideae) diversity and distribution in the Brazilian Amazon. Biodiversity Data Journal 12(online): e136458.

Ananas (1)

Grol 2005 (2005) Effect of bromeliad (Pseudananas sagenarius) cover on seed predation and tree regeneration in tropical dry forest INPA, Bolivia. ibifbolivia.org.bo, 42 pp.

Andes (1)

Heathcote 2013 (2013) The Ecology of Vascular Epiphytes in the Peruvian Andes. Linacre College, Department of Plant Sciences, Oxford, 295 pp.

Animal (43)

Aguetoni Cambuí et al. 2009 (2009) Detection of urease in the cell wall and membranes from leaf tissues of bromeliad species. Physiologia Plantarum 136(1): 86-93.
Albert et al. 2014 (2014) Diversity and evolution of microsporogenesis in Bromeliaceae. Botanical Journal of the Linnean Society 176(1): 36-45.
Armbruster et al. 2002 (2002) Factors influencing community structure in a South American tank bromeliad fauna. Oikos 96(2): 225-234.
Benavides-Gordillo et al. 2019 (2019) Changes in rainfall level and litter stoichiometry affect aquatic community and ecosystem processes in bromeliad phytotelmata. Freshwater Biology 64(8): 1357-1368.
Bueno et al. 2012 (2012) Arachnids and Myriapods in Tillandsia imperialis and Tillandsia deppeana (Bromeliaceae) from Hidalgo State, Mexico. , pp.
Canela & Sazima 2003 (2003) Florivory by the Crab Armases angustipes (Grapsidae) Influences Hummingbird Visits to Aechmea pectinata (Bromeliaceae)1. Biotropica 35(2): 289-294.
Castaño & Palacios 2016 (2016) The Role of Arthropods in the Growth of Tillandsia violacea (Bromeliaceae) in a Mexican Temperate Forest. The American Midland Naturalist 175(2): 286-294.
Céréghino et al. 2018 (2018) Constraints on the functional trait space of aquatic invertebrates in bromeliads. Functional Ecology 32(10): 2435-2447.
Cotgreave et al. 1993 (1993) The relationship between body size and population size in bromeliad tank faunas. Biological Journal of the Linnean Society 49(4): 367-380.
Darocha et al. 2021 (2021) Disentangling the factors that shape bromeliad and ant communities in the canopies of cocoa agroforestry and preserved Atlantic Forest. Biotropica 2021; 00: 1–12.
DE OMENA & ROMERO 2008 (2008) Fine-scale microhabitat selection in a bromeliad-dwelling jumping spider (Salticidae). Biological Journal of the Linnean Society 94(4): 653-662.
Dézerald et al. 2015 (2015) Functional trait responses of aquatic macroinvertebrates to simulated drought in a Neotropical bromeliad ecosystem. Freshwater Biology 60(9): 1917-1929.
Dézerald et al. 2017 (2017) Environmental drivers of invertebrate population dynamics in Neotropical tank bromeliads. Freshwater Biology 62(2): 229-242.
Favretto et al. 2011 (2011) Insects in Two Bromeliad Species in the West of Santa Catarina, Brazil. EntomoBrasilis 4(1): 10-12.
Foissner & 2013 (2013) Description of Glaucomides bromelicola n. gen., n. sp. (Ciliophora, Tetrahymenida), a Macrostome Forming Inhabitant of Bromeliads (Bromeliaceae), Including Redescriptions of Glaucoma scintillans and G. reniformis. Journal of Eukaryotic Microbiology 60(2): 137-157.
Foissner & Stoeck 2013 (2013) Morphology of Bromeliophrya quadristicha n. spec., an Inhabitant of Tank Bromeliads (Bromeliaceae), and Phylogeny of the Bromeliophryidae (Ciliophora, Tetrahymenida). Journal of Eukaryotic Microbiology 60(3): 223-234.
Galindo et al. 2003 (2003) Arboreal frogs, tank bromeliads and disturbed seasonal tropical forest . Contemporary Herpetology 2003(1): 1-12.
Gomez et al. 2017 (2017) The use of epiphytic Bromeliads by Ateles geoffroyi Kuhl (Primates, Mammalia) in Chiapas, Mexico. Journal of the Bromeliad Society 66(1): 26-33.
Guzmán et al. 2012 (2012) Arthropods associated with three Species of Tillandsia (Bromeliaceae) in undisturbed and secondary Cloud Forest. , pp.
Hornung & Palacios 2012 (2012) Tillandsia imperialis (Bromeliaceae) as a refuge of Collembola in cloud forest Hidalgo State, and ciscovery of a new Sminthurinus. , pp.
Jocque & Kolby 2012 (2012) Acidity of tank bromeliad water in a cloud forest, Cusuco National Park, Honduras. International Journal of Plant Physiology and Biochemistry 4(4): 59-70.
Louca et al. 2017 (2017) Functional structure of the bromeliad tank microbiome is strongly shaped by local geochemical conditions. Environmental Microbiology 19(8): 3132-3151.
Mejía et al. 2012 (2012) Microarthropods (Collembola and Mites) found in two species of Tillandsia (Bromeliaceae) from Oaxaca. , pp.
Mestre et al. 2001 (2001) Macroinvertebrate Fauna Associated to the Bromeliad Vriesea inflata of the Atlantic Forest (Paraná State, Southern Brazil). Brazilian Archives of Biology and Technology 44(1): 89 - 94.
Mosdossy et al. 2015 (2015) Quantifying seasonal fallback on invertebrates, pith, and bromeliad leaves by white-faced capuchin monkeys (Cebus capucinus) in a tropical dry forest. American Journal of Physical Anthropology 158(1): 67-77.
Oliveira & Rocha 1997 (1997) The Effect Of Complexity Of The Tank Bromeliad Neoregelia cruenta (R. Graham) L. B. Smith, On The Associated Animal Community. Revista Bromélia 4(2): 13-22.
Omena et al. 2018 (2018) Bromeliads provide shelter against fire to mutualistic spiders in a fire-prone landscape. In: . Ecological Entomology 43(3): 389-393.
Richardson & 1999 (1999) The Bromeliad Microcosm and the Assessment of Faunal Diversity in a Neotropical Forest1. Biotropica 31(2): 321-336.
Richardson et al. 2000 (2000) Effects of nutrient availability and other elevational changes on bromeliad populations and their invertebrate communities in a humid tropical forest in Puerto Rico. Journal of Tropical Ecology 16: 167-188.
Richardson et al. 2015 (2015) The Stability of Invertebrate Communities in Bromeliad Phytotelmata in a Rain Forest Subject to Hurricanes. Biotropica 47(2): 201-207.
Rio et al. 2021 (2021) Spatial distribution and interannual variability of coastal fog and low clouds cover in the hyperarid Atacama Desert and implications for past and present Tillandsia landbeckii ecosystems. Plant Systematics and Evolution 307(5): 58.
Rogy et al. 2019 (2019) Complex indirect effects of epiphytic bromeliads on the invertebrate food webs of their support tree. Biotropica 51(4): 549-561.
Romero & Mondragón 2012 (2012) Bromeliad freshwater Meiofauna community from Pine-oak Forest. , pp.
Romero & Vasconcellos 2005 (2005) The effects of plant structure on the spatial and microspatial distribution of a bromeliad-living jumping spider (Salticidae). Journal of Animal Ecology 74(1): 12-21.
Romero & Vasconcellos-Neto 2004 (2004) Spatial Distribution Patterns of Jumping Spiders Associated with Terrestrial Bromeliads. Biotropica 36(4): 596-601.
Romero et al. 2007 (2007) Association of two New Coryphasia species (Araneae, Salticidae) With Tank-bromeliads In southeastern Brazil: Habitats and patterns of Host plant use. The Journal of Arachnology 35: 181–192.
Romero et al. 2010 (2010) Nitrogen fluxes from treefrogs to tank epiphytic bromeliads: an isotopic and physiological approach. Oecologia 162: 941–949.
Silva et al. 2011 (2011) Selecting a Hiding Place: Anuran Diversity and the use of Bromeliads in a Threatened Coastal Sand Dune Habitat in Brazil. Biotropica 43(2): 218-227.
Simão et al. 2020 (2020) Remarkably Complex Microbial Community Composition in Bromeliad Tank Waters Revealed by eDNA Metabarcoding. Journal of Eukaryotic Microbiology 67(5): 593-607.
Srivastava et al. Habitat size thresholds for predators: Why damselflies only occur in large bromeliads. Biotropica n/a(n/a): -.
Talaga et al. 2015 (2015) A Bromeliad Species Reveals Invasive Ant Presence in Urban Areas of French Guiana. Ecological Indicators 58 (2015): 1–7. online.
Vasconcelos et al. 2017 (2017) Mutualism influences species distribution predictions for a bromeliad-breeding anuran under climate change. Austral Ecology 42(7): 869-877.
Vosgueritchian & Buzato 2006 (2006) Reprodução sexuada de Dyckia tuberosa (Vell.) Beer (Bromeliaceae), Pitcairnioideae) e interação planta-animal. Revista Brasileira de Botânica 29 (3): 433–442.

Animals (40)

