Growth response of Abies spectabilis to climate along an elevation gradient of the Manang valley in the central Himalayas

Samresh Rai; Binod Dawadi; Yafeng Wang; Xiaoming Lu; Huang Ru; Shalik Ram Sigdel

doi:10.1007/s11676-019-01011-x

Journal of Forestry Research ›› 2019, Vol. 31 ›› Issue (6) : 2245 -2254. DOI: 10.1007/s11676-019-01011-x

Original Paper

Growth response of Abies spectabilis to climate along an elevation gradient of the Manang valley in the central Himalayas

Author information +

History +

PDF

Abstract

The Himalayas are characterized by a broad gradient of bioclimatic zones along their elevation. However, less is known how forest growth responds to climatic change along elevation. In this study, four standard tree-ring width chronologies of Himalayan fir (Abies spectabilis) were developed, spanning 142–649 years along an elevation gradient of 3076–3900 m a.s.l. Principal component analysis classified the four chronologies into two groups; the ones at lower elevations (M1 and M2) and higher elevations (M3 and M4) show two distinct growth trends. Radial growth is limited by summer (June–August) precipitation at M3, and by precipitation during spring (March–May) and summer at M4. It is limited by spring temperatures and winter precipitation (December–February) at M1. Tree-ring width chronologies also significantly correlate with winter and spring Palmer Drought Severity Index (PDSI) at M1, and with summer PDSI at M3 and M4. Thus, Himalayan fir growth at high elevations is mainly limited by moisture stress rather than by low temperatures. Furthermore, the occurrence of missing rings coincides with dry periods, providing additional evidence for moisture limitation of Himalayan fir growth.

Keywords

Climate signals / Tree-ring width / Abies spectabilis / Radial growth / Precipitation / Manang valley / Himalayas

Cite this article

Download citation ▾

Samresh Rai, Binod Dawadi, Yafeng Wang, Xiaoming Lu, Huang Ru, Shalik Ram Sigdel. Growth response of Abies spectabilis to climate along an elevation gradient of the Manang valley in the central Himalayas. Journal of Forestry Research, 2019, 31(6): 2245-2254 DOI:10.1007/s11676-019-01011-x

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Affolter P, Büntgen U, Esper J, Rigling A, Weber P, Luterbacher J, Frank D. Inner alpine conifer response to 20th century drought swings. Eur J For Res, 2010, 129(3): 289-298.

[2]	Allen CD, Breshears DD, McDowell NG. On underestimation of global vulnerability to tree mortality and forest die-off from hotter drought in the anthropocene. Ecosphere, 2015, 6(8): 1-55.

[3]	Bayramzadeh V, Zhu H, Lu X, Attarod P, Zhang H, Li X, Asad F, Liang E. Temperature variability in northern Iran during the past 700 years. Sci Bull, 2018, 63: 462-464.

[4]	Bhattarai KR, Vetaas OR, Grytnes JA. Relationship between plant species richness and biomass in an arid sub-alpine grassland of the central Himalayas, Nepal. Folia Geobot, 2004, 39: 57-71.

[5]	Borgaonkar HP, Sikder AB, Ram S. High altitude forest sensitivity to the recent warming: a tree-ring analysis of conifers from western Himalaya, India. Quat Int, 2011, 236(1–2): 158-166.

[6]	Chen F, Yuan Y, Wei W. Climatic response of Picea crassifolia tree-ring parameters and precipitation. J Arid Environ, 2011, 75: 1121-1128.

[7]	Cook ER (1985) A time series approach to tree ring standardization [dissertation]. University of Arizona, Tuscon, p 171

[8]	Cook ER, Kairiukstis LA. Methods of dendrochronology: applications in the environmental sciences, 2013, Berlin: Springer 394

[9]	Cook ER, Krusic PJ, Jones PD. Dendroclimatic signals in long tree-ring chronologies from the Himalayas of Nepal. Int J Clim, 2003, 23(7): 707-732.

[10]	Dawadi B, Liang E, Tian L, Devkota LP, Yao T. Pre-monsoon precipitation signal in tree rings of timberline Betula utilis in the central Himalayas. Quat Int, 2013, 283: 72-77.

[11]	Ding JZ, Yang T, Zhao YT, Liu D, Wang XY, Yao YT, Peng SS, Wang T, Piao SL. Increasingly important role of atmospheric aridity on Tibetan alpine grasslands. Geophys Res Lett, 2018, 45(6): 2852-2859.

[12]	Fan ZX, Bräuning A, Cao KF. Annual temperature reconstruction in the central Hengduan Mountains, China, as deduced from tree rings. Dendrochronologia, 2008, 26(2): 97-107.

[13]	Fang O, Alfaro RI, Zhang QB. Tree rings reveal a major episode of forest mortality in the late 18th century on the Tibetan Plateau. Glob Planet Change, 2018, 163: 44-50.

