Climate variability, tree increment patterns and ENSO-related carbon sequestration reduction of the tropical dry forest species Loxopterygium huasango of Southern Ecuador

Published Date

August 2016, Volume 30, Issue 4, pp 1245-1258

First online: 16 February 2016

Title 

Climate variability, tree increment patterns and ENSO-related carbon sequestration reduction of the tropical dry forest species Loxopterygium huasango of Southern Ecuador

• Author 

• Susanne Spannl 
• , Franziska Volland 
• , Darwin Pucha
• , Thorsten Peters
• , Eduardo Cueva
• , Achim Bräuning

Abstract

Key message

Striking hydro-climatic differences of 2 years (wet; dry) dramatically control the increment pattern of L. huasango in varying extent, even causing a “growth collapse” during the La Niña drought 2010/2011.

Abstract

We present the first multi-year long time series of local climate data in the seasonally dry tropical forest in Southern Ecuador and related growth dynamics of Loxopterygium huasango, a deciduous tree species. Local climate was investigated by installing an automatically weather station in 2007 and the daily tree growth variability was measured with high-resolution point dendrometers. The climatic impact on growth behaviour was evaluated. Hydro-climatic variables, like precipitation and relative humidity, were the most important factors for controlling tree growth. Changes in rainwater input affected radial increment rates and daily amplitudes of stem diameter variations within the study period from 2009 to 2013. El Niño Southern Oscillation (ENSO) related variations of tropical Pacific Ocean sea surface temperatures influenced the trees’ increment rates. Average radial increments showed high inter-annual (up to 7.89 mm) and inter-individual (up to 3.88 mm) variations. Daily amplitudes of stem diameter variations differed strongly between the two extreme years 2009 (wet) and 2011 (dry). Contrary to 2009, the La Niña drought in 2011 caused a rapid reduction of the daily amplitudes, indicating a total cessation (‘growth collapse’) of stem increment under ENSO-related drought conditions and demonstrating the high impact of climatic extreme events on carbon sequestration of the dry tropical forest ecosystem.