Aguetoni Cambuí et al. 2009 (2009) Detection of urease in the cell wall and membranes from leaf tissues of bromeliad species. Physiologia Plantarum 136(1): 86-93.
Albert et al. 2014 (2014) Diversity and evolution of microsporogenesis in Bromeliaceae. Botanical Journal of the Linnean Society 176(1): 36-45.
Armbruster et al. 2002 (2002) Factors influencing community structure in a South American tank bromeliad fauna. Oikos 96(2): 225-234.
Benavides-Gordillo et al. 2019 (2019) Changes in rainfall level and litter stoichiometry affect aquatic community and ecosystem processes in bromeliad phytotelmata. Freshwater Biology 64(8): 1357-1368.
Bueno et al. 2012 (2012) Arachnids and Myriapods in Tillandsia imperialis and Tillandsia deppeana (Bromeliaceae) from Hidalgo State, Mexico. , pp.
Canela & Sazima 2003 (2003) Florivory by the Crab Armases angustipes (Grapsidae) Influences Hummingbird Visits to Aechmea pectinata (Bromeliaceae)1. Biotropica 35(2): 289-294.
Castaño & Palacios 2016 (2016) The Role of Arthropods in the Growth of Tillandsia violacea (Bromeliaceae) in a Mexican Temperate Forest. The American Midland Naturalist 175(2): 286-294.
Céréghino et al. 2018 (2018) Constraints on the functional trait space of aquatic invertebrates in bromeliads. Functional Ecology 32(10): 2435-2447.
Cotgreave et al. 1993 (1993) The relationship between body size and population size in bromeliad tank faunas. Biological Journal of the Linnean Society 49(4): 367-380.
DE OMENA & ROMERO 2008 (2008) Fine-scale microhabitat selection in a bromeliad-dwelling jumping spider (Salticidae). Biological Journal of the Linnean Society 94(4): 653-662.
Dézerald et al. 2015 (2015) Functional trait responses of aquatic macroinvertebrates to simulated drought in a Neotropical bromeliad ecosystem. Freshwater Biology 60(9): 1917-1929.
Dézerald et al. 2017 (2017) Environmental drivers of invertebrate population dynamics in Neotropical tank bromeliads. Freshwater Biology 62(2): 229-242.
Favretto et al. 2011 (2011) Insects in Two Bromeliad Species in the West of Santa Catarina, Brazil. EntomoBrasilis 4(1): 10-12.
Foissner & 2013 (2013) Description of Glaucomides bromelicola n. gen., n. sp. (Ciliophora, Tetrahymenida), a Macrostome Forming Inhabitant of Bromeliads (Bromeliaceae), Including Redescriptions of Glaucoma scintillans and G. reniformis. Journal of Eukaryotic Microbiology 60(2): 137-157.
Foissner & Stoeck 2013 (2013) Morphology of Bromeliophrya quadristicha n. spec., an Inhabitant of Tank Bromeliads (Bromeliaceae), and Phylogeny of the Bromeliophryidae (Ciliophora, Tetrahymenida). Journal of Eukaryotic Microbiology 60(3): 223-234.
Galindo et al. 2003 (2003) Arboreal frogs, tank bromeliads and disturbed seasonal tropical forest . Contemporary Herpetology 2003(1): 1-12.
Gomez et al. 2017 (2017) The use of epiphytic Bromeliads by Ateles geoffroyi Kuhl (Primates, Mammalia) in Chiapas, Mexico. Journal of the Bromeliad Society 66(1): 26-33.
Guzmán et al. 2012 (2012) Arthropods associated with three Species of Tillandsia (Bromeliaceae) in undisturbed and secondary Cloud Forest. , pp.
Hornung & Palacios 2012 (2012) Tillandsia imperialis (Bromeliaceae) as a refuge of Collembola in cloud forest Hidalgo State, and ciscovery of a new Sminthurinus. , pp.
Jocque & Kolby 2012 (2012) Acidity of tank bromeliad water in a cloud forest, Cusuco National Park, Honduras. International Journal of Plant Physiology and Biochemistry 4(4): 59-70.
Louca et al. 2017 (2017) Functional structure of the bromeliad tank microbiome is strongly shaped by local geochemical conditions. Environmental Microbiology 19(8): 3132-3151.
Mejía et al. 2012 (2012) Microarthropods (Collembola and Mites) found in two species of Tillandsia (Bromeliaceae) from Oaxaca. , pp.
Mosdossy et al. 2015 (2015) Quantifying seasonal fallback on invertebrates, pith, and bromeliad leaves by white-faced capuchin monkeys (Cebus capucinus) in a tropical dry forest. American Journal of Physical Anthropology 158(1): 67-77.
Oliveira & Rocha 1997 (1997) The Effect Of Complexity Of The Tank Bromeliad Neoregelia cruenta (R. Graham) L. B. Smith, On The Associated Animal Community. Revista Bromélia 4(2): 13-22.
Omena et al. 2018 (2018) Bromeliads provide shelter against fire to mutualistic spiders in a fire-prone landscape. In: . Ecological Entomology 43(3): 389-393.
Richardson & 1999 (1999) The Bromeliad Microcosm and the Assessment of Faunal Diversity in a Neotropical Forest1. Biotropica 31(2): 321-336.
Richardson et al. 2000 (2000) Effects of nutrient availability and other elevational changes on bromeliad populations and their invertebrate communities in a humid tropical forest in Puerto Rico. Journal of Tropical Ecology 16: 167-188.
Richardson et al. 2015 (2015) The Stability of Invertebrate Communities in Bromeliad Phytotelmata in a Rain Forest Subject to Hurricanes. Biotropica 47(2): 201-207.
Rio et al. 2021 (2021) Spatial distribution and interannual variability of coastal fog and low clouds cover in the hyperarid Atacama Desert and implications for past and present Tillandsia landbeckii ecosystems. Plant Systematics and Evolution 307(5): 58.
Rogy et al. 2019 (2019) Complex indirect effects of epiphytic bromeliads on the invertebrate food webs of their support tree. Biotropica 51(4): 549-561.
Romero & Mondragón 2012 (2012) Bromeliad freshwater Meiofauna community from Pine-oak Forest. , pp.
Romero & Vasconcellos 2005 (2005) The effects of plant structure on the spatial and microspatial distribution of a bromeliad-living jumping spider (Salticidae). Journal of Animal Ecology 74(1): 12-21.
Romero & Vasconcellos-Neto 2004 (2004) Spatial Distribution Patterns of Jumping Spiders Associated with Terrestrial Bromeliads. Biotropica 36(4): 596-601.
Romero et al. 2007 (2007) Association of two New Coryphasia species (Araneae, Salticidae) With Tank-bromeliads In southeastern Brazil: Habitats and patterns of Host plant use. The Journal of Arachnology 35: 181–192.
Romero et al. 2010 (2010) Nitrogen fluxes from treefrogs to tank epiphytic bromeliads: an isotopic and physiological approach. Oecologia 162: 941–949.
Silva et al. 2011 (2011) Selecting a Hiding Place: Anuran Diversity and the use of Bromeliads in a Threatened Coastal Sand Dune Habitat in Brazil. Biotropica 43(2): 218-227.
Simão et al. 2020 (2020) Remarkably Complex Microbial Community Composition in Bromeliad Tank Waters Revealed by eDNA Metabarcoding. Journal of Eukaryotic Microbiology 67(5): 593-607.
Srivastava et al. Habitat size thresholds for predators: Why damselflies only occur in large bromeliads. Biotropica n/a(n/a): -.
Vasconcelos et al. 2017 (2017) Mutualism influences species distribution predictions for a bromeliad-breeding anuran under climate change. Austral Ecology 42(7): 869-877.
Vosgueritchian & Buzato 2006 (2006) Reprodução sexuada de Dyckia tuberosa (Vell.) Beer (Bromeliaceae), Pitcairnioideae) e interação planta-animal. Revista Brasileira de Botânica 29 (3): 433–442.

Ant-garden (2)

Céréghino et al. 2010 (2010) Ants mediate the structure of phytotelm communities in an ant-garden bromeliad. Ecology 91(5): 1549-1556.
Leroy et al. 2012 (2012) Ant species identity mediates reproductive traits and allocation in an ant-garden bromeliad. Annals of Botany 109: 145-152.

Argentina (4)

Barberis 2020 (2020) Ramet demography of Aechmea distichantha (Bromeliaceae) in two contrasting years in the understory and open areas of a South American xerophytic forest. Rodriguésia 71: e00262018 (online).
Barberis et al. 2011 (2011) Terrestrial bromeliads as seed accumulation microsites in a xerophytic forest of Southern Chaco, Argentina. BOSQUE 32(1): 57-63.
Klekailo et al. 2012 (2012) The effects of temperature, light environment and scarification on seed germination of bromelia serra griseb. (bromeliaceae). Rev. bras. sementes 34(4): 605-612.
Medina 1990 (1990) Eco-fisiologia y Evolucion de las Bromeliaceae . Boletin de la Academia Nacional de Ciencias 59: 71-100.

Atlantic forest (9)

Basilio et al. 20115 (2015) Community ecology of epiphytic Bromeliaceae in a remnant of Atlantic Forest in Zona da Mata, Minas Gerais State, Brazil. Hoehnea 42(1): 21-31, 3 tab., 3 fig..
Brandao et al. 2009 (2009) Analysis and Visualization of the Geographical Distribution of Atlantic Forest Bromeliads Species. , pp.
Costa et al 2022 (2022) Hybridization and species boundaries between three sympatric bromeliads from the Brazilian Atlantic Forest. Botanical Journal of the Linnean Society 198(4): 438-455.
Darocha et al. 2021 (2021) Disentangling the factors that shape bromeliad and ant communities in the canopies of cocoa agroforestry and preserved Atlantic Forest. Biotropica 2021; 00: 1–12.
Machado et al. 2021 (2021) Neglected epiphytism: Accidental epiphytes dominate epiphytic communities on tree ferns in the Atlantic Forest. Biotropica 2021(00): 1–11 online.
Matos et al. 20115 (2015) Limited pollen flow and high selfing rates towards geographic range limit in an Atlantic forest bromeliad. Flora 211: 1-10.
Matos et al. 2022 (2022) Spatiotemporal Variation on Fertility, Mating System, and Gene Flow in Vriesea gigantea (Bromeliaceae), an Atlantic Forest Species. Frontiers .
Mestre et al. 2001 (2001) Macroinvertebrate Fauna Associated to the Bromeliad Vriesea inflata of the Atlantic Forest (Paraná State, Southern Brazil). Brazilian Archives of Biology and Technology 44(1): 89 - 94.
Rocha et al. 2015 (2014) Positive association between Bromelia balansae (Bromeliaceae) and tree seedlings on rocky outcrops of Atlantic forest. Journal of Tropical Ecology 31(2): 195-198.

Atmospheric bromeliad (1)

Chaves et al. 2016 (2016) Host trait combinations drive abundance and canopy distribution of atmospheric bromeliad assemblages. AoB PLANTS 8: 1–13.

Betaine (1)

Adrian-Romero et al. 2001 (2001) Betaine distribution in the Bromeliaceae. Biochemical Systematics and Ecology 29: 305-311.

Biomass (2)

Dezerald et al. 2018 (2018) Tank bromeliads sustain high secondary production in neotropical forests. Aquatic Sciences 80:14 (1-12).
LeCraw & Srivastava 2019 (2019) Biogeographic context dependence of trophic cascade strength in bromeliad food webs. Ecology 100(7): e02692-.

Biomass turnover (1)

Dezerald et al. 2018 (2018) Tank bromeliads sustain high secondary production in neotropical forests. Aquatic Sciences 80:14 (1-12).

Bolivia (10)

Fredericksen et al. 1999 (1999) Ecología de la bromeliácea terrestre Pseudananas sagenarius (Bromeliaceae, Bromelioideae) en bosques secos de Bolivia. Revista de la Sociedad Boliviana Botánica 2(2): 165-173.
Grol 2005 (2005) Effect of bromeliad (Pseudananas sagenarius) cover on seed predation and tree regeneration in tropical dry forest INPA, Bolivia. ibifbolivia.org.bo, 42 pp.
Ibisch et al. 1999a (1999) Puya raimondii Harms in Bolivien - ein Fall für den Artenschutz ?. Deutsche Bromelien-Gesellschaft, 32 pages pp.
Kessler 2002 (2002) Environmental patterns and ecological correlates of range size among bromeliad communities of Andean forests in Bolivia. The Botanical review, interpreting botanical progress 68(1): 100-127.
Kessler 2002 (2002) Species richness and ecophysiological types among Bolivian bromeliad communities. Biodiversity and Conservation 11: 987-1010.
Kessler 2002 (2002) Species richness and ecophysiological types among Bolivian bromeliad communities. Biodiversity and Conservation 11: 987–1010.
Kromer 2000 (2000) Distribution of terrestrial bromeliads along the La Paz to Caranavi road in Bolivia. Journal of the Bromeliad Society 50(4): 158-164.
Kromer 2004 (2004) Diversity and ecology of epiphytic bromeliads along an elevational gradient in the Andes of Bolivia. Journal of the Bromeliad Society 54(5): 217-221, 225.
Kromer et al. 2006 (2006) Distribution and Flowering Ecology of Bromeliads along Two Climatically Contrasting Elevational Transects in the Bolivian Andes. Biotropica 38(2): 183–195.
Krömer et al. 1999 (1999) Notes on species distribution and levels of endemism (Bromeliaceae, Bolivia). Selbyana; 20(2): 201-223.

