祁连山东部青杄年内径向生长动态对气候的响应

树木径向生长对气候因子的响应是树轮气候学的基础。在我国西北地区,虽然已有大量的树轮-气候响应研究,但是响应分析多基于数理统计结果,缺乏对树木生长过程的理解。基于此,于2013年到2015年在祁连山东部吐鲁沟国家森林公园内通过Dendrometer连续监测了树轮气候重建中常用树种青杄的径向生长,通过平均值法提取2013到2015年生长季内不同时间尺度(1天、7天、10天)的平均径向生长量及对应时间段的平均气候状况。不同时间尺度径向生长量和气候因子的相关分析结果表明,时间尺度的延长削弱了树干水分昼夜变化的干扰,但水分仍然是青杄径向生长的限制因子。为了进一步分析青杄径向生长与气候关系随时间的变化情况,以31天为窗口将日径向生长量与气候要素每隔一天进行滑动相关,结果显示:5、7月青杄的径向生长与降水的关系稳定,都呈显著正相关,但是6月降水的年际变率较大,导致树木可利用水分的变幅也较大,因而树木径向生长与6月水分的响应关系不稳定,存在较大的年际差异,而这可能是一些树轮-气候响应研究中轮宽与6月降水关系不显著的原因。     

祁连山不同植被类型的物候变化及其对气候的响应

基于1982—2006年GIMMS NDVI和2000—2014年MODIS NDVI遥感数据,利用double logistic拟合方法提取了1982—2014年祁连山区不同植被的生长季始期、生长季末期和生长季长度3个重要的物候参数,分析了不同植被物候期的时间变化趋势、空间分异特征及对气候因子的响应。结果表明:(1)祁连山区不同植被的生长季始期和生长季末期随年际变化表现出波动提前或推迟,其中沼泽植被的变化波动最大;草甸植被、灌丛植被、阔叶林植被和栽培植被生长季长度出现延长趋势;(2)祁连山区植被生长季始期集中在5月初,其中阔叶林植被生长季开始最早,荒漠植被生长季开始最晚,植被生长季末期集中在9月,栽培植被生长季结束较早,荒漠植被、沼泽植被生长季结束较晚,植被生长季长度集中在110—140 d,其中阔叶林植被、针叶林植被生长季长度较长,而荒漠植被、高山植被生长季长度较短;(3)祁连山植被物候期变化趋势的空间分布表明植被生长季始期、生长季末期主要表现为提前不明显和推迟不明显,生长季长度主要表现为缩短不明显和延长不明显;(4)物候要素与气候要素相关性表明前期温度的积累有利于植被的开始生长,但当年3月的降水量对植被生长季始期同样有重要作用,不同植被生长季末期与8月、9月温度相关性较大,而与10月、11月降水的相关性较大。     

秦岭山地针叶树种树木生长对气候变化的响应

秦岭作为我国重要的地理分界线,其亚高山针叶林生态系统在区域乃至更大尺度范围的水源涵养、生物多样性维护、气候调节等方面具有重要价值。近几十年,秦岭地区大幅升温且存在空间异质性。研究秦岭针叶林带树木生长对气候变化的响应规律对于气候变化下山地森林保护与管理具有重要价值。本文综述了秦岭西部、中部和东部不同海拔针叶树种树木生长与气候的响应关系,从树木径向生长、NDVI、物候和物种分布范围等方面探讨了气候变化对针叶树种的影响,并对树木生长响应气候变化研究中可能存在的问题和研究前景进行了展望。     

祁连山气候变化特征及其对水资源的影响

祁连山作为我国重要的生态功能区、西北地区重要的生态安全屏障和河流产流区,是气候变化敏感区和生态环境脆弱区,其生态环境对西北地区经济发展起着重要作用。本研究利用祁连山区气温和降水观测数据、MOD10A2积雪产品以及石羊河、黑河和疏勒河流量资料,系统分析了1961—2020年祁连山区的气候变化特征,以及在气候变暖背景下,气候变化对祁连山区水资源的影响。结果表明: 1961—2020年,祁连山区平均气温呈显著上升趋势,升温速率达0.39 ℃·(10 a)^-1,西段升温速率最大,中、东段次之,冬季升温趋势最显著,春季最小;祁连山区平均气温在1997年发生突变。祁连山区年降水量总体呈波动增加趋势[10 mm·(10 a)^-1],中段增加最明显,2004年以来祁连山区处于多雨时期,气候呈暖湿化趋势;四季降水量均呈增加趋势,夏季降水增加对年降水贡献最大;年降水以年际尺度变化为主,2.8年的年际尺度贡献率高达64.3%。祁连山积雪面积受气温和降雪影响明显,与夏季气温存在负相关,与降雪量存在正相关;2016—2020年,祁连山增温趋缓、降雪增多,积雪面积呈增加趋势。2000年以来,祁连山升温加剧,降水增多,冰雪融水增加,石羊河、黑河和疏勒河出山径流均呈增加趋势。研究结果对祁连山区生态文明建设和应对气候变化具有重要意义。     

Growth and response patterns of Picea crassifolia and Pinus tabuliformis to climate factors in the Qilian Mountains,northwest China