[14]	Fritts HC, Smith DG, Cardis JW, Budelsky CA. Tree-ring characteristics along a vegetation gradient in northern Arizona. Ecology, 1965, 46(4): 393-401.

[15]	Gaire NP, Koirala M, Bhuju DR, Borgaonkar HP. Treeline dynamics with climate change at the central Nepal Himalaya. Clim Past, 2014, 10(4): 1277-1290.

[16]	Holmes RL. Computer-assisted quality control in tree-ring dating and measurement. Tree-Ring Bull, 1983, 43: 69-78.

[17]	Hughes MK, Funkhouser G. Frequency-dependent climate signal in upper and lower forest border tree rings in the mountains of the Great Basin. Clim Change, 2003, 59: 233-244.

[18]	IPCC. Climate Change 2014-impacts, adaptation and vulnerability: regional aspects, 2014, Cambridge: Cambridge University Press 688

[19]	Karger DN, Conrad O, Bohner J, Kawohl T, Kreft H, Soria-Auza RW, Zimmermann NE, Linder HP, Kessler M. Climatologies at high resolution for the earth's land surface areas. Sci Data, 2017 4

[20]	Kharal DK, Thapa UK, St. George S, Meilby H, Rayamajhi S, Bhuju DR. Tree-climate relations along an elevational transect in Manang Valley, central Nepal. Dendrochronologia, 2017, 41: 57-64.

[21]	Körner C. Alpine treelines: functional ecology of the global high elevation tree limits, 2012, Basel: Springer 220

[22]	LaMarche VC. Frequency-dependent relationships between tree-ring series along an ecological gradient and some dendroclimatic implications. Tree-Ring Bull, 1974, 34: 1-20.

[23]	Leel S, Melvin TM, Grabner M, Wimmer R, Briffa KR. Tree-ring growth variability in the Austrian Alps: the influence of site, altitude, tree species and climate. Boreas, 2007, 36(4): 426-440.

[24]	Li X, Liang E, Gričar J, Rossi S, Čufar K, Ellison AM. Critical minimum temperature limits xylogenesis and maintains treelines on the southeastern Tibetan Plateau. Sci Bull, 2017, 62(11): 804-812.

[25]	Liang E, Camarero JJ. Threshold-dependent and non-linear associations between temperature and tree growth at and below the alpine treeline. Trees, 2018, 32(2): 661-662.

[26]	Liang E, Wang Y, Xu Y, Liu B, Shao X (2010) Growth variation in Abies georgei var. smithii along altitudinal gradients in the Sygera Mountains, southeastern Tibetan Plateau. Trees 24(2):363–373

[27]	Liang E, Dawadi B, Pederson N, Eckstein D. Is the growth of birch at the upper timberline in the Himalayas limited by moisture or by temperature?. Ecology, 2014, 95(9): 2453-2465.

[28]	Liang E, Leuschner C, Dulamsuren C, Wagner B, Hauck M. Global warming-related tree growth decline and mortality on the north-eastern Tibetan plateau. Clim Change, 2016, 134(1–2): 163-176.

[29]	Liang E, Dawadi B, Pederson N, Piao S, Zhu H, Sigdel SR, Chen D. Strong link between large tropical volcanic eruptions and severe droughts prior to monsoon in the central Himalayas revealed by tree-ring records. Sci Bull, 2019

[30]	Littell JS, Peterson DL, Tjoelker M. Douglas-fir growth in mountain ecosystems: water limits tree growth from stand to region. Ecol Monogr, 2008, 78(3): 349-368.

[31]	Liu X, Qin D, Shao X, Chen T, Ren J. Temperature variations recovered from tree-rings in the middle Qilian Mountain over the last millennium. Sci China Ser D Earth Sci, 2005, 48(4): 521-529.

[32]	Liu LS, Shao XM, Liang EY. Climate signals from tree ring chronologies of the upper and lower treelines in the Dulan region of the northeastern Qinghai-Tibetan Plateau. J Integr Plant Biol, 2006, 48(3): 278-285.

[33]	Lu X, Liang E, Wang Y, Babast F, Leavitt SW, Camarero JJ. Past the climate optimum: recruitment is declining at the world's highest juniper shrublines on the Tibetan Plateau. Ecology, 2019 100 2 e02557

[34]	Lyu L, Suvanto S, Nöjd P, Henttonen HM, Mäkinen H, Zhang QB. Tree growth and its climate signal along latitudinal and altitudinal gradients: comparison of tree rings between Finland and the Tibetan Plateau. Biogeosciences, 2017, 14: 3083-3095.

[35]	Lyu L, Zhang QB, Pellatt MG, Büntgen U, Li MH, Cherubini P. Drought limitation on tree growth at the Northern Hemisphere’s highest tree line. Dendrochronologia, 2019, 53: 40-47.

[36]	Mou YM, Fang O, Cheng X, Qiu H. Recent tree growth decline unprecedented over the last four centuries in a Tibetan juniper forest. J For Res, 2019, 30(4): 1429-1436.