Brazil (80)

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Adrian-Romero et al. 2001 (2001) Betaine distribution in the Bromeliaceae. Biochemical Systematics and Ecology 29: 305-311.
Almeida 2015 (2015) Chemical and pharmacological properties of Bromeliaceae species from the Caatinga biome. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.
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Arevalo et al. 2006 (2006) Vertical distribution of Vascular Epiphytes in four forest types of the Serrania de Chiribiquete, Colombian Guayana. Selbyana 27(2): 175-185.
Benzing 1980 (1980) The biology of the bromeliads. Mad River Press, Eureka California USA, 305 pp.
Benzing 2000 (2000) Bromeliaceae. Profile of an adaptive radiation. Cambridge University Press UK, 690 pp.
Benzing 2023 (2023) Bromeliaceae: A brief Profile and some Topics that Warrant Further Inquiry. Selbyana 34: 1–79.
Chedier & Kaplan 1996 (1996) Chemical ecology of three species of Bromeliaceae. National Museum Univ. Rio de Janeiro Brazil, pp.
Costa 1995 (1995) On the Bromeliaceae of the restinga of Barra de Marica in Brazil: environmental influences of Crassulacean Acid Metabolism. University of Newcastle upon Tyne UK, pp.
Crayn et al. 2004 (2004) Multiple origins of crassulacean acid metabolism and the epiphytic habit in the Neotropical family Bromeliaceae. PNAS 101(10): 3703-3708.
Cuatrecasas 1958 (1958) Aspectos de la vegetacion natural de Colombia. Revista de la Academia Colombiana de Ciencias Exactas, Fisicas y Naturales 10: 221-268.
Frank 1983 (1983) Phytotelmata - terrestrial plants as hosts for aquatic communities. Bromeliad phytotelmata and their biota, especially mosquitos. Plexus, Medford New Jersey USA, 28 pp.
Gilmartin 1973 (1973) Transandean Distributions of Bromeliaceae in Ecuador quick view. Ecology 54(6): 1389-1393.
Gouda 1995 (1995) Bromeliaceeën - aanpassingen aan epifytische en epilithische leefwijze. University Botanic Gardens, Utrecht, 44 pp.
Janetzky & Vareschi 1993 (1993) Phytotelmata in bromeliads as microhabitats for limnatic organisms. In: Animal plant interactions in tropical environments. Zool. Forschungsinstitut Mus. A. Koenig, Bonn Germany, pp. 199–209.
Kessler 2002 (2002) Environmental patterns and ecological correlates of range size among bromeliad communities of Andean forests in Bolivia. The Botanical review, interpreting botanical progress 68(1): 100-127.
Kessler 2002 (2002) Species richness and ecophysiological types among Bolivian bromeliad communities. Biodiversity and Conservation 11: 987-1010.
Kockel 1995 (1995) An Grenzstandorten Der Neuen Welt - Die Bromelien. Wilhelma, 72 pp.
Kromer 2000 (2000) Distribution of terrestrial bromeliads along the La Paz to Caranavi road in Bolivia. Journal of the Bromeliad Society 50(4): 158-164.
Kromer 2004 (2004) Diversity and ecology of epiphytic bromeliads along an elevational gradient in the Andes of Bolivia. Journal of the Bromeliad Society 54(5): 217-221, 225.
Krömer 1997 (1997) Untersuchungen zur Verbreitung, Ökologie und Nektarzusammensetzung von Bromeliaceen. Systematisch-Geobotanisch Institut Universität Göttingen, Germany, pp.
Krömer et al. 1999 (1999) Notes on species distribution and levels of endemism (Bromeliaceae, Bolivia). Selbyana; 20(2): 201-223.
Larson & Frank 2002 (2002) Bromeliads and bromeliad weevils of Florida. Coop. Ext. Service, Univ. of Florida, Inst. of Food and Agricultural Sciences USA, pp.
Lasso 2001 (2001) Reproductive constraints in an elfin forest: Bromeliads. Univ. Puerto Rico, Rio Piedras, pp.
Lima & Vidal 1996 (1996) Bromélias da Reserva Ecológica Rio das Pedras. Unibanco / Club Med, Brazil, 68 pp.
Machado & Neto 2010 (2010) Bromeliaceæ de um campo de altitude no sul de Minas Gerais (Brasil). Fontqueria 56(11): 109-124.
Marques 2002 (2002) Ecofisiologia e contribuições para a conservação das bromélias da Serra da Piedade. Universidadede Federal de Minas Gerais, Belo Horizonte, Brazil, pp.
Martin 1994 (1994) Physiological ecology of the Bromeliaceae. The Botanical review 60(1): 1-82.
Martinelli 1994 (1994) Reproductive biology of Bromeliaceae in the Atlantic rainforest of Southeastern Brazil. Univ. of St. Andrews, Scotland UK, 220 pp.
Martinelli 2015 (2015) The Brazilian Red-List of Flora: Bromeliaceae. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.
Picado 1913 (1913) Les Bromeliacées epiphytes considerées comme milieu biologique. Paris France, 146 pp.
Rundel & Dillon 1998 (1998) Ecological patterns in the Bromeliaceae of the lomas formations of coastal Chile and Peru. Plant Systematics and Evolution 212: 261-278.
Sarthou et al. 1998 (1998) Epilithic plant communities on inselbergs in French Guiana. Journal of Vegetation Science 9: 847-860.
Siqueira Filho 2003 (2003) História natural, fenologia da floração, ecologia da polinização e conservação de Bromeliaceae na floresta Atlântica Nordestina. Univ. Federal de Pernambuco, Recife Brazil, 144 pp.
Smith 1989 (1989) Epiphytic bromeliads. In: Lüttge, U. (ed) Vascular plants as epiphytes, evolution and ecophysiology. Springer Verlag, Berlin Germany, pp. 109–138.
Strehl 1994 (1994) Bromélias que passam parte do ano submersas. Bromélia 1: 19–21.
Taylor et al. 2021 (2021) Vascular epiphytes contribute disproportionately to global centres of plant diversity. bioRxiv 2021.05.21.445115. Web..
Utley & Burt-Utley 1977 (1977) Biologia de las Bromeliaceas (Phytogeography, physiological ecology and the Costa Rican genera of Bromeliaceae). Departamento de Historia Natural Museo National de Costa Rica, San Jose, pp. 9–29.
Versieux et al. 2004 (2004) Bromeliaceae no Parque Natural do Caraça. Sociedade Botânica do Brasil & Universidade Federal de Viçosa, Viçosa, Minas Gerais .
Zotz & Cascante 2024 (2024) Life on the Wire - Plant Growth on Power Lines in the Americas. Diversity 16(9): 1-13 (online).

C3 (6)

Griffiths et al. 1986 (1986) Comparative ecophysiology of CAM and C3 bromeliads. III. Environmental influences on CO2 assimilation and transpiration. Plant, Cell & Environment 9(5): 385-393.
Lüttge et al. 1986 (1986) Comparative ecophysiology of CAM and C3 bromeliads. II. Field measurements of gas exchange of CAM bromeliads in the humid tropics. Plant, Cell & Environment 9(5): 377-383.
Males & Griffiths 2017 (2017) Specialized stomatal humidity responses underpin ecological diversity in C3 bromeliads. Plant, Cell & Environment 40(12): 2931-2945.
Maxwell et al. 1992 (1992) Photoinhibitory responses of the epiphytic bromeliad Guzmania monostachia during the dry season in Trinidad maintain photochemical integrity under adverse conditions. Plant, Cell & Environment 15(1): 37-47.
Smith et al. 1986 (1986) Comparative ecophysiology of CAM and C3 bromeliads. I. The ecology of the Bromeliaceae in Trinidad. Plant, Cell & Environment 9(5): 359-376.
Smith et al. 1986 (1986) Comparative ecophysiology of CAM and C3 bromeliads. IV. Plant water relations. Plant, Cell & Environment 9(5): 395-410.

Cam (18)

Abreu et al. 2018 (2018) Antioxidant capacity along the leaf blade of the C3-CAM facultative bromeliad Guzmania monostachia under water deficit conditions. Funct. Plant Biol 45 : 620-629.
Ceusters et al. 2009 (2009) Differential usage of storage carbohydrates in the CAM bromeliad Aechmea ?Maya? during acclimation to drought and recovery from dehydration. Physiologia Plantarum 135(2): 174-184.
Crayn et al. 2015 (2015) Photosynthetic pathways in Bromeliaceae: phylogenetic and ecological significance of CAM and C3 based on carbon isotope ratios for 1893 species. Botanical Journal of the Linnean Society 178(2): 169–221.
Fontoura & Reinert 2009 (2009) Habitat utilization and CAM occurrence among epiphytic bromeliads in a dry forest from southeastern Brazil. Revista Brasil. Bot 32(3): 521-530.
Freschi et al. 2010 (2010) Specific leaf areas of the tank bromeliad Guzmania monostachia perform distinct functions in response to water shortage. J. Plant Physiol 167 : 526-533.
Griffiths 1988 (1988) Carbon balance during CAM: an assessment of respiratory CO2 recycling in the epiphytic bromeliads Aechmea nudicaulis and Aechmea fendleri. Plant, Cell & Environment 11(7): 603-611.
Griffiths et al. 1986 (1986) Comparative ecophysiology of CAM and C3 bromeliads. III. Environmental influences on CO2 assimilation and transpiration. Plant, Cell & Environment 9(5): 385-393.
Lüttge et al. 1986 (1986) Comparative ecophysiology of CAM and C3 bromeliads. II. Field measurements of gas exchange of CAM bromeliads in the humid tropics. Plant, Cell & Environment 9(5): 377-383.
LÜTTGE et al. 1986 (1986) Comparative ecophysiology of CAM and C3 bromeliads. V. Gas exchange and leaf structure of the C3 bromeliad Pitcairnia integrifolia. Plant, Cell & Environment 9(5): 411-419.
Maxwell et al. 1992 (1992) Photoinhibitory responses of the epiphytic bromeliad Guzmania monostachia during the dry season in Trinidad maintain photochemical integrity under adverse conditions. Plant, Cell & Environment 15(1): 37-47.
Pierce et al. 2002 (2002) The role of CAM in high rainfall cloud forests: an in situ comparison of photosynthetic pathways in Bromeliaceae. Plant, Cell & Environment 25(9): 1181-1189.
Popp et al. 2003 (2003) Metabolite gradients and carbohydrate translocation in rosette leaves of CAM and C3 bromeliads. New Phytologist 157(3): 649-656.
Quezada et al. 2018 (2018) Crassulacean acid metabolism and distribution range in Chilean Bromeliaceae: Influences of climate and phylogeny. Journal of Biogeography 45(7): 1541-1549.
Rosado-Calderón et al. 2020 (2020) High resilience to extreme climatic changes in the CAM epiphyte Tillandsia utriculata L. (Bromeliaceae). Physiologia Plantarum 168(3): 547-562.
Schmitt et al. 1989 (1989) Gas Exchange and Water Vapor Uptake in the Atmospheric CAM Bromeliad Tillandsia recurvata L.: The Influence of Trichomes. Botanica Acta 102(1): 80-84.
Smith et al. 1986 (1986) Comparative ecophysiology of CAM and C3 bromeliads. I. The ecology of the Bromeliaceae in Trinidad. Plant, Cell & Environment 9(5): 359-376.
Smith et al. 1986 (1986) Comparative ecophysiology of CAM and C3 bromeliads. IV. Plant water relations. Plant, Cell & Environment 9(5): 395-410.
Wagner & Zotz 2018 (2018) Epiphytic bromeliads in a changing world: the effect of elevated CO2 and varying water supply on growth and nutrient relations. Plant Biology 20(3): 636-640.

