Published Date
August 2016, Volume 30, Issue 4, pp 1403-1415

First online: 18 March 2016

Blue intensity parameters derived from Ponderosa pine tree rings characterize intra-annual density fluctuations and reveal seasonally divergent water limitations

• Flurin Babst 
• , William E. Wright
• , Paul Szejner
• , Leon Wells
• , Soumaya Belmecheri
• , Russell K. Monson

Abstract

Key message

A set of novel parameters extracted from fine-spatial resolution blue intensity profiles characterizes intra-annual density fluctuations in Ponderosa pine and complements information on climate sensitivity obtained from radial growth.

Abstract

Rapidly rising evaporative demand threatens forests in semi-arid areas around the world, but the timing of stem growth response to drought is often coarsely known. This is partly due to a shortage of sub-annual growth records, particularly outside the Mediterranean region where most intra-annual density fluctuation (IADF) chronologies are based. We anticipate that an automated, cost-effective, and easily implementable method to characterize IADFs could foster more widespread development of sub-annual chronologies. We applied a peak detection algorithm to fine-spatial resolution blue intensity (BI) profiles of Ponderosa pine tree rings from two sites in southern Arizona (~300 m elevation difference). Out of seven BI parameters that characterize IADFs, peak height, width, and area showed satisfactory chronology statistics. We assessed the response of these BI and radial growth parameters to six monthly resolved climate variables and to the onset date of the North American summer monsoon. Radial growth at the lower-elevation site depended mainly on winter precipitation, whereas the higher site relied on spring and monsoon precipitation. A regular May–June drought period promoted IADFs in early ring portions at both sites. Yet, IADFs at the higher site were only formed, if spring was sufficiently humid to assume enough radial growth. Late-position IADFs were caused by a weak monsoon and additionally promoted by favorable conditions towards the end of the growing season. The contrast between sites is likely attributable to a three-week difference in the growing season onset, emphasizing the importance of growth phenology for drought impacts on forests in the US Southwest.

