Treeline dynamics in relation to climatic variability in the central Tianshan Mountains, northwestern China

Aim: Climate variability may be an important mediating agent of ecosystem dynamics in cold, arid regions such as the central Tianshan Mountains, north-western China. Tree-ring chronologies and the age structure of a Schrenk spruce (Picea schrenkiana) forest were developed to examine treeline dynamic...

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Published inGlobal ecology and biogeography Vol. 15; no. 4; pp. 406 - 415
Main Authors Wang, Ting, Zhang, Qi-Bin, Ma, Keping
Format Journal Article
LanguageEnglish
Published Oxford, UK Blackwell Publishing Ltd 01.07.2006
Blackwell Publishing
Blackwell
Subjects
Age structure
Animal and plant ecology
Animal, plant and microbial ecology
Biological and medical sciences
Climate change
Climate models
climatic fluctuation
Dendroclimatology
Forest ecology
Fundamental and applied biological sciences. Psychology
General aspects
Growth rings
Picea schrenkiana
radial growth
Summer
Synecology
Timberlines
Tree growth
tree rings
treeline dynamics
Trees
Asia
China
Climate
Fluctuations
Growth
Biogeography
Ecology
Picea schrenkiana
Climatic condition
Tree ring
Mountain
Geographic distribution
Age structure
Gymnospermae
treeline dynamics
radial growth
Coniferales
Spermatophyta
climatic fluctuation
Age
Picea
tree rings
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Abstract Aim: Climate variability may be an important mediating agent of ecosystem dynamics in cold, arid regions such as the central Tianshan Mountains, north-western China. Tree-ring chronologies and the age structure of a Schrenk spruce (Picea schrenkiana) forest were developed to examine treeline dynamics in recent decades in relation to climatic variability. Of particular interest was whether tree-ring growth and population recruitment patterns responded similarly to climate warming. Location: The study was conducted in eight stands that ranged from 2500 m to 2750 m a.s.l. near the treeline in the Tianchi Nature Reserve (43°45'-43°59' N, 88°00'-88°20' E) in the central Xinjiang Uygur Autonomous Region, northwestern China. Methods: Tree-ring cores were collected and used to develop tree-ring chronologies. The age of sampled trees was determined from basal cores sampled as close as possible to the ground. Population age structure and recruitment information were obtained using an age-d.b.h. (diameter at breast height) regression from the sampled cores and the d.b.h. measured on all trees in the plots. Ring-width chronologies and tree age structure were both used to investigate the relationship between treeline dynamics and climate change. Results: Comparisons with the climatic records showed that both the radial growth of trees and tree recruitment were influenced positively by temperature and precipitation in the cold high treeline zone, but the patterns of their responses differed. The annual variation in tree rings could be explained largely by the average monthly minimum temperatures during February and August of the current year and by the monthly precipitation of the previous August and January, which had a significant and positive effect on tree radial growth. P. schrenkiana recruitment was influenced mainly by consecutive years of high minimum summer temperatures and high precipitation during spring. Over the last several decades, the treeline did not show an obvious upward shift and new recruitment was rare. Some trees had established at the treeline at least 200 years ago. Recruitment increased until the early 20th century (1910s) but then decreased with poor recruitment over the past several decades (1950-2000). Main conclusions: There were strong associations between climatic change and ring-width patterns, and with recruitments in Schrenk spruce. Average minimum temperatures in February and August, and total precipitation in the previous August and January, had a positive effect on tree-ring width, and several consecutive years of high minimum summer temperature and spring precipitation was a main factor favouring the establishment of P. schrenkiana following germination within the treeline ecotone. Both dendroclimatology and recruitment analysis were useful and compatible to understand and reconstruct treeline dynamics in the central Tianshan Mountains.