Canistropsis (1)

Freitas & Rocha 2007 (2007) Spatial distribution by Canistropsis microps (E. Morren ex Mez)Leme (Bromeliaceae: Bromelioideae) in theAtlantic rain forest in Ilha Grande, Southeastern Brazil. Braz. J. Biol 67(3): 467-474.

Carnivores (1)

JOEL & 1988 (1988) Mimicry and mutualism in carnivorous pitcher plants (Sarraceniaceae, Nepenthaceae, Cephalotaceae, Bromeliaceae). Biological Journal of the Linnean Society 35(2): 185-197.

Catopsis (5)

Castillo et al. 2013 (2013) Possible combined effects of climate change, deforestation, and harvesting on the epiphyte Catopsis compacta: a multidisciplinary approach. Ecology and Evolution 3(11): 1-10.
Kartzinel et al. 2016 (2016) Spatial Patterns of Haplotype Variation in the Epiphytic Bromeliad Catopsis nutans. Biotropica 48(2): 206-217.
Marín et al. 2008 (2008) Establishment of Epiphytic Bromeliads in Successional Tropical Premontane Forests in Costa Rica. Biotropica 40(4): 441-448.
Winkler et al. 2007 (2007) Population dynamics of epiphytic bromeliads: Lifestrategies and the role of host branches. Basic and Applied Ecology 8: 183-196.
Zotz & Laube 2005 (2005) Tank function in the epiphytic bromeliad, Catopsis sessiliflora. ECOTROPICA 11: 63–68.

Chile (9)

Koch et al. 2022 (2022) Range expansion and contraction of Tillandsia landbeckii lomas in the hyperarid Chilean Atacama Desert indicates ancient introgression and geneflow. Perspectives in Plant Ecology, Evolution and Systematics 56: 1-14 (online 125689).
Loayza et al. 2024 (2024) Reproductive variation and germination capacity of Tillandsia landbeckii Phil. in the southernmost Tillandsia dune of the Atacama Desert. Gayana Botanica 81(1): 22-31.
Marcus et al. 2019 (2019) Living at the dry limits: ecological genetics of Tillandsia landbeckii lomas in the Chilean Atacama Desert. Plant Systematics and Evolution (2019) 305: 1041–1053.
Merklinger et al. 2020 (2020) Population genomics of Tillandsia landbeckii reveals unbalanced genetic diversity and founder effects in the Atacama Desert. Global and Planetary Change 184: 103076.
Ortega-Solis et al. 2020 (2020) The importance of tree species and size for the epiphytic bromeliad Fascicularia bicolor in a South-American temperate rainforest (Chile). iForest - Biogeosciences and Forestry 13(2): 92-97.
Osses et al. 2007 (2007) Distribution and geographical factors of the Tillandsia fields in the coastal mountain range of the Tarapac´a Region, Chile . In: Biggs, A., Cereceda, C. (Eds.), Proceedings of Fourth Internacional Conference on Fog, Fog Collection and Dew. La Serena, Chile. 93–96.
Quezada et al. 2018 (2018) Crassulacean acid metabolism and distribution range in Chilean Bromeliaceae: Influences of climate and phylogeny. Journal of Biogeography 45(7): 1541-1549.
Rundel & Dillon 1998 (1998) Ecological patterns in the Bromeliaceae of the lomas formations of coastal Chile and Peru. Plant Systematics and Evolution 212: 261-278.
Wolf et al. 2016 (2016) Remote sensing-based detection and spatial pattern analysis for geo-ecological niche modeling of Tillandsia spp. in the Atacama, Chile. , pp.

Cleistogamy (1)

Gilmartin & Brown 1985 (1985) Cleistogamy in Tillandsia capillaris (Bromeliaceae). Biotropica 17(3): 256-259.

Climate change (3)

Castillo et al. 2013 (2013) Possible combined effects of climate change, deforestation, and harvesting on the epiphyte Catopsis compacta: a multidisciplinary approach. Ecology and Evolution 3(11): 1-10.
Rundel et al. 1997 (1997) Tillandsia landbeckii in the coastal Atacama Desert of northern Chile. Re vista Chilena de Historia Natural 70: 341-349,.
Wagner & Zotz 2018 (2018) Epiphytic bromeliads in a changing world: the effect of elevated CO2 and varying water supply on growth and nutrient relations. Plant Biology 20(3): 636-640.

Cloud forest (3)

Lasso & Ackerman 2004 (2004) The Flexible Breeding System of Werauhia sintenisii, a Cloud Forest Bromeliad from Puerto Rico. Biotropica 36(3): 414-417.
Molina et al. 2012 (2012) Diversity of Epiphytic Bromeliads in a successional gradient at cloud forest of the El Triunfo Biosphere Reserve, Chiapas, México. , pp.
Pierce et al. 2002 (2002) The role of CAM in high rainfall cloud forests: an in situ comparison of photosynthetic pathways in Bromeliaceae. Plant, Cell & Environment 25(9): 1181-1189.

Co2 (1)

Monteiroa et al. 2009 (2009) Tropical epiphytes in a CO2-rich atmosphere. Acta Oecologica 35: 60–68.

Colombia (5)

Arevalo et al. 2006 (2006) Vertical distribution of Vascular Epiphytes in four forest types of the Serrania de Chiribiquete, Colombian Guayana. Selbyana 27(2): 175-185.
Benavides 2015 (2015) Diversity pattern of epiphytic Bromeliaceae in the northwestern Andes of Colombia. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.
Cuatrecasas 1958 (1958) Aspectos de la vegetacion natural de Colombia. Revista de la Academia Colombiana de Ciencias Exactas, Fisicas y Naturales 10: 221-268.
Franco 2015 (2015) Contrasting patterns in reproductive phenology of a monocarpic perennial bromeliad (Puya nitida) in a paramo of Colombia. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.
Pico-V.. & Gastelbondo 2017 (2017) A record for the newly described species Tillandsia hansonii (Bromeliaceae) in Bogotá, including initial field studies from Colombia. Journal of the Bromeliad Society 66(4): 259-266.

Colonization (9)

Bonnet & Queiroz 2006 (2006) Vertical stratification of epiphytic bromeliads on different stages of secondary succession of Atlantic Rainforest, in Santa Catarina Island, Santa Catarina, Brazil. Revista Brasileira de Botânica 29(2): 217-228.
Cascante et al. 2006 (2006) Reproductive Strategies and Colonizing Ability of Two Sympatric Epiphytic Bromeliads in a Tropical Premontane Area. International Journal of Plant Sciences 167(6): 1187-1195.
Cascante-Marín et al. 2014 (2014) Genetic Diversity and Spatial Genetic Structure of an Epiphytic Bromeliad in Costa Rican Montane Secondary Forest Patches. Biotropica 46(4): 425-432.
Hoeltgebaum et al. 2013 (2013) Relationship between epiphytic bromeliads and phorophytes at different successional stages. Rodriguésia 64(2): 337-347.
Meireles & Manos 2018 (2018) Pervasive migration across rainforest and sandy coastal plain Aechmea nudicaulis (Bromeliaceae) populations despite contrasting environmental conditions. Molecular Ecology 27(5): 1261-1272.
Pinzon et al. 2015 (2015) The diversity of the Bromeliaceae of Mexico from a phylogenetic perspective. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.
Rundel et al. 1997 (1997) Tillandsia landbeckii in the coastal Atacama Desert of northern Chile. Re vista Chilena de Historia Natural 70: 341-349,.
Sampaio et al. 2010 (2010) Seed dispersal and population structure in Vriesea gigantea, a bromeliad from the Brazilian Atlantic Rainforest. Botanical Journal of the Linnean Society 164: 317–325.
Weising et al. 2015 (2015) Phylogeographic patterns in Bromeliaceae: examples from Pitcairnioideae s.s. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.

Costa rica (8)

Amici et al. 2019 (2019) Contrasting effects of host tree isolation on population connectedness in two tropical epiphytic bromeliads. American Journal of Botany 106(12): 1602-1611.
Cascante et al. 2006 (2006) Reproductive Strategies and Colonizing Ability of Two Sympatric Epiphytic Bromeliads in a Tropical Premontane Area. International Journal of Plant Sciences 167(6): 1187-1195.
Cascante et al. 2009 (2009) Dispersal limitation in epiphytic bromeliad communities in a Costa Rican fragmented montane landscape. Journal of Tropical Ecology 25(1): 63-73.
Cascante-Marın et al. 2006 (2006) Epiphytic bromeliad communities in secondary and mature forest in a tropical premontane area. Basic and Applied Ecology 7: 520-532.
Cascante-Marín et al. 2014 (2014) Genetic Diversity and Spatial Genetic Structure of an Epiphytic Bromeliad in Costa Rican Montane Secondary Forest Patches. Biotropica 46(4): 425-432.
LeCraw & Srivastava 2019 (2019) Biogeographic context dependence of trophic cascade strength in bromeliad food webs. Ecology 100(7): e02692-.
Marín et al. 2008 (2008) Establishment of Epiphytic Bromeliads in Successional Tropical Premontane Forests in Costa Rica. Biotropica 40(4): 441-448.
Utley & Burt-Utley 1977 (1977) Biologia de las Bromeliaceas (Phytogeography, physiological ecology and the Costa Rican genera of Bromeliaceae). Departamento de Historia Natural Museo National de Costa Rica, San Jose, pp. 9–29.

Cryptanthus (1)

Versieux et al. 2013a (2013) Extension of the Cryptanthus range in Northeastern Brazil with new findings in the phenotypic variation including changes in the trichome’s distribution, thus enhancing the understanding of the Cryptanthus zonatus complex (Bromeliaceae). Phytotaxa 109(1): 54–60.

Cuba (1)

Schwesinger 2004 (2004) Guzmania monostachia and its varieties at the Alturas de Banao Ecological Reserve, central Cuba. Journal of the Bromeliad Society 54(4): 160-162.

Culture (3)

Holst 2020 (2020) Airplant Aerialists on the High-Wire. Journal of the Bromeliad Society 69(3): 54-58.
Males 2018 (2018) Understanding the Basis of Drought Tolerance in Bromeliads. Journal of the Bromeliad Society 68(1): 40-44.
Monteiroa et al. 2009 (2009) Tropical epiphytes in a CO2-rich atmosphere. Acta Oecologica 35: 60–68.

Curacao (1)

Debrot et al. 1993 (1993) A Comparison of Ungrazed and Livestock-Grazed Rock Vegetation in Curacao. Biotropica 25(3): 270-280.

Deforestation (1)

Castillo et al. 2013 (2013) Possible combined effects of climate change, deforestation, and harvesting on the epiphyte Catopsis compacta: a multidisciplinary approach. Ecology and Evolution 3(11): 1-10.

Desert (1)

Marcus et al. 2019 (2019) Living at the dry limits: ecological genetics of Tillandsia landbeckii lomas in the Chilean Atacama Desert. Plant Systematics and Evolution (2019) 305: 1041–1053.