References

1. Ahlström A, Raupach MR, Schurgers G et al (2015) The dominant role of semi-arid ecosystems in the trend and variability of the land CO2 sink. Science 348:895–899CrossRefPubMed
2. Babst F, Frank D, Büntgen U, Nievergelt D, Esper J (2009) Effect of sample preparation and scanning resolution on the blue reflectance of Picea abies. TRACE Proc 7:188–195
3. Babst F, Alexander MR, Szejner P et al (2014) A tree-ring perspective on the terrestrial carbon cycle. Oecologia 176:307–322CrossRefPubMed
4. Battipaglia G, DeMicco V, Brand WA, Linke P, Aronne G, Saurer M, Cherubini P (2010) Variations of vessel diameter and 13C in false rings of Arbutus unedo L. reflect different environmental conditions. New Phytol 188:1099–1112CrossRefPubMed
5. Battipaglia G, DeMicco V, Brand WA, Saurer M, Aronne G, Linke P, Cherubini P (2013) Drought impact on water-use efficiency and intra-annual density fluctuations in Erica arborea on Elba (Italy). Plant Cell Environ 37:382–391CrossRefPubMed
6. Björklund JA, Gunnarson BE, Seftigen K, Esper J, Linderholm HE (2014) Blue intensity and density from northern Fennoscandian tree rings, exploring the potential to improve summer temperature reconstructions with earlywood information. Clim Past 10:877–885CrossRef
7. Blessing CH, Werner RA, Siegwolf R, Buchmann N (2015) Allocation dynamics of recently fixed carbon in beech saplings in response to increased temperatures and drought. Tree Physiol 35:585–598CrossRefPubMed
8. Bogino S, Bravo F (2009) Climate and intraannual density fluctuations in Pinus pinaster subsp. mesogeensis in Spanish woodlands. Can J For Res 39:1557–1565CrossRef
9. Brice B, Lorion KK, Griffin D et al (2013) Signal strength in sub-annual tree-ring chronologies from Pinus ponderosain Northwestern New Mexico. Tree Ring Res 69:81–86CrossRef
10. Bunn AG (2008) A dendrochronology program library in R (dplR). Dendrochronologia 26:115–124CrossRef
11. Camarero JJ, Olano JM, Parras A (2010) Plastic bimodal xylogenesis in conifers from continental Mediterranean climates. New Phytol 185:471–480CrossRefPubMed
12. Campbell R, McCarroll D, Loader NJ, Grudd H, Robertson I, Jalkanen R (2007) Blue intensity in Pinus sylvestristree rings: developing a new palaeoclimate proxy. Holocene 17:821–828CrossRef
13. Campbell R, McCarroll D, Robertson I, Loader NJ, Grudd H, Gunnarson B (2011) Blue intensity in Pinus sylvestristree rings: a manual for a new palaeoclimate proxy. Tree Ring Res 67:127–134CrossRef
14. Campelo F, Nabais C, Freitas H, Gutierrez E (2007) Climatic significance of tree-ring width and intra-annual density fluctuations in Pinus pinea from a dry Mediterranean area in Portugal. Ann Forest Sci 64:229–238CrossRef
15. Campelo F, Vieira J, Battipaglia G, de Luis M, Nabais C, Freitas H, Cherubini P (2015) Which matters most for the formation of intra-annual density fluctuations in Pinus pinaster: age or size? Trees 29:237–245CrossRef
16. Carvalho A, Nabais C, Vieira J, Rossi S, Campelo F (2015) Plastic response of tracheids in Pinus pinaster in a water-limited environment: adjusting lumen size instead of wall thickness. PLoS One 10:0136305
17. Cheaib A, Badeau V, Boe J (2012) Climate change impacts on tree ranges: model intercomparison facilitates understanding and quantification of uncertainty. Ecol Lett 15:533–544CrossRefPubMed
18. Choat B, Jansen S, Brodribb TJ et al (2012) Global convergence in the vulnerability of forests to drought. Nature 491:752–755PubMed
19. Cook ER, Peters K (1997) Calculating unbiased tree-ring indices for the study of climatic and environmental change. Holocene 7:361–370CrossRef
20. Copenheaver CA, Pokorski EA, Currie JE, Abrams MD (2006) Causation of false ring formation in Pinus banksiana: a comparison of age, canopy class, climate and growth rate. For Ecol Manag 236:348–355CrossRef
21. Cuny H, Rathgeber CBK, Frank DC, Fonti P, Fournier M (2014) Kinetics of tracheid development explain conifer tree-ring structure. New Phytol 203:1231–1241CrossRefPubMed
22. Cuny H, Rathgeber CBK, Frank DC et al (2015) Woody biomass production lags stem-girth increase by over one month in coniferous forests. Nat Plants. doi:10.​1038/​NPLANTS.​2015.​160 PubMed
23. De Luis M, Novak K, Raventos J, Gricar J, Prislan P, Cufar K (2011) Climate factors promoting intra-annual density fluctuations in Aleppo pine (Pinus halepensis) from semiarid sites. Dendrochronologia 29:163–169CrossRef
24. De Micco V, Battipaglia G, Brand WA, Linke P, Saurer M, Aronne G, Cherubini P (2012) Discrete versus continuous analysis of anatomical and 13C variability in tree rings with intra-annual density fluctuations. Trees 26:513–524CrossRef