References

1. Agrawal AA (1996a) Seed germination of Loxopterygium guasango, a threatened tree of coastal Northwestern South America. Trop Ecol 37:273–276
2. Agrawal AA (1996b) Reforestation in Ecuador’s dry forest. Desert Plants 12:12–14
3. Appelhans T (2013) Metvurst: METeorological visualisation utilities using R for science and teaching. https://​metvurst.​wordpress.​com/​. Accessed 31 Aug 2015
4. Bazo J, de las Nieves Lorenzo M, Porfirio da Rocha R (2013) Relationship between monthly rainfall in NW Peru and tropical sea surface temperature. Adv Meteorol. doi:10.​1155/​2013/​152875
5. Bendix J, Trachte K, Palacopis E, Rollenbeck R, Göttlicher D, Nauss T, Bendix A (2011) El Niño meets La Niña—anomalous rainfall patterns in the “Traditional” El Niño region of Southern Ecuador. Erdkd 65:151–167CrossRef
6. Biondi F, Hartsough P (2010) Using automated point dendrometers to analyze tropical treeline stem growth at Nevado de Colima, Mexico. Sens 10(6):5827–5844CrossRef
7. Biondi F, Rossi S (2014) Plant-water relationships in the Great Basin Desert of North America derived from Pinus monophylla hourly dendrometer records. Intern J Biometeorol. doi:10.​1007/​s00484-0-014-0907-4
8. Biondi F, Hartsough P, Estrada I (2005) Daily weather and tree growth at the tropical treeline of North America. Arctic Antarct Alp Res 37:16–24CrossRef
9. Boening C, Willis JK, Landerer FW, Nerem RS, Fasullo J (2012) The 2011 La Niña: so strong, the oceans fell. Geophys Res Lett 39:L19602
10. Boninsegna J, Argollo J, Aravena J, Brichivich J, Christie D, Ferrero M, Lara A, Le Quesne C, Luckmann B, Masiokas M, Morales M, Oliveiera J, Roig F, Srur A, Villalba R (2009) Dendroclimatological reconstructions in South America: a review. Paleogeogr Paleoclimatol Paleoecol 281:210–228CrossRef
11. Borchert R (1994) Water status and development of tropical trees during seasonal drought. Trees 8:115–125CrossRef
12. Borchert R, Renner SR, Calle Z, Navarrete D, Tye A, Gautier L, Spichiger R, von Hildebrand P (2005) Photoperiodic induction of synchronous flowering near the Equator. Nature 433:627–629CrossRefPubMed
13. Bräuning A, von Schnakenburg P, Volland-Voigt F, Peters T (2008) Seasonal growth dynamics and its climate forcing in a tropical mountain rain forest in southern Ecuador. Tree Rings Archaeol Climatol Ecol 6:27–30
14. Bräuning A, Volland-Voigt F, Burchardt I, Ganzhi O, Nauss T, Peters T (2009a) Climatic control of radial growth of Cedrela montana in a humid mountain rain forest in southern Ecuador. Erdkd 63:337–345CrossRef
15. Bräuning A, Volland-Voigt F, von Schnakenburg P (2009b) Jahrringe als Ausdruck von Klimabedingungen und Lebensform: wie wachsen Tropenbäume? Biol unserer Zeit 39:124–132CrossRef
16. Brienen R, Lebrija-Trejos E, Zuidema P, Marinez-Ramos M (2010) Climate–growth analysis for Mexican dry forest tree shows strong impact of sea surface temperatures and predicts future growth declines. Glob Change Biol 16:2001–2012CrossRef
17. Bullock SH, Mooney HA, Medina E (1995) Seasonally dry tropical forests, 1st edn. Cambridge University Press, Cambridge Books, Cambridge. doi:10.​1017/​CBO9780511753398​ CrossRef
18. Bunn A (2008) A dendrochronology program library in R. Dendrochronologia 26:115–124CrossRef
19. Burnham RJ, Carranco N (2004) Miocene winged fruits of Loxopterygium (Anacardiaceae) from the ecuadorian Andes. Am J Bot 91:1767–1773CrossRefPubMed
20. Cardoso F, Marques R, Botosso P, Marques M (2012) Stem growth and phenology of two tropical trees in contrasting soil conditions. Plant Soil 354:269–281CrossRef
21. Clark DA, Clark DB (1994) Climate-induced annual variation in canopy tree growth in a Costa Rican tropical rain forest. J Ecol 82(4):865–872CrossRef