Distribution (4)

Brandao et al. 2009 (2009) Analysis and Visualization of the Geographical Distribution of Atlantic Forest Bromeliads Species. , pp.
Fontoura et al. 2012 (2012) Floristics and environmental factors determining the geographic distribution of epiphytic bromeliads in the Brazilian Atlantic Rain Forest. Flora 207(9): 662–672.
Gilmartin & 1973 (1973) Transandean Distributions of Bromeliaceae in Ecuador. Ecology 54(6): 1389-1393.
Merwin et al. 2003 (2003) The Influence of Host Tree Species on the Distribution of Epiphytic Bromeliads in Experimental Monospecific Plantations, La Selva, Costa Rica. Biotropica 35(1): 37-47.

Disturbance (1)

Werner & Gradstein 2010 (2010) Spatial distribution and abundance of epiphytes along a gradient of human disturbance in an Interandean dry valley, Ecuador. Selbyana 30(2): 203–211.

Diversity (6)

Flores-Argíelles et al. 2022 (2022) Diversity and Vertical Distribution of Epiphytic Angiosperms, in Natural and Disturbed Forest on the Northern Coast of Jalisco, Mexico. Frontiers in Forests and Global Change 5: 1-16 (online).
Kessler 2002 (2002) Species richness and ecophysiological types among Bolivian bromeliad communities. Biodiversity and Conservation 11: 987–1010.
Males & Griffiths 2017 (2017) Specialized stomatal humidity responses underpin ecological diversity in C3 bromeliads. Plant, Cell & Environment 40(12): 2931-2945.
Reyes-García et al. 2012 (2012) High but not dry: diverse epiphytic bromeliad adaptations to exposure within a seasonally dry tropical forest community. New Phytologist 193(3): 745-754.
Taylor et al. 2021 (2021) Vascular epiphytes contribute disproportionately to global centres of plant diversity. bioRxiv 2021.05.21.445115. Web..
Werner & Homeier 2024 (2024) Diverging Elevational Patterns of Tree vs. Epiphyte Species Density, Beta Diversity, and Biomass in a Tropical Dry Forest. Plants 13(18): 1-18 (online 2555).

Drought (4)

Bader et al. 2009 (2009) Pronounced drought tolerance characterizes the early life stages of the epiphytic bromeliad Tillandsia flexuosa. Functional Ecology 23(3): 472-479.
Carvalho et al. 2024 (2024) Drought memory in Acanthostachys strobilacea, a CAM epiphytic bromeliad. Plant biology online.
Graham & Andrade 2004 (2004) Drought tolerance associated with vertical stratification of two co-occurring epiphytic bromeliads in a tropical dry forest. American Journal of Botany 91(5): 699-706.
Males 2018 (2018) Understanding the Basis of Drought Tolerance in Bromeliads. Journal of the Bromeliad Society 68(1): 40-44.

Drought tolerance (1)

Bader et al. 2009 (2009) Pronounced drought tolerance characterizes the early life stages of the epiphytic bromeliad Tillandsia flexuosa. Functional Ecology 23(3): 472-479.

Dyckia (7)

Hirsch et al. 2015 (2015) Patterns of hybridization in three sympatric species of Dyckia (Bromeliaceae) endemic from southern Brazil. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.
Musegante et al. 2020 (2020) Geographical distribution of Dyckia walteriana (Bromeliaceae), a recently described and endangered species endemic to the Serra Geral formation, southern Brazil. Phytotaxa 438(4): 263–275.
Paggi et al. 2015 (2015) Insights into the biodiversity of Dyckia from Brazilian Pantanal and chaco of Mato Grosso do Sul. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.
Rogalski et al. 2009 (2009) Biologia reprodutiva da reófita Dyckia brevifolia Baker (Bromeliaceae) no Rio Itajaí-Açu, Santa Catarina, Brasil. Revista Brasileira de Botânica 32(4): 691–702..
Rogalski et al. 2021 (2021) Demographic structure of clonal, endemic, and endangered rheophyte bromeliad Dyckia ibiramensis: asexual vs sexual reproduction. Rodriguésia 72: 1-12 (online).
Vosgueritchian & Buzato 2006 (2006) Reprodução sexuada de Dyckia tuberosa (Vell.) Beer (Bromeliaceae), Pitcairnioideae) e interação planta-animal. Revista Brasileira de Botânica 29 (3): 433–442.
Weising et al. 2015 (2015) Phylogeographic patterns in Bromeliaceae: examples from Pitcairnioideae s.s. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.

Ecosystem (1)

Ladino et al. 2019 (2019) Ecosystem services provided by bromeliad plants: A systematic review. Ecology and Evolution 9(9): 1–13.

Ecuador (4)

Gilmartin & 1973 (1973) Transandean Distributions of Bromeliaceae in Ecuador. Ecology 54(6): 1389-1393.
Gilmartin 1973 (1973) Transandean Distributions of Bromeliaceae in Ecuador quick view. Ecology 54(6): 1389-1393.
Werner & Gradstein 2010 (2010) Spatial distribution and abundance of epiphytes along a gradient of human disturbance in an Interandean dry valley, Ecuador. Selbyana 30(2): 203–211.
Werner & Homeier 2024 (2024) Diverging Elevational Patterns of Tree vs. Epiphyte Species Density, Beta Diversity, and Biomass in a Tropical Dry Forest. Plants 13(18): 1-18 (online 2555).

Encholirium (5)

Araujo 2015 (2015) The monodominance of Encholirium spctabilis Mart. ex Schult. in inselbergs from an area of the semi-arid region in northeastern Brazil. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.
Gonçalves-Oliveira et al. 2017 (2017) Population genetic structure of the rock outcrop species Encholirium spectabile (Bromeliaceae): The role of pollination vs. seed dispersal and evolutionary implications. American Journal of Botany 104(6): 868-878.
Hmeljevski et al. 2014 (2014) Patterns of Gene Flow in Encholirium horridum L.B.Sm., a Monocarpic Species of Bromeliaceae From Brazil. Journal of Heredity 1(4): 1200445.
Hmeljevski et al. 2017 (2017) Do plant populations on distinct inselbergs talk to each other? A case study of genetic connectivity of a bromeliad species in an Ocbil landscape. Ecology and Evolution 7(13): 4704-4716.
Jorge et al. 2023 (2023) Among flowers and thorns: birds associated with Encholirium spectabile, a keystone bromeliad in a Brazilian semi-arid region. Ornithology Research 31(2?): Online 2662-673X.

Endemism (1)

Little & Hebert 1996 (1996) Endemism and ecological islands: the ostracods from Jamaican bromeliads. Freshwater Biology 36(2): 327-338.

Environment (3)

Amundrud & Srivastava 2016 (2016) Phytotelm Bromeliads as Model Systems to Study EcoSystem Responses to Environmental Stress. The Bulletin of the Ecological Society of America 97(4): 403-405.
de Oliveira et al. 2016 (2016) Tillandsia stricta Sol (Bromeliaceae) leaves as monitors of airborne particulate matter? A comparative SEM methods evaluation: Unveiling an accurate and odd HP-SEM method. Microscopy Research and Technique 79(9): 869-879.
Kratina et al. 2017 (2017) Environmental control of the microfaunal community structure in tropical bromeliads. Ecology and Evolution 7(5): 1627-1634.

Environmental control (1)

Kratina et al. 2017 (2017) Environmental control of the microfaunal community structure in tropical bromeliads. Ecology and Evolution 7(5): 1627-1634.

Environmental stress (1)

Amundrud & Srivastava 2016 (2016) Phytotelm Bromeliads as Model Systems to Study EcoSystem Responses to Environmental Stress. The Bulletin of the Ecological Society of America 97(4): 403-405.

Epiphyte (85)

Aguilar et al. 2021 (2021) Litter-trapping tank bromeliads in five different forests: Carbon and nutrient pools and fluxes. Biotropica 2021: 1–11 (online).
Apodaca & Guerrero 2019 (2019) Why is the geographic distribution of Tillandsia recurvata (Bromeliaceae) expanding to the south?. Bol. Soc. Argent. Bot 54(2): 255-261.
Arevalo et al. 2006 (2006) Vertical distribution of Vascular Epiphytes in four forest types of the Serrania de Chiribiquete, Colombian Guayana. Selbyana 27(2): 175-185.
Bader et al. 2009 (2009) Pronounced drought tolerance characterizes the early life stages of the epiphytic bromeliad Tillandsia flexuosa. Functional Ecology 23(3): 472-479.
Basilio et al. 20115 (2015) Community ecology of epiphytic Bromeliaceae in a remnant of Atlantic Forest in Zona da Mata, Minas Gerais State, Brazil. Hoehnea 42(1): 21-31, 3 tab., 3 fig..
Benavides 2015 (2015) Diversity pattern of epiphytic Bromeliaceae in the northwestern Andes of Colombia. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.
Benzing & Renfrow 1971 (1971) The Biology of the Epiphytic Bromeliad Tillandsia circinata Schlecht. I. The Nutrient Status of Populations in South Florida. American Journal of Botany 58(9): 867-873.
Bernal et al. 2005 (2005) Habitat preference of the epiphyte Tillandsia recurvata (Bromeliaceae) in a semi-desert environment in Central Mexico. Canadian Journal of Botany 83(10): 1238-1247.
Borgo & Silva 2003 (2003) Epífitos vasculares em fragmentos de Floresta Ombrófila Mista,Curitiba, Paraná, Brasil. Revista Brasil. Bot 26(3): 391-401.
Cach et al. 2013 (2013) Climatic and structural factors influencing epiphytic bromeliad community assemblage along a gradient of water-limited environments in the Yucatan Peninsula, Mexico. 6(1): 283-302.
Cach et al. 2012 (2012) Epiphytic Bromeliad and host communities composition along a rainfall gradient in the Yucatán PenÍnsula. , pp.
Cach-Pérez et al. 2012 (2012) Epiphytic bromeliad and hosts communities composition along a rainfall gradient in the Yucatán Peninsula. , pp.
Cascante et al. 2012 (2012) Genetic structure of the epiphytic Bromeliad Guzmania monostachia (Bromeliaceae) in recovering montane forest areas. , pp.
Cascante-Marın et al. 2006 (2006) Epiphytic bromeliad communities in secondary and mature forest in a tropical premontane area. Basic and Applied Ecology 7: 520-532.
Chaves & Rossatto 2020 (2020) Unravelling intricate interactions among atmospheric bromeliads with highly overlapping niches in seasonal systems. Plant Biology 22(2): 243-251.
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Epiphytes (2)

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Fascicularia (1)

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Fire (1)

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Food (1)

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Fosterella (1)

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Fragrance (1)

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French guiana (5)

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Germination (4)

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Global warming (1)

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Growth (1)

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Guzmania (13)

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Guzmania epiphyte (1)

Zotz & Thomas 1999 (1999) How much water is in the tank? Model calculations for two Epiphytic Bromeliads. Annals of Botany 83: 183-1992.

Hechtia (3)

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Herbivory (2)

Palacios & Mondragón 2012 (2012) Herbivory in Tillandsia carlos-hankii (Bromeliaceae) and the impact on reproductive success. , pp.
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Heteroblasty (2)

Meisner & Zotz 2012 (2012) Prevalence and gunctional relevance of Heteroblasty in Epiphytic Bromeliads. . , pp.
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Hohenbergia (2)

Fernandes et al. 2015 (2015) Richness and abundance of Aechmea and Hohenbergia (Bromeliaceae) in forest fragments and shade cocoa plantations in two contrasting landscapes in Southern Bahia, Brazil. Tropical Conservation, Science 8: 58–75.
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Host (6)

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Ramirez et al. 2018 (2018) Spatial variation in host preference in the endangered epiphytic bromeliad Tillandsia carlos-hankii. Acta Oecologica 92: 75–84.
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Inselbergs (2)

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Jamaica (2)

Laessle 1961 (1961) A Micro-Limnological Study of Jamaican Bromeliads. Ecology 42(3): 499-517.
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Litter (1)

Aguilar et al. 2021 (2021) Litter-trapping tank bromeliads in five different forests: Carbon and nutrient pools and fluxes. Biotropica 2021: 1–11 (online).