AbstractList Aim  Climate variability may be an important mediating agent of ecosystem dynamics in cold, arid regions such as the central Tianshan Mountains, north‐western China. Tree‐ring chronologies and the age structure of a Schrenk spruce ( Picea schrenkiana ) forest were developed to examine treeline dynamics in recent decades in relation to climatic variability. Of particular interest was whether tree‐ring growth and population recruitment patterns responded similarly to climate warming. Location  The study was conducted in eight stands that ranged from 2500 m to 2750 m a.s.l. near the treeline in the Tianchi Nature Reserve (43°45′−43°59′ N, 88°00′−88°20′ E) in the central Xinjiang Uygur Autonomous Region, northwestern China. Methods  Tree‐ring cores were collected and used to develop tree‐ring chronologies. The age of sampled trees was determined from basal cores sampled as close as possible to the ground. Population age structure and recruitment information were obtained using an age–d.b.h. (diameter at breast height) regression from the sampled cores and the d.b.h. measured on all trees in the plots. Ring‐width chronologies and tree age structure were both used to investigate the relationship between treeline dynamics and climate change. Results  Comparisons with the climatic records showed that both the radial growth of trees and tree recruitment were influenced positively by temperature and precipitation in the cold high treeline zone, but the patterns of their responses differed. The annual variation in tree rings could be explained largely by the average monthly minimum temperatures during February and August of the current year and by the monthly precipitation of the previous August and January, which had a significant and positive effect on tree radial growth. P. schrenkiana recruitment was influenced mainly by consecutive years of high minimum summer temperatures and high precipitation during spring. Over the last several decades, the treeline did not show an obvious upward shift and new recruitment was rare. Some trees had established at the treeline at least 200 years ago. Recruitment increased until the early 20th century (1910s) but then decreased with poor recruitment over the past several decades (1950–2000). Main conclusions  There were strong associations between climatic change and ring‐width patterns, and with recruitments in Schrenk spruce. Average minimum temperatures in February and August, and total precipitation in the previous August and January, had a positive effect on tree‐ring width, and several consecutive years of high minimum summer temperature and spring precipitation was a main factor favouring the establishment of P. schrenkiana following germination within the treeline ecotone. Both dendroclimatology and recruitment analysis were useful and compatible to understand and reconstruct treeline dynamics in the central Tianshan Mountains.
ABSTRACT Aim  Climate variability may be an important mediating agent of ecosystem dynamics in cold, arid regions such as the central Tianshan Mountains, north‐western China. Tree‐ring chronologies and the age structure of a Schrenk spruce (Picea schrenkiana) forest were developed to examine treeline dynamics in recent decades in relation to climatic variability. Of particular interest was whether tree‐ring growth and population recruitment patterns responded similarly to climate warming. Location  The study was conducted in eight stands that ranged from 2500 m to 2750 m a.s.l. near the treeline in the Tianchi Nature Reserve (43°45′−43°59′ N, 88°00′−88°20′ E) in the central Xinjiang Uygur Autonomous Region, northwestern China. Methods  Tree‐ring cores were collected and used to develop tree‐ring chronologies. The age of sampled trees was determined from basal cores sampled as close as possible to the ground. Population age structure and recruitment information were obtained using an age–d.b.h. (diameter at breast height) regression from the sampled cores and the d.b.h. measured on all trees in the plots. Ring‐width chronologies and tree age structure were both used to investigate the relationship between treeline dynamics and climate change. Results  Comparisons with the climatic records showed that both the radial growth of trees and tree recruitment were influenced positively by temperature and precipitation in the cold high treeline zone, but the patterns of their responses differed. The annual variation in tree rings could be explained largely by the average monthly minimum temperatures during February and August of the current year and by the monthly precipitation of the previous August and January, which had a significant and positive effect on tree radial growth. P. schrenkiana recruitment was influenced mainly by consecutive years of high minimum summer temperatures and high precipitation during spring. Over the last several decades, the treeline did not show an obvious upward shift and new recruitment was rare. Some trees had established at the treeline at least 200 years ago. Recruitment increased until the early 20th century (1910s) but then decreased with poor recruitment over the past several decades (1950–2000). Main conclusions  There were strong associations between climatic change and ring‐width patterns, and with recruitments in Schrenk spruce. Average minimum temperatures in February and August, and total precipitation in the previous August and January, had a positive effect on tree‐ring width, and several consecutive years of high minimum summer temperature and spring precipitation was a main factor favouring the establishment of P. schrenkiana following germination within the treeline ecotone. Both dendroclimatology and recruitment analysis were useful and compatible to understand and reconstruct treeline dynamics in the central Tianshan Mountains.