22. Cotrill DA (2012) Seasonal climate summery southern hemisphere (spring 2011): La Niña returns. Aust Meteorol Oceanograph J 62:179–192
23. Deslauriers A, Rossi S, Anfodillo T (2007) Dendrometer and intraannual tree growth: what kind of information can be inferred? Dendrochronologia 25:113–124CrossRef
24. Do FC, Goudiaby VA, Gimenez O, Diagne AL, Diouf M, Rocheteau A, Akpo LE (2005) Environmental influence on canopy phenology in the dry tropics. Forest Ecol Manag 215:319–328CrossRef
25. Drew DM, Downes GD (2009) The use of precision dendrometers in research on daily stem size and wood property variation: a review. Denrochronologia 27:159–172CrossRef
26. Drew DM, Richards AE, Cook GD, Downes GM, Gill W, Baker PJ (2014) The number of days on which increment occurs is the primary determinant of annual ring width in Callitris intratropica. Trees 28:31–40CrossRef
27. Eamus D (1999) Ecophysiological traits of deciduous and evergreen woody species in the seasonally dry tropics. Trees 14:11–16
28. Estrada-Medina H, Santiago LS, Graham RC, Allan MF, Jimenez-Osornio JJ (2013) Source water, phenology and growth of two tropical dry forest tree species growing on shallow karst soils. Trees 27:1297–1307CrossRef
29. Fichtler E, Trouet V, Beeckman H, Coppin P, Worbes M (2004) Climatic signals in tree rings of Burkea africana and Pterocarpus angolensis from semiarid forests in Namibia. Trees 18:442–451CrossRef
30. Garreaud RD, Vuille M, Compagnucci R, Marengo J (2009) Present-day South American climate. Palaeogeogr Palaeoclimatol Palaeoecol 281:180–195CrossRef
31. Gebrekirstos A, Mitlöhner R, Teketay D, Worbes M (2008) Climate-growth relationships of the dominant tree species from semi-arid savanna woodland in Ethiopia. Trees 22:631–641CrossRef
32. Gebrekirstos A, Bräuning A, Sass-Klaassen U, Mbow C (2014) Opportunities and applications of dendrochronology in Africa. Curr Opin Env Sustain 6(1):48–53CrossRef
33. Gonzáles Estrella JE, Garcia Riofrio JC, Correa Conde J (2005) Especies forestales del bosqoue seco “Cerro Negro-Cazaderos” Zapotillo—Puyango—Loja Ecuador. Fundación Ecológica Arcoiris, Loja
34. Grogan J, Schulze M (2012) The impact of annual and seasonal rainfall patterns on growth and phenology of emergent tree species in Southeastern Amazonia, Brazil. Biotropica 44(3):331–340CrossRef
35. Heidelberger M, Rao C (1966) Immunchemical properties of hualtaco gum. Immunology 10(6):543–548PubMedPubMedCentral
36. Hoyos N, Escobar J, Restrepo JC, Arango AM, Ortiz JC (2013) Impact of the 2010–2011 La Niña phenomenon in Columbia, South America: the human toll of an extreme weather event. Appl Geogr 39:16–25 CrossRef
37. Jiang Y, Wang B-Q, Dong M-U, Huang Y-M, Wang M-C, Wang B (2015) Response of daily stem radial growth of Platycladus orientalis to environmental factors in a semi-arid area of North China. Trees 29:87–96CrossRef
38. Krepkowski J, Bräuning A, Gebrekirstos A, Strobl S (2011) Cambial growth dynamics and climatic control of different tree life forms in tropical mountain forest in Ethiopia. Trees 25:59–70CrossRef
39. Krepkowski J, Gebrekirstos A, Shibistova O, Bräuning A (2013) Stable carbon isotope labeling reveals different carry-over effects between functional types of tropical trees in an Ethiopian mountain forest. New Phytol 199:431–440CrossRef
40. Lagos P, Silva Y, Nickl E, Mosquera K (2008) El Niño-related precipitation variability in Perú. Adv Geosci 14:231–237CrossRef
41. Linares-Palomino R, Ponce-Alvarez SI (2005) Tree community patterns on seasonally dry forests in the Cerros de Amotape Cordillera, Tumbes, Peru. Forest Ecol Manag 209:261–272CrossRef
42. Linares-Palomino R, Ponce-Alvarez SI (2009) Structural patterns and floristics of a seasonally dry forest in Reserva Ecológica Chaparri, Lambayeque, Peru. Tropic Ecol 50:305–314