Loma (8)

Garcia et al. 2021 (2021) Climate and coastal low-cloud dynamic in the hyperarid Atacama fog Desert and the geographic distribution of Tillandsia landbeckii (Bromeliaceae) dune ecosystems. Plant Systematics and Evolution 307(5): 1-22 (online 57).
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Mexico (31)

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Reyes-García et al. 2008 (2008) Niche Differentiation in Tank and Atmospheric Epiphytic Bromeliads of a Seasonally Dry Forest. Biotropica 40(2): 168-175.
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Rosa et al. 2017 (2017) Vascular epiphyte diversity in two forest types of the “El Cielo” Biosphere Reserve, Mexico. Botany 95(6): 599-610.
Scheffknecht et al. 2012 (2012) Survival and Growth of Juvenile Bromeliads in Coffee Plantations and Forests in Central Veracruz, Mexico. Biotropica 44(3): 341-349.
Toledo- et al. 2017 (2017) Do cloud forest tree species differ in their suitability as a substrate for epiphytic bromeliads?. Plant Ecology 218(5): 541-546.
Winkler et al. 2005 (2005) Herbivory in epiphytic bromeliads, orchids and ferns in a Mexican montane forest. Journal of Tropical Ecology 21 : 147–154.

Montane forest (1)

Kessler 2002 (2002) Species richness and ecophysiological types among Bolivian bromeliad communities. Biodiversity and Conservation 11: 987–1010.

Neoregelia (2)

Cogliatti & Rocha 2001 (2001) Spatial distribution and preferential substrate of Neoregelia johannis (Carriere) L.B. Smith (Bromeliaceae) in a disturbed area of Atlantic Rainforest at Ilha Grande, RJ, Brazil. Revta brasil. Bot., Sao Paulo 24(4): 389-394.
Mantuano et al. 2015 (2015) Intraclonal physiological specialization in the endemic nurse-plant Neoregelia cruenta. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.

Neoregeria (1)

Guimaraes-Souza et al. 2006 (2006) Limnological parameters in the water accumulated in tropical bromeliads. Acta Limnol. Bras 18(1): 47-53.

Niche (2)

Chaves & Rossatto 2020 (2020) Unravelling intricate interactions among atmospheric bromeliads with highly overlapping niches in seasonal systems. Plant Biology 22(2): 243-251.
Reyes-García et al. 2008 (2008) Niche Differentiation in Tank and Atmospheric Epiphytic Bromeliads of a Seasonally Dry Forest. Biotropica 40(2): 168-175.

Nidularium (1)

Freitas et al. 1998 (1998) Habitat choice in two facultative epiphytes of the genus Nidularium (Bromeliaceae). Selbyana 19(2): 236-239.

Nutrients (11)

Gonzalez et al. 2014a (2014) Detrital nutrient content determines growth rate and elemental composition of bromeliad-dwelling insects. Freshwater Biology 59(4): 737-747.
Inselsbacher et al. 2007 (2007) Microbial activities and foliar uptake of nitrogen in the epiphytic bromeliad Vriesea gigantea. New Phytologist 175(2): 311-320.
Lafont et al. 2022 (2022) Effect of substrate fertility on tank-bromeliad performances. Plant and Soil 480 (prepublished online).
Lasso & Ackerman 2013 (2013) Nutrient limitation restricts growth and reproductive output in a tropical montane cloud forest bromeliad: findings from a long-term forest fertilization experiment. Oecologia 171: 165–174.
Leroy et al. 2015 (2015) The contribution of microorganisms and metazoans to mineral nutrition in tank bromeliads. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.
Leroy et al. 2019 (2019) Water and nutrient uptake capacity of leaf-absorbing trichomes vs. roots in epiphytic tank bromeliads. Environ. Exp. Bot 163 : 112-123.
Richardson et al. 2000 (2000) Effects of nutrient availability and other elevational changes on bromeliad populations and their invertebrate communities in a humid tropical forest in Puerto Rico. Journal of Tropical Ecology 16: 167-188.
Romero et al. 2010 (2010) Nitrogen fluxes from treefrogs to tank epiphytic bromeliads: an isotopic and physiological approach. Oecologia 162: 941–949.
Wanek & Zotz 2011 (2011) Are vascular epiphytes nitrogen or phosphorus limited? A study of plant 15N fractionation and foliar N:P stoichiometry with the tank bromeliad Vriesea sanguinolenta. New Phytologist 192(2): 462-470.
Winkler & Zotz 2009 (2009) Highly efficient uptake of phosphorus in epiphytic bromeliads. Annals of Botany 103 : 477–484.
Zotz & Asshoff 2010 (2010) Growth in epiphytic bromeliads: response to the relative supply of phosphorus and nitrogen. Plant Biology 12(1): 108-113.

Nutrients absorption (3)

Lafont et al. 2022 (2022) Effect of substrate fertility on tank-bromeliad performances. Plant and Soil 480 (prepublished online).
Leroy et al. 2015 (2015) The contribution of microorganisms and metazoans to mineral nutrition in tank bromeliads. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.
Richardson et al. 2000 (2000) Effects of nutrient availability and other elevational changes on bromeliad populations and their invertebrate communities in a humid tropical forest in Puerto Rico. Journal of Tropical Ecology 16: 167-188.

Organic compounds (1)

Gonzalez et al. 2022 (2022) Extraction and Identification of Volatile Organic Compounds in Scentless Flowers of 14 Tillandsia Species Using HS-SPME/GC-MS. Metabolites 12(7): 1-15 (online).

Ortgiesia (1)

Goetze et al. 2015 (2015) Diversification of Bromelioideae in the Atlantic rainforest: a case study of Aechmea subgenus Ortgiesia. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.

Orthophytum (1)

Costa et al. 2024 (2024) Distribution pattern in the rupiculous genus Orthophytum (Bromelioideae/Bromeliaceae) reveals high microendemicity in different types of rocky outcrops. Anais da Academia Brasileira de Ciencias 96: 1-26 (online).

Panama (6)

Laube & Zotz 2003 (2003) Which abiotic factors limit vegetative growth in a vascular epiphyte?. Ecology 17: 598–604.
Laube & Zotz 2006 (2006) Neither Host-specific nor Random: Vascular Epiphytes on Three Tree Species in a Panamanian Lowland Forest. Annals of Botany 97: 1103–1114.
Poltz & Zotz 2011 (2011) Vascular Epiphytes on Isolated Pasture Trees Along a Rainfall Gradient in the Lowlands of Panama. BIOTROPICA 43(2): 165–172.
Zotz & Einzmann 2024 (2024/11/22) Werauhia sanguinolenta - A Conspicuous Epiphytic Tank Bromeliad. In: Helene C. Muller-Landau; S. Joseph Wright - The First 100 Years of Research on Barro Colorado: Plant and Ecosystem Science (Volumes 1 and 2). Plant and Ecosystem Science 2: 769-771.
Zotz & Richter 2006 (2006) Changes in carbohydrate and nutrient contents throughout a reproductive cycle indicate that phosphorus is a limiting nutrient in the epiphytic bromeliad, Werauhia sanguinolenta. Annals of Botany 97: 745–754.
Zotz et al. 2002 (2002) A Simulation Study on the Importance of Size-related Changes in Leaf Morphology and Physiology for Carbon Gain in an Epiphytic Bromeliad. Annals of Botany 90: 1-7.

Peru (6)

Benavides et al. 2021 (2021) Distribution patterns, ecological niche and conservation status of endemic Tillandsia purpurea along the Peruvian coast. Plant Systematics and Evolution 307(52): 1-14 (online).
Bennett 1988 (1988) A comparison of life history traits in selected epiphytic and saxicolous species of Tillandsia (Bromeliaceae) from Florida and Peru. University of North Carolina, Chapell Hill USA, pp.
Heathcote 2013 (2013) The Ecology of Vascular Epiphytes in the Peruvian Andes. Linacre College, Department of Plant Sciences, Oxford, 295 pp.
Krügel 1993 (1993) Biologie und Ökologie der Bromelienfauna von Guzmania weberbaueri im amazonischen Peru ergänzt durch eine umfassende Bibliographie der Bromelien-Phytotelmata. Österreichische Akademie der Wissenschaften, Vienna Austria, 93 pp.
Pauca-Tanco et al. 2020 (2020) Distribution and characterization of the communities of Tillandsia (Bromeliaceae) in southern Peru and their relationship with altitude, slope and orientation. Ecosistemas 29(3): 2035 (online).
Rundel & Dillon 1998 (1998) Ecological patterns in the Bromeliaceae of the lomas formations of coastal Chile and Peru. Plant Systematics and Evolution 212: 261-278.

Pest (1)

Magalhães et al. 2012 (2012) Effects of leaf herbivory on the bromeliad Aechmea blanchetiana: a study of selective feeding by the scraper Acentroptera pulchella. Acta Botanica Brasilica 26(4): 944-952.

Photosynthesis (1)

Gonzalez et al. 2021 (2021) Seasonal changes in photosynthesis for the epiphytic bromeliad Tillandsia brachycaulos in a tropical dry deciduous forest. Botanical Sciences 99(4): 850-862..

Phytotelmata (1)

ROTHERAY et al. 2007 (2007) Neotropical Copestylum (Diptera, Syrphidae) breeding in bromeliads (Bromeliaceae) including 22 new species. Zoological Journal of the Linnean Society 150(2): 267-317.

Pitcairnia (13)

Ballego-Campos et al. 2022 (2022) Extranuptial nectaries in bromeliads: a new record for Pitcairnia burchellii and perspectives for Bromeliaceae. The Science of Nature 109(3): 28(1-15 online).
Boisselier et al. 2010 (2010) Genetic structure of the xerophilous bromeliad Pitcairnia geyskesii on inselbergs in French Guiana - a test of the forest refuge hypothesis. Ecography 33(1): 175-184.
Groger 1995 (1995) Die Vegetation der Granit-Inselberge Südvenezuelas: Ökologische und Biogeographische Untersuchungen. , pp.
Leal et al. 2015 (2015) Phylogeography, population genomics and adaptive variation in the Pitcairnia lanuginosa (Bromeliaceae) species complex. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.
Paggi et al. 2008 (2008) Isolation and characterization of microsatellite loci in Pitcairnia albiflos (Bromeliaceae), an endemic bromeliad from the Atlantic Rainforest, and cross-amplification in other species. Molecular Ecology Resources 2008: 1-3.
Palma et al. 2011 (2011) Sympatric bromeliad species (Pitcairnia spp.) facilitate tests of mechanisms involved in species cohesion and reproductive isolation in Neotropical inselbergs. Molecular Ecology 20(15): 3185-3201.
Palma-Silva et al. 2016 (2016) De novo assembly and characterization of leaf and floral transcriptomes of the hybridizing bromeliad species (Pitcairnia spp.) adapted to Neotropical Inselbergs. Molecular Ecology Resources 16(4): 1012-1022.
Rex 2001 (2001) Molekulare analyse von Verwandtschaftsbeziehungen in ausgewählten Gattungen der Pitcairnioideae. Univ. of Kassel, Germany, pp.
Sarthou et al. 2001 (2001) Genetic structure of the saxicole Pitcairnia Geyskesii (Bromeliaceae) on inselbergs in French Guiana. American Journal of Botany 88(5): 861-868.
Wendt et al. 2000 (2000) Recognition of Pitcairnia corcovadensis (Bromeliaceae) at the species level. Systematic botany 25(3): 389-398.
Wendt et al. 2001 (2001) Reproductive biology and natural hybridization between two endemic species of Pitcairnia (Bromeliaceae). The American journal of botany; official publication of the Botanical Society of America 88: (10): 1760-1767.
Wendt et al. 2001 (2001) Reproductive biology and natural hybridization between two endemic species of Pitcairnia (Bromeliaceae). American Journal of Botany 88(10): 1760-1767.
Wendt et al. 2002 (2002) Selfing faciltates reproductive isolation among three sympatric species of Pitcairnia (Bromeliaceae). Plant systematics and evolution 232: 201-212.