Aim: Climate variability may be an important mediating agent of ecosystem dynamics in cold, arid regions such as the central Tianshan Mountains, north-western China. Tree-ring chronologies and the age structure of a Schrenk spruce (Picea schrenkiana) forest were developed to examine treeline dynamics in recent decades in relation to climatic variability. Of particular interest was whether tree-ring growth and population recruitment patterns responded similarly to climate warming. Location: The study was conducted in eight stands that ranged from 2500 m to 2750 m a.s.l. near the treeline in the Tianchi Nature Reserve (43°45'-43°59' N, 88°00'-88°20' E) in the central Xinjiang Uygur Autonomous Region, northwestern China. Methods: Tree-ring cores were collected and used to develop tree-ring chronologies. The age of sampled trees was determined from basal cores sampled as close as possible to the ground. Population age structure and recruitment information were obtained using an age-d.b.h. (diameter at breast height) regression from the sampled cores and the d.b.h. measured on all trees in the plots. Ring-width chronologies and tree age structure were both used to investigate the relationship between treeline dynamics and climate change. Results: Comparisons with the climatic records showed that both the radial growth of trees and tree recruitment were influenced positively by temperature and precipitation in the cold high treeline zone, but the patterns of their responses differed. The annual variation in tree rings could be explained largely by the average monthly minimum temperatures during February and August of the current year and by the monthly precipitation of the previous August and January, which had a significant and positive effect on tree radial growth. P. schrenkiana recruitment was influenced mainly by consecutive years of high minimum summer temperatures and high precipitation during spring. Over the last several decades, the treeline did not show an obvious upward shift and new recruitment was rare. Some trees had established at the treeline at least 200 years ago. Recruitment increased until the early 20th century (1910s) but then decreased with poor recruitment over the past several decades (1950-2000). Main conclusions: There were strong associations between climatic change and ring-width patterns, and with recruitments in Schrenk spruce. Average minimum temperatures in February and August, and total precipitation in the previous August and January, had a positive effect on tree-ring width, and several consecutive years of high minimum summer temperature and spring precipitation was a main factor favouring the establishment of P. schrenkiana following germination within the treeline ecotone. Both dendroclimatology and recruitment analysis were useful and compatible to understand and reconstruct treeline dynamics in the central Tianshan Mountains.
Author Zhang, Qi-Bin
Wang, Ting
Ma, Keping
Author_xml – sequence: 1
  givenname: Ting
  surname: Wang
  fullname: Wang, Ting
  organization: Laboratory of Quantitative Vegetation Ecology, Institute of Botany, Chinese Academy of Sciences, Beijing, 100093, China
– sequence: 2
  givenname: Qi-Bin
  surname: Zhang
  fullname: Zhang, Qi-Bin
  organization: Laboratory of Quantitative Vegetation Ecology, Institute of Botany, Chinese Academy of Sciences, Beijing, 100093, China
– sequence: 3
  givenname: Keping
  surname: Ma
  fullname: Ma, Keping
  email: makp@brim.ac.cn
  organization: E-mail: makp@brim.ac.cn
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Issue 4
Keywords Climate
Fluctuations
Growth
Biogeography
Ecology
Picea schrenkiana
Climatic condition
Tree ring
Mountain
Geographic distribution
Age structure
Gymnospermae
treeline dynamics
radial growth
Coniferales
Spermatophyta
climatic fluctuation
Age
Picea
tree rings
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PublicationPlace_xml – name: Oxford, UK
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PublicationTitle Global ecology and biogeography
PublicationYear 2006
Publisher Blackwell Publishing Ltd
Blackwell Publishing
Blackwell
Publisher_xml – name: Blackwell Publishing Ltd
– name: Blackwell Publishing
– name: Blackwell
References Black, R.A. & Bliss, L.C. (1980) Reproductive ecology of Picea mariana (Mill.) BSP at tree line near Inuvik, Northwest Territories, Canada. Ecological Monographs, 50, 331-354.
Svensson, J.S. & Jeglum, J.K. (2001) Structure and dynamics of an undisturbed old-growth Norway spruce forest on the rising Bothnian coastline. Forest Ecology and Management, 151, 67-79.
Szeicz, J.M. & MacDonald, G.M. (1994) Age dependent tree-ring growth responses of subarctic white spruce to climate. Canandian Journal of Forest Research, 24, 20-132.
Bradley, R.S. & Jones, P.D. (1993) 'Little Ice Age' summer temperature variations: their nature and relevance to recent global warming trends. The Holocene, 3, 367-376.
Kullman, L. (1996) Rise and demise of cold-climate Picea abies forest in Sweden. New Phytologist, 134, 243-256.
Kullman, L. (1991) Structural change in a subalpine birth woodland in north Sweden during the past century. Journal of Biogeography, 18, 53-62.
Johnson, E.A. & Fryer, G.I. (1989) Population dynamics in lodgepole pine-Engelmann spruce forests. Ecology, 70, 1335-1345.
Lloyd, A.H. & Graumlich, L.J. (1997) Holocene dynamics of treeline forests in the Sierra Nevada. Ecology, 78, 1199-1210.
Cullen, L.E., Palmer, J.G., Duncan, R.P. & Stewart, G.H. (2001) Climate change and tree-ring relationships of Nothofagus menziesii tree-line forests. Canadian Journal of Forest Research, 31, 1981-1991.
Kullman, L. (1987b) Long-term dynamics of high-altitude populations of Pinus sylvestris in the Swedish Scandes. Journal of Biogeography, 14, 1-8.
Kullman, L. (1990) Dynamics of altitudinal tree-limit in Sweden: a review. Norsk Geologisk Tidsskrift, 44, 104-116.