25. De Micco V, Battipaglia G, Cherubini P, Aronne G (2013) Comparing methods to analyse anatomical features of tree rings with and without intra-annual density fluctuations (IADFs). Dendrochronologia 32:1–6CrossRef
26. De Soto L, De la Cruz M, Fonti P (2011) Intra-annual patterns of tracheid size in the Mediterranean tree Juniperus thurifera as an indicator of seasonal water stress. Can J For Res 41:1280–1294CrossRef
27. Die AD, Kitin P, N’Guessan-Kouame F, Van den Bulcke J, Van Acker J, Beeckman H (2012) Fluctuations in cambial activity in relation to precipitation result in annual rings and intra-annual growth zones of xylem and phloem in teak (Tectona grandis) in Ivory Coast. Ann Bot 110:861–873CrossRefPubMedPubMedCentral
28. Eschbach W, Nogler P, Schär E, Schweingruber FH (1995) Technical advances in the radiodensitometrical determination of wood density. Dendrochronologia 13:155–168
29. Frank DC, Poulter B, Saurer M et al (2015) Water-use efficiency and transportation across European forests during the Anthropocene. Nat Clim Change 5:579–583CrossRef
30. Franklin O, Johansson J, Dewar RC et al (2012) Modeling carbon allocation in trees: a search for principles. Tree Physiol 32:648–666CrossRefPubMed
31. Franks PJ, Adams MA, Amthor JS et al (2013) Sensitivity of plants to changing atmospheric CO2 concentration: from the geological past to the next century. New Phytol 197:1077–1094CrossRefPubMed
32. Gonzalez-Benecke CA, Rivieros-Walker AJ, Martin TA, Peter GF (2015) Automated quantification of intra-annual density fluctuations using microdensity profiles of mature Pinus taeda in replicated irrigation experiment. Trees 29:185–197CrossRef
33. Griffin D, Meko DM, Touchan R, Leavitt S, Woodhouse CA (2011) Latewood chronology development for summer moisture reconstruction in the US Southwest. Tree Ring Res 67:87–101CrossRef
34. Griffin D, Woodhouse CA, Meko DM et al (2013) North American monsoon precipitation reconstructed from tree-ring latewood. Geophys Res Lett 40:954–958CrossRef
35. Gustafson EJ (2013) When relationships estimated in the past cannot be used to predict the future: using mechanistic models to predict landscape ecological dynamics in a changing world. Landsc Ecol 28:1429–1437CrossRef
36. Higgins RW, Shi W (2001) Intercomparison of the principal modes of interannual and intraseasonal variability of the North American Monsoon System. J Clim 14:403–417CrossRef
37. Hijmans RJ, Cameron SE, Parra JL, Jones PG, Jarvis A (2005) Very high resolution interpolated climate surfaces for global land areas. Int J Climatol 25:1965–1978CrossRef
38. Holmes RL (1983) Computer-assisted quality control in treering dating and measurement. Tree Ring Bull 43:69–78
39. Leavitt S, Wright WE, Long A (2002) Spatial expression of ENSO, drought, and summer monsoon in seasonal 13C of ponderosa pine tree rings in southern Arizona and New Mexico. J Geophys Res 107:3–10CrossRef
40. Liang E, Leuschner C, Dulamsuren C, Wagner B, Hauck M (2016) Global warming-related tree growth decline and mortality on the north-eastern Tibetan plateau. Clim Change 134:163–176CrossRef
41. Lin YS, Medlyn BE, Duursma RA et al (2015) Optimal stomatal behavior around the world. Nat Clim Change 5:459–464CrossRef
42. Lupi C, Morin H, Deslauriers A, Rossi S (2010) Xylem phenology and wood production: resolving the chicken-or-egg dilemma. Plant Cell Environ 33:1721–1730CrossRefPubMed
43. McCarroll D, Pettigrew E, Luckman A (2002) Blue reflectance provides a surrogate for latewood density of high-latitude pine tree rings. Arct Antarct Alp Res 34:450–453CrossRef
44. McDowell NG, Allen CD (2015) Darcy’s law predicts widespread forest mortality under climate warming. Nat Clim Change 5:669–672CrossRef
45. McDowell NG, Allen CD, Marshall L (2010) Growth, carbon-isotope discrimination, and drought-associated mortality across a Pinus ponderosa elevational transect. Global Change Biol 16:399–415CrossRef
46. McDowell NG, Beerling DJ, Breshears DD, Fisher RA, Raffa KF, Stitt M (2011) The interdependence of mechanisms underlying climate-driven vegetation mortality. Trends Ecol Evol 26:523–532CrossRefPubMed
47. McDowell NG, Williams AP, Xu C et al (2015) Multi-scale predictions of massive conifer mortality due to chronic temperature rise. Nat Clim Change. doi:10.​1038/​NCLIMATE2873
48. Meko DM, Baisan CH (2001) Pilot study of latewood-width of conifers as an indicator of variability of summer rainfall in the North American monsoon region. Int J Climatol 21:697–708CrossRef
49. Nabais C, Campelo F, Vieira J, Cherubini P (2014) Climatic signals of tree-ring width and intra-annual density fluctuations in Pinus pinea and Pinus pinaster along a latitudinal gradient in Portugal. Forestry 87:598–605CrossRef