Pitcairnioideae (3)

Gomes-da-Silva et al. 2017 (2017) Distribution of the xeric clade species of Pitcairnioideae (Bromeliaceae) in South America: a perspective based on areas of endemism. Journal of Biogeography 44(9): 1994-2006.
Silva et al. 2017 (2017) Distribution of the xeric clade species of Pitcairnioideae (Bromeliaceae) in South America: a perspective based on areas of endemism. Journal of Biogeography .
Weising et al. 2015 (2015) Phylogeographic patterns in Bromeliaceae: examples from Pitcairnioideae s.s. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.

Predation (5)

Chilpa-Galván et al. 2017 (2017) Drought, post-dispersal seed predation, and the establishment of epiphytic bromeliads (Tillandsia spp.). Biotropica 49(6): 770-773.
Dézerald et al. 2015 (2015) Temperature: Diet Interactions Affect Survival through Foraging Behavior in a Bromeliad-Dwelling Predator. Biotropica 47(5): 569-578.
Gonçalves et al. 2017 (2017) Effects of predatory ants within and across ecosystems in bromeliad food webs. Journal of Animal Ecology 86(4): 790-799.
Hammill et al. 2014 (2014) Bromeliad-associated Reductions in Host Herbivory: Do Epiphytic Bromeliads Act as Commensalists or Mutualists?. Biotropica 46(1): 78-82.
STARZOMSKI et al. 2010 (2010) Predation and facilitation determine chironomid emergence in a bromeliad-insect food web. Ecological Entomology 35(1): 53-60.

Pseudananas (1)

Grol 2005 (2005) Effect of bromeliad (Pseudananas sagenarius) cover on seed predation and tree regeneration in tropical dry forest INPA, Bolivia. ibifbolivia.org.bo, 42 pp.

Pseudoananas (1)

Fredericksen et al. 1999 (1999) Ecología de la bromeliácea terrestre Pseudananas sagenarius (Bromeliaceae, Bromelioideae) en bosques secos de Bolivia. Revista de la Sociedad Boliviana Botánica 2(2): 165-173.

Puerto rica (1)

Lasso & Ackerman 2004 (2004) The Flexible Breeding System of Werauhia sintenisii, a Cloud Forest Bromeliad from Puerto Rico. Biotropica 36(3): 414-417.

Puerto rico (2)

Lasso 2003 (2003) Flowering phenology of Werauhia sintenisii, a bromeliad from the dwarf montane forest in Puerto Rico: an indicator of climate change?. Selbyana 24(1): 95-104.
Pett-Ridge & Silver 2002 (2002) Survival, Growth, and Ecosystem Dynamics of Displaced Bromeliads in a Montane Tropical Forest1. Biotropica 34(2): 211-224.

Puya (3)

Franco 2015 (2015) Contrasting patterns in reproductive phenology of a monocarpic perennial bromeliad (Puya nitida) in a paramo of Colombia. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.
Ibisch et al. 1999a (1999) Puya raimondii Harms in Bolivien - ein Fall für den Artenschutz ?. Deutsche Bromelien-Gesellschaft, 32 pages pp.
Veldhuisen et al. 2022 (2022) Description of Life History and Reproductive Size Thresholds in Three High Elevation Puya (Bromeliaceae). bioRxiv 2022.02.18.480924.

Rainfall (2)

Cach-Pérez et al. 2012 (2012) Epiphytic bromeliad and hosts communities composition along a rainfall gradient in the Yucatán Peninsula. , pp.
Poltz & Zotz 2011 (2011) Vascular Epiphytes on Isolated Pasture Trees Along a Rainfall Gradient in the Lowlands of Panama. BIOTROPICA 43(2): 165–172.

Rainfall gradient (1)

Cach-Pérez et al. 2012 (2012) Epiphytic bromeliad and hosts communities composition along a rainfall gradient in the Yucatán Peninsula. , pp.

Remote sensing (1)

Judith et al. 2013 (2013) Using high-resolution remote sensing data for habitat suitability models of Bromeliaceae in the city of Mérida, Venezuela. Landscape and Urban Planning 120: 107– 118.

Rio de janeiro state (1)

Fontoura 1995 (1995) Distribution pattens of five bromeliad genera in atlantic rain forest, Rio de Janeiro State, Brasil. Selbyana; journal of the Marie Selby Botanical Gardens 16(1): 79-93.

Rocky outcrops (6)

Araujo 2015 (2015) The monodominance of Encholirium spctabilis Mart. ex Schult. in inselbergs from an area of the semi-arid region in northeastern Brazil. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.
Costa et al. 2024 (2024) Distribution pattern in the rupiculous genus Orthophytum (Bromelioideae/Bromeliaceae) reveals high microendemicity in different types of rocky outcrops. Anais da Academia Brasileira de Ciencias 96: 1-26 (online).
Jorge et al. 2023 (2023) Among flowers and thorns: birds associated with Encholirium spectabile, a keystone bromeliad in a Brazilian semi-arid region. Ornithology Research 31(2?): Online 2662-673X.
Mollo et al. 2011 (2011) Effects of low temperature on growth and non-structural carbohydrates of the imperial bromeliad Alcantarea imperialis cultured in vitro. Plant Cell Tiss Organ Cult 107: 141–149.
Musegante et al. 2020 (2020) Geographical distribution of Dyckia walteriana (Bromeliaceae), a recently described and endangered species endemic to the Serra Geral formation, southern Brazil. Phytotaxa 438(4): 263–275.
Wendt et al. 2001 (2001) Reproductive biology and natural hybridization between two endemic species of Pitcairnia (Bromeliaceae). American Journal of Botany 88(10): 1760-1767.

Saxicoles (1)

Kessler 2002 (2002) Species richness and ecophysiological types among Bolivian bromeliad communities. Biodiversity and Conservation 11: 987–1010.

Seed dispersal (8)

Amici et al. 2019 (2019) Contrasting effects of host tree isolation on population connectedness in two tropical epiphytic bromeliads. American Journal of Botany 106(12): 1602-1611.
Brancalion et al. 2009 (2009) Do Terrestrial Tank Bromeliads in Brazil Create Safe Sites for Palm Establishment or Act as Natural Traps for Its Dispersed Seeds?. Biotropica 41(1): 3-6.
Cascante et al. 2009 (2009) Dispersal limitation in epiphytic bromeliad communities in a Costa Rican fragmented montane landscape. Journal of Tropical Ecology 25(1): 63-73.
Cascante-Marín et al. 2014 (2014) Genetic Diversity and Spatial Genetic Structure of an Epiphytic Bromeliad in Costa Rican Montane Secondary Forest Patches. Biotropica 46(4): 425-432.
Lavor et al. 2014 (2014) Population genetics of the endemic and endangered Vriesea minarum (Bromeliaceae) in the Iron Quadrangle, Espinhaço Range, Brazil. American Journal of Botany 101(7): 1167-1175.
Marín et al. 2008 (2008) Establishment of Epiphytic Bromeliads in Successional Tropical Premontane Forests in Costa Rica. Biotropica 40(4): 441-448.
Meireles & Manos 2018 (2018) Pervasive migration across rainforest and sandy coastal plain Aechmea nudicaulis (Bromeliaceae) populations despite contrasting environmental conditions. Molecular Ecology 27(5): 1261-1272.
Zotz & Vollrath 2002 (2005) Substrate preferences of epiphytic bromeliads: an experimental approach. Acta Oecologica 28: 306–312.

Speciation (1)

Lexer et al. 2015 (2015) Speciation genomics and the (dis-) continuum between speciation and radiation in bromeliads. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.

Substrate (1)

Zotz & 1997 (1997) Substrate use of three epiphytic bromeliads. Ecography 20(3): 264-270.

Tillandsia (70)

Alfaro et al. 2021 (2021) Soil bacterial community structure of fog‐dependent Tillandsia landbeckii dunes in the Atacama Desert. Plant Systematics and Evolution 307(56): 1-11 (online).
Aoki et al. 2023 (2023) Urban epiphytes: bromeliad diversity in a green cover gradient across a Neotropical streetscape. Urban Forestry & Urban Greening 82: 127901 online.
Apodaca & Guerrero 2019 (2019) Why is the geographic distribution of Tillandsia recurvata (Bromeliaceae) expanding to the south?. Bol. Soc. Argent. Bot 54(2): 255-261.
Bader et al. 2009 (2009) Pronounced drought tolerance characterizes the early life stages of the epiphytic bromeliad Tillandsia flexuosa. Functional Ecology 23(3): 472-479.
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Benavides et al. 2021 (2021) Distribution patterns, ecological niche and conservation status of endemic Tillandsia purpurea along the Peruvian coast. Plant Systematics and Evolution 307(52): 1-14 (online).
Benavides et al. 2022 (2022) Phenology of Tillandsia purpurea in association with microclimatic variables in a hyperarid environment of the southern Peruvian coast. Idesia 40(2): 77-84.
Bennett 1988 (1988) A comparison of life history traits in selected epiphytic and saxicolous species of Tillandsia (Bromeliaceae) from Florida and Peru. University of North Carolina, Chapell Hill USA, pp.
Benzing & Renfrow 1971 (1971) The Biology of the Epiphytic Bromeliad Tillandsia circinata Schlecht. I. The Nutrient Status of Populations in South Florida. American Journal of Botany 58(9): 867-873.
Bernal et al. 2005 (2005) Habitat preference of the epiphyte Tillandsia recurvata (Bromeliaceae) in a semi-desert environment in Central Mexico. Canadian Journal of Botany 83(10): 1238-1247.
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Cach et al. 2018 (2018) Morphophysiological Plasticity in Epiphytic Bromeliads Across a Precipitation Gradient in the Yucatan Peninsula, Mexico. Tropical Conservation Science 11: 1–10.
Cascante et al. 2006 (2006) Reproductive Strategies and Colonizing Ability of Two Sympatric Epiphytic Bromeliads in a Tropical Premontane Area. International Journal of Plant Sciences 167(6): 1187-1195.
Castano et al. 2014, (2014,) Correlation between arthropods and physical and chemical characteristics of water and soil retained in Tillandsia violacea (Bromeliaceae) in an abies-quercus forest in Central Mexico. Applied Ecology and Environmental Research 12(1): 179-192.
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Cathcart 2019 (2019) The ‘Floridian Fasciculata’. Journal of the Bromeliad Society Int 68(3): 184-188.
Cervantes et al. 2005 (2005) Light microhabitats, growth and photosynthesis of an epiphytic bromeliad in a tropical dry forest. Plant Ecology 179: 107–118.
Chaparro et al. (2024) Urban and suburban's airborne magnetic particles accumulated on Tillandsia capillaris. Science of The Total Environment 907: 167890 (online).
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Chavez et al. 2019 (2019) Dew Can Prolong Photosynthesis and Water Status During Drought in Some Epiphytic Bromeliads From a Seasonally Dry Tropical Forest. Tropical Conservation Science 12: 1–11.
Chilpa-Galván et al. 2017 (2017) Drought, post-dispersal seed predation, and the establishment of epiphytic bromeliads (Tillandsia spp.). Biotropica 49(6): 770-773.
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Tillandsioid (4)

Harpe et al. 2018 (2018) Genomic footprints of repeated evolution of CAM photosynthesis in tillandsioid bromeliads. bioRxiv .
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Tillandsioideae (3)

Lexer et al. 2015 (2015) Speciation genomics and the (dis-) continuum between speciation and radiation in bromeliads. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.
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Zotz 2013 (2013) A Longer Story Than Expected: Seeds Of Several Species (Tillandsioideae) Remain Viable For Up To Two Years. Journal of the Bromeliad Society 63(1): 83-86.