Bradley, R.S. & Jones, P.D. (1992) Climate since A.D. 1500. Routledge, London.
Fritts, H.C. (1974) Relationships of ring widths in arid-site conifers to variations in monthly temperature and precipitation. Ecological Monographs, 44, 411-440.
Yadav, R.R. & Singh, J. (2002) Tree-ring-based spring temperature patterns over the past four centuries in western Himalaya. Quaternary Research, 57, 299-305.
Stewart, G.H. (1986) Population dynamics of a montane conifer forest, western Cascade Range, Oregon, USA. Ecology, 67, 534-544.
Brubaker, L.B. (1986) Responses of tree populations to climatic change. Vegetatio, 67, 119-130.
Houghton, J.T., Meira Filho, L.G., Callander, B.A., Harris, N., Kattenberg, A. & Maskell, K. (1996) Climate change 1995: the science of climate change. Cambridge University Press, Cambridge.
Bradshaw, R.H.W. (1993) Tree species dynamics and disturbance in three Swedish boreal forest stands during the last two thousands year. Journal of Vegetation Science, 4, 759-764.
Scott, P.A., Hansell, R.I.C. & Erickson, W.R. (1993) Influences of wind and snow on northern tree-line environments at Churchill, Manitoba, Canada. Arctic, 46, 316-323.
Daniels, L.D. & Veblen, T.T. (2004) Spatiotemporal influences of climate on altitudinal treeline in northern Patagonia. Ecology, 85, 1284-1296.
Szeicz, J.M. & MacDonald, G.M. (1995) Recent white spruce dynamics at the subarctic alpline treeline of north-western Canada. Journal of Ecology, 83, 873-885.
Kozlowski, T.T., Kramer, P.J. & Pallardy, S.G. (1991) The physiological ecology of woody plants. Academic Press, San Diego, CA.
Tardif, J. & Conciatori, F. (2001) Comparative analysis of the climatic response of seven boreal tree species from northwestern Quebec, Canada. Tree-Ring Research, 57, 169-181.
Payette, S. & Lavoie, C. (1994) Recent fluctuations of the lichen-spruce forest limit in subarctic Quebec. Journal of Ecology, 82, 725-734.
Rochefort, R.M., Little, R.L., Woodward, A. & Peterson, D.L. (1994) Changes in sub-alpine tree distribution in western North America: a review of climatic and other causal factors. Holocene, 4, 89-100.
Kullman, L. (1993) Tree limit dynamics of Betula pubescens ssp. tortuosa in relation to climate change variability: evidence from central Sweden. Journal of Vegetation Science, 4, 765-772.
Bluemle, J.P. (1999) Global warming: a geological perspective. NDGS Newsletter, 26, 1-3.
Harcombe, P.A. (1987) Tree life table. Bioscience, 37, 557-568.
Shiyatov, S.G. (1993) The upper timberline dynamics during the last 1100 years in the polar Ural Mountains. Palaeoclimate Research, 9, 195-203.
Yuan, Y.J. & Li, J.F. (1999) Reconstruction and analysis of 450 years winter temperature series in the Ûrûmqi river source of Tianshan Mountains. Journal of Glaciology and Geocryology, 21, 64-70.
D'Arrigo, R.D., Schuster, W.S.F., Lawrence, D.M., Cook, E.D. & Wiljanen, M. (2001) Climate-growth relationships of eastern hemlock and chestnut oak from Black Rock Forest in the highlands of southeastern New York. Tree-Ring Research, 57, 183-190.
Kullman, L. (1987a) Little Ice Age decline of a cold marginal Pinus sylvestris forest in the Swedish Scandes. New Phytologist, 106, 567-584.
Tranqullini, W. (1979) Physiological ecology of the alpine timberline. Spinger-Verlag, Berlin.
Fritts, H.C. (1976) Tree rings and climate. Academic Press, New York.
Cook, E.R. & Kairiukstis, L.A. (1990) Methods of dendrochronology, applications in the environmental sciences. Kluwer Academic Publishers, Dordrecht, The Netherlands.
Camarero, J.J. & Gutiérrez, E. (2004) Pace and pattern of recent treeline dynamics: response of ecotones to climatic variability in the Spanish Pyrenees. Climatic Change, 63, 181-200.
Holmes, R.L. (1983) A computer-based quality control program. Tree Ring Bulletin, 43, 69-78.
Wang, T., Liang, Y., Ren, H.B., Yu, D., Ni, J. & Ma, K.P. (2004) Age structure of Picea schrenkiana forest along an altitudinal gradient in the central Tianshan Mountains, northwestern China. Forest Ecology and Management, 196, 267-274.