[37]	Panthi S, Bräuning A, Zhou ZK, Fan ZX. Tree rings reveal recent intensified spring drought in the central Himalaya, Nepal. Glob Planet Change, 2017, 157: 26-34.

[38]	Ram S. Tree growth-climate relationships of conifer trees and reconstruction of summer season Palmer Drought Severity Index (PDSI) at Pahalgam in Srinagar, India. Quat Int, 2012, 254: 152-158.

[39]	Ren P, Rossi S, Camarero JJ, Ellison AM, Liang E, Penuelas J. Critical temperature and precipitation thresholds for the onset of xylogenesis of Juniperus przewalskii in a semi-arid area of the north-eastern Tibetan Plateau. Ann Bot, 2018, 121(4): 617-624.

[40]	Sano M, Furuta F, Kobayashi O, Sweda T. Temperature variations since the mid-18th century for western Nepal, as reconstructed from tree-ring width and density of Abies spectabilis. Dendrochronologia, 2005, 23(2): 83-92.

[41]	Savva Y, Oleksyn J, Reich PB, Tjoelker MG, Vaganov EA, Modrzynski J. Interannual growth response of Norway spruce to climate along an altitudinal gradient in the Tatra Mountains, Poland. Trees, 2006, 20(6): 735-746.

[42]	Shrestha UB, Gautam S, Bawa KS. Widespread climate change in the Himalayas and associated changes in local ecosystems. PLoS ONE, 2012 7 5 e36741

[43]	Shrestha KB, Chhetri PK, Bista R. Growth responses of Abies spectabilis to climate variations along an elevational gradient in Langtang National Park in the central Himalaya, Nepal. J For Res, 2017, 22(5): 274-281.

[44]	Sigdel M, Ikeda M. Spatial and temporal analysis of drought in Nepal using standardized precipitation index and its relationship with climate indices. J Hydrol Meteorol, 2010, 7(1): 59-74.

[45]	Sigdel SR, Dawadi B, Camarero J, Liang E, Leavitt S. Moisture-Limited Tree Growth for a Subtropical Himalayan Conifer Forest in Western Nepal. Forests, 2018 9 6 340

[46]	Sigdel SR, Wang Y, Julio Camarero J, Zhu H, Liang E, Penuelas J. Moisture-mediated responsiveness of treeline shifts to global warming in the Himalayas. Glob Change Biol, 2018, 24(11): 5549-5559.

[47]	Sohar K, Altman J, Lehečková E, Doležal J. Growth–climate relationships of Himalayan conifers along elevational and latitudinal gradients. Int J Clim, 2017, 37(5): 2593-2605.

[48]	Thapa UK, Shah SK, Gaire NP, Bhuju DR. Spring temperatures in the far-western Nepal Himalaya since AD 1640 reconstructed from Picea smithiana tree-ring widths. Clim Dyn, 2014, 45(7–8): 2069-2081.

[49]	Tiwari A, Fan ZX, Jump AS, Li SF, Zhou ZK. Gradual expansion of moisture sensitive Abies spectabilis forest in the Trans-Himalayan zone of central Nepal associated with climate change. Dendrochronologia, 2017, 41: 34-43.

[50]	Wang T, Ren H, Ma K. Climatic signals in tree ring of Picea schrenkiana along an altitudinal gradient in the central Tianshan Mountains, northwestern China. Trees, 2005, 19(6): 736-742.

[51]	Wang SY, Yoon JH, Gillies RR, Cho C. What caused the winter drought in western Nepal during recent years?. J Clim, 2013, 26(21): 8241-8256.

[52]	Wang Z, Yang B, Deslauriers A, Bräuning A. Intra-annual stem radial increment response of Qilian juniper to temperature and precipitation along an altitudinal gradient in northwestern China. Trees, 2015, 29(1): 25-34.

[53]	Wigley TML, Briffa KR, Jones PD. On the average value of correlated time series, with applications in dendroclimatology and hydrometeorology. J Clim Appl Meteorol, 1984, 23(2): 201-213.

[54]	Yadav RR, Park WK, Singh J, Dubey B. Do the western Himalayas defy global warming?. Geophys Res Lett, 2004, 31: L17201.

[55]	Yang B, He M, Melvin TM, Zhao Y, Briffa KR. Climate control on tree growth at the upper and lower treelines: a case study in the Qilian Mountains. Tibetan Plateau. PLoS One, 2013 8 7 e69065

[56]	Yao T, Thompson L, Yang W, Yu W, Gao Y, Guo X, Yang X, Duan K, Zhao H, Xu B, Pu J, Lu A, Xiang Y, Kattel DB, Joswiak D. Different glacier status with atmospheric circulations in Tibetan Plateau and surroundings. Nat Clim Change, 2012, 2(9): 663-667.

[57]	Yu J, Liu QJ. Larix olgensis growth–climate response between lower and upper elevation limits: an intensive study along the eastern slope of the Changbai Mountains, northeastern China. J For Res, 2018