Trichomes (1)

Schmitt et al. 1989 (1989) Gas Exchange and Water Vapor Uptake in the Atmospheric CAM Bromeliad Tillandsia recurvata L.: The Influence of Trichomes. Botanica Acta 102(1): 80-84.

Trinidad (3)

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Maxwell et al. 1992 (1992) Photoinhibitory responses of the epiphytic bromeliad Guzmania monostachia during the dry season in Trinidad maintain photochemical integrity under adverse conditions. Plant, Cell & Environment 15(1): 37-47.
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Urban (6)

Aoki et al. 2023 (2023) Urban epiphytes: bromeliad diversity in a green cover gradient across a Neotropical streetscape. Urban Forestry & Urban Greening 82: 127901 online.
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Zotz & Cascante 2024 (2024) Life on the Wire - Plant Growth on Power Lines in the Americas. Diversity 16(9): 1-13 (online).

Ursulaea (3)

Siekkinen 2016 (2016) In the field with Ursulaea . Journal of the Bromeliad Society BSI_V65(3): 166-178.
Siekkinen 2016b (2016) The Mystery of Hechtia argentea - Part 1 . Journal of the Bromeliad Society 65(1): 48-57.
Siekkinen 2016c (2016) The Mystery of Hechtia argentea - Part 2 . Journal of the Bromeliad Society 65(2): 100-110.

Usa (3)

Bennett 1988 (1988) A comparison of life history traits in selected epiphytic and saxicolous species of Tillandsia (Bromeliaceae) from Florida and Peru. University of North Carolina, Chapell Hill USA, pp.
Benzing & Renfrow 1971 (1971) The Biology of the Epiphytic Bromeliad Tillandsia circinata Schlecht. I. The Nutrient Status of Populations in South Florida. American Journal of Botany 58(9): 867-873.
Larson & Frank 2002 (2002) Bromeliads and bromeliad weevils of Florida. Coop. Ext. Service, Univ. of Florida, Inst. of Food and Agricultural Sciences USA, pp.

Variation (1)

de Freitas et al. 2003 (2003) Morphological Variation in Two Facultative Epiphytic Bromeliads Growing on the Floor of a Swamp Forest1. Biotropica 35(4): 546-550.

Venezuela (5)

Groger 1995 (1995) Die Vegetation der Granit-Inselberge Südvenezuelas: Ökologische und Biogeographische Untersuchungen. , pp.
Groger 2005 (2005) Im Tiefland des venezolanischen Guayanagebiets: Granitinselberge und ihre Bromelien. 2005(1): 4-9.
Groger et al. 1996 (1996) Biogeography and diversity of the inselberg (Laja) vegetation of southern Venezuela. Biodiversity letters 3: 165-179.
Judith et al. 2013 (2013) Using high-resolution remote sensing data for habitat suitability models of Bromeliaceae in the city of Mérida, Venezuela. Landscape and Urban Planning 120: 107– 118.
Morillo, Briceno & Silva 2010 (2010) Botánica y Ecología de las Monocotiledóneas de los Páramos en Venezuela - Volume 2. , 778 pp.

Vriesea (17)

Gilmartin 1983 (1983) Evolution of mesic and xeric habits in Tillandsia and Vriesea. Systematic botany 8(3): 233-242.
Gobara et al. 2020 (2020) How does a C3 epiphytic tank bromeliad respond to drought?. Bot. J. Linn. Soc 192 : 855-867.
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Kessler et al. 2019 (2019) The role of hummingbirds in the evolution and diversification of Bromeliaceae: unsupported claims and untested hypotheses. Botanical Journal of the Linnean Society 20: 1–17.
Lavor et al. 2014 (2014) Population genetics of the endemic and endangered Vriesea minarum (Bromeliaceae) in the Iron Quadrangle, Espinhaço Range, Brazil. American Journal of Botany 101(7): 1167-1175.
Mestre et al. 2001 (2001) Macroinvertebrate Fauna Associated to the Bromeliad Vriesea inflata of the Atlantic Forest (Paraná State, Southern Brazil). Brazilian Archives of Biology and Technology 44(1): 89 - 94.
Neri et al. 2017 (2017) Variation in reproductive systems facilitates species boundaries of sympatric Vriesea (Bromeliaceae). Botanical Journal of the Linnean Society 184(2): 272–279.
Nogueira et al. 2015 (2015) Diversity of species, altitudinal gradient and flowering season of Vriesea in Bahia, Brazil. In: Benko-Iseppon, A.M.; Alves, M. & Louzada, R. (2015) An overview and abstracts of the First World Congress on Bromeliaceae Evolution. Rodriguésia 66(2): A1-A66. , pp.
Paggi et al. 2013 (2013) Reproductive system and fitness of Vriesea friburgensis, a self-sterile bromeliad species. Plant Species Biology 28(3): 169-176.
Palma et al. 2008 (2008) Meiotic behavior and pollen viability of wild populations of the neotropical species Vriesea gigantea (Bromeliaceae). Plant Species Biology 23(3): 217-221.
Paula 2006 (2006) Vriesea oligantha: an obligate epiphyte of Velloziaceae. Journal of the Bromeliad Society 55(5): 195-198.
Romero et al. 2010 (2010) Nitrogen fluxes from treefrogs to tank epiphytic bromeliads: an isotopic and physiological approach. Oecologia 162: 941–949.
Sampaio et al. 2010 (2010) Seed dispersal and population structure in Vriesea gigantea, a bromeliad from the Brazilian Atlantic Rainforest. Botanical Journal of the Linnean Society 164: 317–325.
SAMPAIO et al. 2012 (2012) Inbreeding depression in Vriesea gigantea, a perennial bromeliad from southern Brazil. Botanical Journal of the Linnean Society 169(2): 312-319.
Schmidt & Zotz 2001 (2001) Ecophysiological consequences of differences in plant size: in situ carbon gain and water relations of the epiphytic bromeliad, Vriesea sanguinolenta. Plant, Cell & Environment 24(1): 101-111.
Schmidt. & Zotz 2002 (2002) Inherently slow growth in two Caribbean epiphytic species: A demographic approach. Journal of Vegetation Science 13: 527-534.
Zanella et al. 2016 (2016) Hybridization between two sister species of Bromeliaceae: Vriesea carinata and V. incurvata. Botanical Journal of the Linnean Society 181(3): 491-504.

Water (4)

Benzing 2017 (2017) How bromeliads obtain and use water. Journal of the Bromeliad Society 66(4): 274-284.
Jocque & Kolby 2012 (2012) Acidity of tank bromeliad water in a cloud forest, Cusuco National Park, Honduras. International Journal of Plant Physiology and Biochemistry 4(4): 59-70.
Leroy et al. 2019 (2019) Water and nutrient uptake capacity of leaf-absorbing trichomes vs. roots in epiphytic tank bromeliads. Environ. Exp. Bot 163 : 112-123.
Males & Griffiths 2017 (2017) Functional types in the Bromeliaceae: relationships with drought-resistance traits and bioclimatic distributions. Functional Ecology 31(10): 1868-1880.

Werauhia (12)

Beltrán et al. 2013 (2013) Juvenile tank-bromeliads lacking tanks: do they engagein CAM photosynthesis? . Photosynthetica 51 (1): 55-62.
Cascante et al. 2020 (2020) First description of the nocturnal flowers of the little-known Werauhia haberi (Tillandsioideae) and notes about its natural history. Journal of the Bromeliad Society Int 69(1): 6-14.
Lasso & Ackerman 2004 (2004) The Flexible Breeding System of Werauhia sintenisii, a Cloud Forest Bromeliad from Puerto Rico. Biotropica 36(3): 414-417.
Lasso & Ackerman 2013 (2013) Nutrient limitation restricts growth and reproductive output in a tropical montane cloud forest bromeliad: findings from a long-term forest fertilization experiment. Oecologia 171: 165–174.
Lasso 2003 (2003) Flowering phenology of Werauhia sintenisii, a bromeliad from the dwarf montane forest in Puerto Rico: an indicator of climate change?. Selbyana 24(1): 95-104.
Laube & Zotz 2003 (2003) Which abiotic factors limit vegetative growth in a vascular epiphyte?. Ecology 17: 598–604.
Wanek & Zotz 2011 (2011) Are vascular epiphytes nitrogen or phosphorus limited? A study of plant 15N fractionation and foliar N:P stoichiometry with the tank bromeliad Vriesea sanguinolenta. New Phytologist 192(2): 462-470.
Zotz & Einzmann 2024 (2024/11/22) Werauhia sanguinolenta - A Conspicuous Epiphytic Tank Bromeliad. In: Helene C. Muller-Landau; S. Joseph Wright - The First 100 Years of Research on Barro Colorado: Plant and Ecosystem Science (Volumes 1 and 2). Plant and Ecosystem Science 2: 769-771.
Zotz & Richter 2006 (2006) Changes in carbohydrate and nutrient contents throughout a reproductive cycle indicate that phosphorus is a limiting nutrient in the epiphytic bromeliad, Werauhia sanguinolenta. Annals of Botany 97: 745–754.
Zotz 2005 (2005) Differences in vital demographic rates in three populations of the epiphytic bromeliad, Werauhia sanguinolenta. Acta Oecologica 28: 306–312.
Zotz et al. 2002 (2002) A Simulation Study on the Importance of Size-related Changes in Leaf Morphology and Physiology for Carbon Gain in an Epiphytic Bromeliad. Annals of Botany 90: 1-7.
Zotz et al. 2005 (2005) Long-term population dynamics of the epiphytic bromeliad, Werauhia sanguinolenta. Ecography 28(6): 806-814.

Wittrockia (1)

Grzebielucka et al. 2024 (2024) Phenotypic Variation of Wittrockia cyathiformis (Bromeliaceae) Across Life Forms and Forest Types in the Atlantic Rainforest. ARPHA Preprints 5(online): ARPHA Preprints.

Total: 435