Abrams, M.D., Ruffner, C.M. & DeMeo, T.E. (1998) Dendroecology and species co-existence in an old-growth Quercus-Acer-Tilia talus slope forest in the central Appalachians, USA. Forest Ecology and Management, 106, 9-18.
Payette, S. & Filion, L. (1985) White spruce expansion at the tree line and recent climatic change. Canadian Journal of Forest Research, 15, 241-251.
Oberhuber, W., Stumböck, M. & Kofler, W. (1998) Climate-tree-growth relationships of Scots pine stands (Pinus sylvestris L.) exposed to soil dryness. Trees - Structure and Function, 13, 19-27.
Kullman, L. (1986) Recent tree-limit history of Picea abies in the southern Swedish Scandes. Canadian Journal of Forest Research, 16, 761-771.
Camarero, J.J. & Gutiérrez, E. (1999) Structure and recent recruitment at alpine forest-pasture ecotones in the Spanish central Pyrenees. Ecoscience, 6, 451-464.
Rolland, C. (1993) Tree-ring and climate relationships for Abies alba in the internal Alps. Tree-Ring Bulletin, 53, 1-11.
Ruffner, C.M. & Abrams, M.D. (1998) Relating land-use history and climate to the dendroecology of a 326-year-old Quercus prinus talus slope forest. Canadian Journal of Forest Research, 28, 347-358.
Kullman, L. (1983) Short-term dynamics of high altitude populations of Pinus sylvestris in the Swedish Scades. New Phytologist, 106, 567-584.
Kullman, L. (1998) Tree-limits and montane forests in the Swedish Scandes: sensitive biomonitors of climate change and variability. Ambio, 27, 312-321.
Weisberg, P.J. & Baker, W.L. (1995) Spatial variation in tree regeneration in the forest-tundra ecotone, Rocky Mountain National Park, Colorado. Canadian Journal of Forest Research, 25, 1326-1339.
Yuan, Y.J., Li, J.F., Hu, R.J., Liu, C.H., Jiao, K.Q. & Li, Z.Q. (2001) Reconstruction of precipitation in the recent 350 years from tree-rings in the middle Tianshan Mountains. Journal of Glaciology and Geocryology, 23, 34-40.
Briffa, K.R., Jones, P.D., Schweingruber, F.H., Shiyatov, S.G. & Cook, E.R. (1995) Unusual twentieth-century summer warmth in a 1000-year temperature record from Siberia. Nature, 376, 156-159.
Hadley, J.L. & Smith, W.K. (1987) Influence of krummholz mat microclimatic on needle physiology and survival. Oecologia, 73, 82-90.
Fritts, H.C. (1998) Quick help for preconk, version 5.17. Dendrochronological Modelling, Tucson, Arizona.
Moiseev, P. (2002) Effect of climatic changes on radial increment and age structure formation in high-mountain larch forests of the Kuznetsk Ala Tau. Russian Journal of Ecology, 33, 7-13[translated from Ekologiya, 2002 (1), 10-17].
Yan, S., Kong, Z., Yang, Z., Ni, J. & Li, S. (2003) Fluctuation of timberline and environment change near the Northern Piedmonts of Tianshan Mts during the last 2000 years. Scientia Geographica Sinica, 23, 699-704.
Villalba, R., Boninsegna, J.A., Veblen, T.T., Schmelter, A. & Rubulis, S. (1997) Recent trends in tree-ring records from high elevation sites in the Andes of northern Patagonia. Climatic Change, 36, 425-454.
2004; 63
1991; 18
1993; 9
1987; 73
2002; 57
1976
1994; 24
1995; 376
1993; 3
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1983; 106
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1974; 44
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1989; 70
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1996; 134
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2004; 85
1993; 46
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1999; 26
2002; 33
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1987a; 106
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2001; 151
1980; 50
1986; 67
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Shiyatov S.G. (e_1_2_7_45_1) 1993; 9
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Bradley R.S. (e_1_2_7_5_1) 1992
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References_xml – reference: Rolland, C. (1993) Tree-ring and climate relationships for Abies alba in the internal Alps. Tree-Ring Bulletin, 53, 1-11.
– reference: Oberhuber, W., Stumböck, M. & Kofler, W. (1998) Climate-tree-growth relationships of Scots pine stands (Pinus sylvestris L.) exposed to soil dryness. Trees - Structure and Function, 13, 19-27.
– reference: Tranqullini, W. (1979) Physiological ecology of the alpine timberline. Spinger-Verlag, Berlin.
– reference: Bluemle, J.P. (1999) Global warming: a geological perspective. NDGS Newsletter, 26, 1-3.
– reference: Fritts, H.C. (1998) Quick help for preconk, version 5.17. Dendrochronological Modelling, Tucson, Arizona.