43. Linares-Palomino R, Kvist LP, Aguirre-Mendoza Z, Gonzales-Inca C (2010) Diversity and endemism of woody plant species in the Equatorial Pacific seasonally dry forest. Biodivers Conserv 19:169–185CrossRef
44. Maestre F, Quero J, Gotelli N, Escudero A, Ochoa V, Delgado-Baquerizo M, García Gómez M, Bowker M, Soliveres S, Escolar C, García-Palacios P, Berdugo M, Valencia E, Gozalo B, Gallardo A, Aguilera L, Arredondo T, Blones J, Boeken B, Bran D, Conceição A, Cabrera O, Chaieb M, Derak M, Eldridge D, Espinosa C, Florentino A, Gaitán J, Gatica G, Ghiloufi W, Gómez-González S, Gutiérrez R, Hernández R, Huang X, Huber-Sannwald E, Jankju M, Miriti M, Monerris J, Mau R, Morici E, Naseri K, Ospina A, Polo V, Prina A, Pucheta E, Ramírez-Collantes D, Romão R, Tighe M, Torres-Díaz C, Val J, Veiga J, Wang D, Zaady E (2012) Plant species richness and ecosystem multifunctionality in global drylands. Science 335:214–218CrossRefPubMedPubMedCentral
45. Mayle FE (2004) Assessment of the Neotropical dry forest refugia hypothesis in the light of palaeoecological data and vegetation model simulations. J Q Sci 19:713–720CrossRef
46. Méndez-Alonso R, Pineda-García F, Paz H, Rosell JA, Olson JC (2013) Leaf phenology is associated with soil water availability and xylem traits in a tropical dry forest. Trees 27:745–754CrossRef
47. Ministerio de Agricultura y Ganaderia (1984) Macara—Mapa de Suelos, Quito
48. Ministerio de Recursos Naturales y Energeticos (1982) National geological map of the republic of Ecuador, Quito
49. Pennington RT, Lewis G, Ratter JA (2006) Neotropical savannas and dry forests: plant diversity. Biogeography and observation. CRC Press, FloridaCrossRef
50. Pompa-García M, Miranda-Aragón L, Aguirre-Salado CA (2015) Tree growth response to ENSO in Durango, Mexico. Int J Biometerol 59:89–97CrossRef
51. Pucha Cofrep D, Peters T, Bräuning A (2015) Wet season precipitation during the past 120 years reconstructed from tree rings of a tropical dry forest in Southern Ecuador. Global Planet Change 133:65–78CrossRef
52. Reich P, Borchert R (1982) Phenology and ecophysiology of the tropical tree, Tabebuia neochrysantha(Bignoniaceae). Ecology 63:294–299CrossRef
53. Rodríguez R, Mabres A, Luckman B, Evans M, Masiokas M, Ektvedt TM (2005) “El Niño” events recorded in dry-forest species of the lowlands of northwest Peru. Dendrochronologia 22:181–186CrossRef
54. Rozendaal DMA, Zuidema PA (2011) Dendroecology in the tropics: a review. Trees 25:3–16CrossRef
55. Särkinen T, Pennington RT, Lavin M, Simon MF, Hughes CE (2012) Evolutionary islands in the Andes: persistence and isolation explain high endemism in Andes dry tropical forests. J Biogeogr 39:884–900CrossRef
56. Sass-Klaassen U, Couralet C, Sahle Y, Sterck F (2008) Juniper from Ethiopia contains a large-scale precipitation signal. Int J Plant Sci 169(8):1057–1065CrossRef
57. Sayer EJ, Newbery DM (2003) The role of tree size in the leafing phenology of seasonally dry tropical forest in Belize, Central America. J Trop Ecol 19:539–548CrossRef
58. Schöngart J, Junk W, Piedade M, Ayres J, Hüttermann A, Worbes M (2004) Teleconnection between tree growth in the Amazonian floodplains and El-Niño-Southern Oscillation effect. Glob Change Biol 10:683–692CrossRef
59. Steppe K, Sterck F, Deslauries A (2015) Diel growth dynamics in tree stems: linking anatomy and ecophysiology. Trends Plant Sci. doi:10.​1016/​j.​tplants.​2015.​03.​015
60. Takahashi K (2004) The atmospheric circulation associated with extreme rainfall events in Piura, Peru, during the 1997–1998 and 2002 El Niño events. Ann Geophys 22:3917–3926CrossRef