50. Novak K, Saz Sanches MA, Cufar K, Raventos J, de Luis M (2013) Age, climate and intra-annual density fluctuations in Pinus halepensis in Spain. IAWA Journal 34:459–474CrossRef
51. Olivar J, Bogino S, Spiecker H, Bravo F (2012) Climate impact on growth dynamic and intra-annual density fluctuations in Aleppo pine (Pinus halepensis) trees of different crown classes. Dendrochronologia 30:35–47CrossRef
52. Ren P, Rossi S, Gricar J, Liang E, Cufar K (2015) Is precipitation a trigger for the onset of xylogenesis in Juniperus przewalskii on the north-eastern Tibetan Plateau? Ann Bot 115:629–639CrossRefPubMedPubMedCentral
53. Richardson AD, Keenan TF, Migliavacca M, Ryu Y, Sonnentag O, Toomey M (2013) Climate change, phenology, and phenological control of vegetation feedbacks to the climate system. Agric For Meteorol 169:156–173CrossRef
54. Rossi S, Girard MJ, Morin H (2014) Lengthening of the duration of xylogenesis engenders disproportionate increases in xylem production. Global Change Biol 20:2261–2271CrossRef
55. Sala A, Piper F, Hoch G (2010) Physiological mechanisms of drought-induced tree mortality are far from being resolved. New Phytol 186:274–281CrossRefPubMed
56. Schwalm C, Williams CA, Schaefer K et al (2012) Reduction in carbon uptake during turn of the century drought in western North America. Nat Geosci 5:551–556CrossRef
57. Schweingruber FH (1983) Der Jahrring. Haupt Verlag, Bern
58. Sevanto S, Dickman T (2015) Where does the carbon go? Plant carbon allocation under climate change. Tree Physiol 35:581–584CrossRefPubMed
59. Sevanto S, McDowell N, Dickman T, Pangle R, Pockman W (2014) How do trees die? A test of the hydraulic failure and carbon starvation hypotheses. Plant Cell Environ 37:153–161CrossRefPubMed
60. Stahle DW, Cleaveland MK, Grissino-Mayer HD, Griffin RD, Fye FK, Therrell MD, Burnette DJ, Meko DM, Villanueva Diaz J (2009) Cool- and warm-season precipitation reconstructions over Western New Mexico. J Clim 22:3729–3750CrossRef
61. Szejner P (2011) Tropical dendrochronology: exploring tree-rings of Pinus oocarpa in eastern Guatemala. Master Thesis, Georg-August Universität, Göttingen
62. Tatarinov F, Rotenberg E, Masyek K, Ogee J, Klein T, Yakir D (2015) Resilience to seasonal heat wave episodes in a Mediterranean pine forest. New Phytol. doi:10.​1111/​nph.​13791
63. Touchan R, Shishov VV, Meko DM, Nouiri I, Grachev A (2012) Process based model sheds light on climate sensitivity of Mediterranean tree-ring width. Biogeosciences 9:965–972CrossRef
64. Venegas-Gonzalez A, von Arx G, Perez Chagas M, Filho MT (2015) Plasticity in xylem anatomical traits of two tropical species in response to intra-seasonal climate variability. Trees Struct Funct 29:423–435CrossRef
65. Vieira J, Campelo F, Nabais C (2009) Age-dependent responses of tree-ring growth and intra-annual density fluctuations of Pinus pinaster to Mediterranean climate. Trees Struct Funct 23:257–265CrossRef
66. Vieira J, Campelo F, Nabais C (2010) Intra-annual density fluctuations of Pinus pinaster are a record of climatic changes in the western Mediterranean region. Can J For Res 40:1567–1575CrossRef
67. Vieira J, Rossi S, Campelo F, Freitas H, Nabais C (2014) Xylogenesis of Pinus pinaster under a Mediterranean climate. Ann Forest Sci 71:71–80CrossRef
68. Vieira J, Campelo F, Rossi S, Carvalho A, Freitas H, Nabais C (2015) Adjustment capacity of maritime pine cambial activity in drought-prone environments. PLoS One 10:e0126223CrossRefPubMedPubMedCentral
69. Wei Y, Liu S, Huntzinger D, Michalak AM, Viovy N, Post WM, Schwalm C, Schaefer K, Jacobson AR, Lu C, Tian H, Ricciuto DM, Cook RB, Mao J, Shi X (2014) NACP MsTMIP: global and North American driver data for multi-model intercomparison. Data set. http://​daac.​ornl.​gov from Oak Ridge National Laboratory Distributed Active Archive Center, Oak Ridge. doi:10.​3334/​ORNLDAAC/​1220
70. Wilkinson S, Ogee J, Domec JC, Rayment M, Wingate L (2015) Biophysical modeling of intra-ring variations in tracheid features and wood density of Pinus pinaster trees exposed to seasonal droughts. Tree Physiol. doi:10.​1093/​treephys/​tpv01 PubMed
71. Williams AP, Allen CD, Macalady AK et al (2013) Temperature as a potent driver of regional forest drought stress and tree mortality. Nat Clim Change 3:292–297CrossRef
72. Woodruff DR, Meinzer FC (2011) Water stress, shoot growth and storage of non-structural carbohydrates along a tree height gradient in a tall conifer. Plant Cell Environ 34:1920–1930CrossRefPubMed
73. Zang C, Biondi F (2013) Dendroclimatic calibration in R: the bootRes package for response and correlation function analysis. Dendrochronologia 31:68–74CrossRef

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