– reference: Shiyatov, S.G. (1993) The upper timberline dynamics during the last 1100 years in the polar Ural Mountains. Palaeoclimate Research, 9, 195-203.
– reference: Camarero, J.J. & Gutiérrez, E. (2004) Pace and pattern of recent treeline dynamics: response of ecotones to climatic variability in the Spanish Pyrenees. Climatic Change, 63, 181-200.
– reference: Kullman, L. (1983) Short-term dynamics of high altitude populations of Pinus sylvestris in the Swedish Scades. New Phytologist, 106, 567-584.
– reference: Moiseev, P. (2002) Effect of climatic changes on radial increment and age structure formation in high-mountain larch forests of the Kuznetsk Ala Tau. Russian Journal of Ecology, 33, 7-13[translated from Ekologiya, 2002 (1), 10-17].
– reference: D'Arrigo, R.D., Schuster, W.S.F., Lawrence, D.M., Cook, E.D. & Wiljanen, M. (2001) Climate-growth relationships of eastern hemlock and chestnut oak from Black Rock Forest in the highlands of southeastern New York. Tree-Ring Research, 57, 183-190.
– reference: Black, R.A. & Bliss, L.C. (1980) Reproductive ecology of Picea mariana (Mill.) BSP at tree line near Inuvik, Northwest Territories, Canada. Ecological Monographs, 50, 331-354.
– reference: Briffa, K.R., Jones, P.D., Schweingruber, F.H., Shiyatov, S.G. & Cook, E.R. (1995) Unusual twentieth-century summer warmth in a 1000-year temperature record from Siberia. Nature, 376, 156-159.
– reference: Weisberg, P.J. & Baker, W.L. (1995) Spatial variation in tree regeneration in the forest-tundra ecotone, Rocky Mountain National Park, Colorado. Canadian Journal of Forest Research, 25, 1326-1339.
– reference: Bradley, R.S. & Jones, P.D. (1992) Climate since A.D. 1500. Routledge, London.
– reference: Stewart, G.H. (1986) Population dynamics of a montane conifer forest, western Cascade Range, Oregon, USA. Ecology, 67, 534-544.
– reference: Payette, S. & Lavoie, C. (1994) Recent fluctuations of the lichen-spruce forest limit in subarctic Quebec. Journal of Ecology, 82, 725-734.
– reference: Kullman, L. (1996) Rise and demise of cold-climate Picea abies forest in Sweden. New Phytologist, 134, 243-256.
– reference: Wang, T., Liang, Y., Ren, H.B., Yu, D., Ni, J. & Ma, K.P. (2004) Age structure of Picea schrenkiana forest along an altitudinal gradient in the central Tianshan Mountains, northwestern China. Forest Ecology and Management, 196, 267-274.
– reference: Johnson, E.A. & Fryer, G.I. (1989) Population dynamics in lodgepole pine-Engelmann spruce forests. Ecology, 70, 1335-1345.
– reference: Hadley, J.L. & Smith, W.K. (1987) Influence of krummholz mat microclimatic on needle physiology and survival. Oecologia, 73, 82-90.
– reference: Kozlowski, T.T., Kramer, P.J. & Pallardy, S.G. (1991) The physiological ecology of woody plants. Academic Press, San Diego, CA.
– reference: Yan, S., Kong, Z., Yang, Z., Ni, J. & Li, S. (2003) Fluctuation of timberline and environment change near the Northern Piedmonts of Tianshan Mts during the last 2000 years. Scientia Geographica Sinica, 23, 699-704.
– reference: Harcombe, P.A. (1987) Tree life table. Bioscience, 37, 557-568.
– reference: Houghton, J.T., Meira Filho, L.G., Callander, B.A., Harris, N., Kattenberg, A. & Maskell, K. (1996) Climate change 1995: the science of climate change. Cambridge University Press, Cambridge.
– reference: Fritts, H.C. (1976) Tree rings and climate. Academic Press, New York.
– reference: Kullman, L. (1987a) Little Ice Age decline of a cold marginal Pinus sylvestris forest in the Swedish Scandes. New Phytologist, 106, 567-584.
– reference: Kullman, L. (1986) Recent tree-limit history of Picea abies in the southern Swedish Scandes. Canadian Journal of Forest Research, 16, 761-771.
– reference: Kullman, L. (1991) Structural change in a subalpine birth woodland in north Sweden during the past century. Journal of Biogeography, 18, 53-62.
– reference: Kullman, L. (1987b) Long-term dynamics of high-altitude populations of Pinus sylvestris in the Swedish Scandes. Journal of Biogeography, 14, 1-8.
– reference: Szeicz, J.M. & MacDonald, G.M. (1994) Age dependent tree-ring growth responses of subarctic white spruce to climate. Canandian Journal of Forest Research, 24, 20-132.