61. Tobin S (2012) Seasonal climate summary southern hemisphere (winter 2011): a dry season in the lull of La Niña events. Aust Meteorol Oceanograph J 62:97–110
62. Tobin S, Skinner TCL (2012) Seasonal climate summary southern hemisphere (autumn 2011): one of the strongest La Niña events on record begins to decline. Aust Meteorol Oceanograph J 62:39–50
63. Trenberth KE (1997) The definition of El Niño. B Am Meteorol Soc 78:2771–2777CrossRef
64. Trouet V, Coppin P, Beeckman H (2006) Annual growth ring patterns in Brachystegia spiciformis reveal influence of precipitation on tree growth. Biotropica 38:375–382CrossRef
65. United States Department of Agriculture, Natural Resources Conservation Service (1999) Soil Taxonomy: a basic system of soil classification for making and interpreting soil surveys. Government Printing Office Washington, Washington
66. Valdez-Hernández M, Andrade J, Jackson P, Rebolledo-Vieyra M (2010) Phenology of five tree species of a tropical forest in Yucatan, Mexico: effects of environmental and physiological factors. Plant Soil 329:144–171CrossRef
67. Valencia R, Cerón C, Palacios W, Sierra R. (1999) Las Formaciones naturales de la Sierra del Ecuador. In: Sierra R (edn) Propuesta preliminar de un sistema de clasificación de vegetación para el Ecuador Continental. Proyecto INEFAN/GEF y Ecociencia Quito-Ecuador, pp 79–108
68. Volland-Voigt F, Bräuning A, Ganzhi O, Peters T, Maza H (2011) Radial stem variations of Tabebuia chrysantha(Bignoniaceae) in different tropical forest ecosystems of southern Ecuador. Trees 25:39–48CrossRef
69. Vuille M, Bradley RS (2000) Mean annual temperature trends and their vertical structure in the tropical Andes. Geophys Res Lett 27:3885–3888CrossRef
70. Vuille M, Bradley RS, Keimig F (2000) Climate variability in the Andes of Ecuador and its relation to tropical Pacific and Atlantic sea surface temperature anomalies. J Climate 13:2520–2535CrossRef
71. Wagner F, Rossi V, Aubry-Kientz M, Bonal D, Dalitz H (2014) Pan-tropical analysis of climate effects on seasonal tree growth. PLoS ONE 9(3):e92337. doi:10.​1371/​journal.​pone.​0092337 CrossRefPubMedPubMedCentral
72. Wang Z, Yang B, Deslauriers A, Bräuning A (2014) Intra-annual stem radial increment response of Qilian juniper to temperature and precipitation along an altitudinal gradient in northwestern China. Trees 29:25–34CrossRef
73. Williams RJ, Myers BA, Muller WJ, Duff GA, Eamus D (1997) Leaf phenology of woody species in a north Australian tropical savanna. Ecology 78:2542–2558CrossRef
74. Wils G, Sass-Klassen U, Eshetu Z, Bräuning A, Gebrekirstos A, Couralet C, Robertson I, Touchan R, Koprowski M, Conway D, Briffa K, Beeckman H (2011) Dendrochronology in the dry tropics: the Ethiopian case. Trees 25:345–354CrossRef
75. Wimmer R, Downes GM, Evans R (2002) High resolution analysis of radial growth and wood density in Eucalyptus nitens, grown under different irrigation regimes. Ann For Sci 59:519–524CrossRef
76. Worbes M (1999) Annual growth rings, rainfall-dependent growth and long-term growth pattern of tropical trees from Caparo Forest Reserve in Venezuela. J Ecol 87:391–403CrossRef
77. Worbes M (2002) One hundred years of tree-ring research in the tropics: a brief history and an outlook to future challenges. Dendrochronologia 20:217–231CrossRef
78. Zalamea M, González G (2008) Leaffall phenology in a subtropical wet forest in Puerto Rico: from species to community patterns. Biotropica 40:295–304CrossRef
79. Zanne AE, Lopez-Gonzalez G, Coomes DA, Ilic J, Jansen S, Lewis SL, Miller RB, Swenson NG, Wiemann MC, Chave J (2009) Global wood density database. Dryad. Identifier: http://​hdl.​handle.​net/​10255/​dryad.​235.​2014.​06.​3

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