– reference: Fritts, H.C. (1974) Relationships of ring widths in arid-site conifers to variations in monthly temperature and precipitation. Ecological Monographs, 44, 411-440.
– reference: Yuan, Y.J., Li, J.F., Hu, R.J., Liu, C.H., Jiao, K.Q. & Li, Z.Q. (2001) Reconstruction of precipitation in the recent 350 years from tree-rings in the middle Tianshan Mountains. Journal of Glaciology and Geocryology, 23, 34-40.
– reference: Holmes, R.L. (1983) A computer-based quality control program. Tree Ring Bulletin, 43, 69-78.
– reference: Cullen, L.E., Palmer, J.G., Duncan, R.P. & Stewart, G.H. (2001) Climate change and tree-ring relationships of Nothofagus menziesii tree-line forests. Canadian Journal of Forest Research, 31, 1981-1991.
– reference: Abrams, M.D., Ruffner, C.M. & DeMeo, T.E. (1998) Dendroecology and species co-existence in an old-growth Quercus-Acer-Tilia talus slope forest in the central Appalachians, USA. Forest Ecology and Management, 106, 9-18.
– reference: Rochefort, R.M., Little, R.L., Woodward, A. & Peterson, D.L. (1994) Changes in sub-alpine tree distribution in western North America: a review of climatic and other causal factors. Holocene, 4, 89-100.
– reference: Yadav, R.R. & Singh, J. (2002) Tree-ring-based spring temperature patterns over the past four centuries in western Himalaya. Quaternary Research, 57, 299-305.
– reference: Bradshaw, R.H.W. (1993) Tree species dynamics and disturbance in three Swedish boreal forest stands during the last two thousands year. Journal of Vegetation Science, 4, 759-764.
– reference: Szeicz, J.M. & MacDonald, G.M. (1995) Recent white spruce dynamics at the subarctic alpline treeline of north-western Canada. Journal of Ecology, 83, 873-885.
– reference: Kullman, L. (1990) Dynamics of altitudinal tree-limit in Sweden: a review. Norsk Geologisk Tidsskrift, 44, 104-116.
– reference: Tardif, J. & Conciatori, F. (2001) Comparative analysis of the climatic response of seven boreal tree species from northwestern Quebec, Canada. Tree-Ring Research, 57, 169-181.
– reference: Kullman, L. (1998) Tree-limits and montane forests in the Swedish Scandes: sensitive biomonitors of climate change and variability. Ambio, 27, 312-321.
– reference: Kullman, L. (1993) Tree limit dynamics of Betula pubescens ssp. tortuosa in relation to climate change variability: evidence from central Sweden. Journal of Vegetation Science, 4, 765-772.
– reference: Payette, S. & Filion, L. (1985) White spruce expansion at the tree line and recent climatic change. Canadian Journal of Forest Research, 15, 241-251.
– reference: Villalba, R., Boninsegna, J.A., Veblen, T.T., Schmelter, A. & Rubulis, S. (1997) Recent trends in tree-ring records from high elevation sites in the Andes of northern Patagonia. Climatic Change, 36, 425-454.
– reference: Lloyd, A.H. & Graumlich, L.J. (1997) Holocene dynamics of treeline forests in the Sierra Nevada. Ecology, 78, 1199-1210.
– reference: Yuan, Y.J. & Li, J.F. (1999) Reconstruction and analysis of 450 years winter temperature series in the Ûrûmqi river source of Tianshan Mountains. Journal of Glaciology and Geocryology, 21, 64-70.
– reference: Camarero, J.J. & Gutiérrez, E. (1999) Structure and recent recruitment at alpine forest-pasture ecotones in the Spanish central Pyrenees. Ecoscience, 6, 451-464.
– reference: Brubaker, L.B. (1986) Responses of tree populations to climatic change. Vegetatio, 67, 119-130.
– reference: Daniels, L.D. & Veblen, T.T. (2004) Spatiotemporal influences of climate on altitudinal treeline in northern Patagonia. Ecology, 85, 1284-1296.
– reference: Svensson, J.S. & Jeglum, J.K. (2001) Structure and dynamics of an undisturbed old-growth Norway spruce forest on the rising Bothnian coastline. Forest Ecology and Management, 151, 67-79.
– reference: Scott, P.A., Hansell, R.I.C. & Erickson, W.R. (1993) Influences of wind and snow on northern tree-line environments at Churchill, Manitoba, Canada. Arctic, 46, 316-323.
– reference: Bradley, R.S. & Jones, P.D. (1993) 'Little Ice Age' summer temperature variations: their nature and relevance to recent global warming trends. The Holocene, 3, 367-376.
– reference: Ruffner, C.M. & Abrams, M.D. (1998) Relating land-use history and climate to the dendroecology of a 326-year-old Quercus prinus talus slope forest. Canadian Journal of Forest Research, 28, 347-358.
– reference: Cook, E.R. & Kairiukstis, L.A. (1990) Methods of dendrochronology, applications in the environmental sciences. Kluwer Academic Publishers, Dordrecht, The Netherlands.
– year: 1985
– volume: 151
  start-page: 67
  year: 2001
  end-page: 79
  article-title: Structure and dynamics of an undisturbed old‐growth Norway spruce forest on the rising Bothnian coastline
  publication-title: Forest Ecology and Management
– volume: 106
  start-page: 9
  year: 1998
  end-page: 18
  article-title: Dendroecology and species co‐existence in an old‐growth – talus slope forest in the central Appalachians, USA
  publication-title: Forest Ecology and Management
– volume: 46
  start-page: 316
  year: 1993
  end-page: 323
  article-title: Influences of wind and snow on northern tree‐line environments at Churchill, Manitoba, Canada
  publication-title: Arctic
– volume: 376
  start-page: 156
  year: 1995
  end-page: 159
  article-title: Unusual twentieth‐century summer warmth in a 1000‐year temperature record from Siberia
  publication-title: Nature
– volume: 36
  start-page: 425
  year: 1997
  end-page: 454
  article-title: Recent trends in tree‐ring records from high elevation sites in the Andes of northern Patagonia
  publication-title: Climatic Change
– volume: 106
  start-page: 567
  year: 1987a
  end-page: 584
  article-title: Little Ice Age decline of a cold marginal forest in the Swedish Scandes
  publication-title: New Phytologist
– volume: 4
  start-page: 765
  year: 1993
  end-page: 772
  article-title: Tree limit dynamics of ssp. in relation to climate change variability: evidence from central Sweden
  publication-title: Journal of Vegetation Science
– volume: 37
  start-page: 557
  year: 1987
  end-page: 568
  article-title: Tree life table
  publication-title: Bioscience
– volume: 70
  start-page: 1335
  year: 1989
  end-page: 1345
  article-title: Population dynamics in lodgepole pine–Engelmann spruce forests
  publication-title: Ecology
– volume: 53
  start-page: 1
  year: 1993
  end-page: 11
  article-title: Tree‐ring and climate relationships for in the internal Alps
  publication-title: Tree-Ring Bulletin
– volume: 67
  start-page: 119
  year: 1986
  end-page: 130
  article-title: Responses of tree populations to climatic change
  publication-title: Vegetatio
– year: 1979
– volume: 50
  start-page: 331
  year: 1980
  end-page: 354
  article-title: Reproductive ecology of (Mill.) BSP at tree line near Inuvik, Northwest Territories, Canada
  publication-title: Ecological Monographs
– year: 1990
– year: 1998
– volume: 28
  start-page: 347
  year: 1998
  end-page: 358
  article-title: Relating land‐use history and climate to the dendroecology of a 326‐year‐old talus slope forest
  publication-title: Canadian Journal of Forest Research
– volume: 25
  start-page: 1326
  year: 1995
  end-page: 1339
  article-title: Spatial variation in tree regeneration in the forest‐tundra ecotone, Rocky Mountain National Park, Colorado
  publication-title: Canadian Journal of Forest Research
– volume: 24
  start-page: 20
  year: 1994
  end-page: 132
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Snippet Aim: Climate variability may be an important mediating agent of ecosystem dynamics in cold, arid regions such as the central Tianshan Mountains, north-western...
ABSTRACT Aim  Climate variability may be an important mediating agent of ecosystem dynamics in cold, arid regions such as the central Tianshan Mountains,...
Aim  Climate variability may be an important mediating agent of ecosystem dynamics in cold, arid regions such as the central Tianshan Mountains, north‐western...
SourceID pascalfrancis
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wiley
jstor
istex
SourceType Index Database
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Publisher
StartPage 406
SubjectTerms Age structure
Animal and plant ecology
Animal, plant and microbial ecology
Biological and medical sciences
Climate change
Climate models
climatic fluctuation
Dendroclimatology
Forest ecology
Fundamental and applied biological sciences. Psychology
General aspects
Growth rings
Picea schrenkiana
radial growth
Summer
Synecology
Timberlines
Tree growth
tree rings
treeline dynamics
Trees
Title Treeline dynamics in relation to climatic variability in the central Tianshan Mountains, northwestern China
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https://www.jstor.org/stable/3697543
https://onlinelibrary.wiley.com/doi/abs/10.1111%2Fj.1466-822X.2006.00233.x
Volume 15
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