Different tree species exhibit different phenological and physiological characteristics, leading to complexity in inter-species comparison of stem radial growth response to climate change. This study explored the climate-growth responses of Qinghai spruce (Picea crassifolia) and Chinese pine (Pinus tabulaeformis) in the Qilian Mountains, Northwest China. Meanwhile, Vaganov-Shashkin model (VS-oscilloscope) was used to simulate the relationships between radial growth rates and phenology. The results showed that 1) in their radial growth patterns, Qinghai spruce showed a significant increasing trend, while Chinese pine showed a decreasing trend, and Qinghai spruce has a longer growing season than Chinese pine. 2) For the radial growth-climate dynamic response, Qinghai spruce was influenced in an unstable manner by the mean temperature in the mid-growing season of the current year and the late growing season of the previous year and by the mean minimum temperature in the mid-growing season of the current year, while Chinese pine was influenced in a stable manner by the mean temperature and mean maximum temperature during the growing season of the current year. 3) The radial growth rates of the two conifer species were limited by temperature at the initiation and cessation of growth and by soil moisture at the peak of growth. But Chinese pine was more severely affected by soil moisture than Qinghai spruce in the middle of growth. Therefore, different management and restoration measures should be taken based on the differences in ecological responses and physical and physiological properties of the two conifer species to climate change in the subalpine forest ecosystems in the semiarid and arid regions of Northwest China.     

基于祁连山树轮宽度指数的区域NDVI重建

利用祁连山自东向西5条树轮宽度年表序列和1986-2003年间的归一化植被指数(NDVI), 分析了NDVI的时空变化及其与树轮宽度年表之间的关联。结果表明, 祁连山地区植被的生长主要集中在6-8月。空间上, NDVI值从祁连山东段向西段逐渐减小; 在1986-2003时段内, 东、中和西段生长季的NDVI值分别增长了3.28%、4.82%和7.75%。整个祁连山地区的NDVI变化与5个宽度年表的第一主成分相关性较高(r = 0.74, p < 0.01)。基于此, 利用树轮宽度RES年表的第一主成分重建了1843-2003年间祁连山地区生长季的NDVI变化曲线。重建的NDVI曲线表现出6个高值期和6个低值期, 其中1923-1932的10年间植被生长状况最差。另外, 在1989-2003时段内NDVI年际波动较大, 总体上表现为NDVI低于平均值, 但是从1991年开始, NDVI有上升的趋势。     

Responses to climate change in radial growth of Picea schrenkiana along elevations of the eastern Tianshan Mountains,northwest China

Tree growth is largely driven by climate conditions in arid and alpine areas. A strong change in climate from warm-dry to warm-wet has already been observed in northwest China. However, little is known about the impacts of regional climate variability on the radial growth of trees along elevations of the eastern Tianshan Mountains. Consequently, we developed three tree-ring width chronologies of Schrenk spruce (Picea schrenkiana Fisch. et Mey.) ranging in elevation from 2159 to 2552 m above sea level (a.s.l.), which play an important role in the forestry ecosystem, agriculture, and local economy of Central Asia. In our study, the correlation analyses of growth-drought using the monthly standardized precipitation-evapotranspiration index (SPEI) at different temporal scales demonstrated that drought in growing season was the main factor limiting tree growth, regardless of elevation. The relationships between radial growth of Schrenk spruce and main climate factors were relatively stable by moving correlation function, and the trend of STD chronologies and basal area increment (BAI) also showed a synchronous decline across the three elevations in recent decades. And meanwhile, slight differences in responses to climate change in radial growth along elevations were examined. The drought stress increased as elevations decreased. Radial growth at the higher elevation depended on moisture availability due to high temperature, as indicated by the significant negative correlation with mean temperature in the late growing season of the previous year (August-September, p < 0.001). However, radial growth at the lower elevation were restricted by drought stress due to less precipitation and higher temperatures, as demonstrated by the significant negative correlation with mean temperature but positive with total precipitation in the early growing season of the current year (April-May, p < 0.05). In addition, the decline of radial growth (BAI) at the higher elevation (3.710 cm² yr⁻¹/decade, p < 0.001) was faster than that of the middle elevation (2.344 cm² yr⁻¹/decade, p < 0.001) and the lower elevation (3.005 cm² yr⁻¹/decade, p < 0.001) since 2000, indicating that the trees at higher elevation of a relatively humid environment were more susceptible to the effects of climate change due to their poor adaptability to water deficit. Therefore, the forest ecosystems would be suppressed as a result of increasing drought stress in the future, especially in the high-elevation forests of arid and semi-arid areas.     

采自祁连山的冷杉侧耳生物学特性及栽培条件探索

以采自甘肃省祁连山国家级自然保护区菌物保育区的野生侧耳作为试验材料,通过形态学及系统发育分析方法将其鉴定为冷杉侧耳Pleurotus abieticola。对该菌株生物学特性及栽培条件进行初步研究,结果表明：菌丝体最适生长温度为25℃;最适pH为7.0;最适碳源为玉米粉;最适氮源为豆粉;在以棉籽壳、木屑和麸皮为栽培料时,可获得子实体。     

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 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.     

Individual and time-varying tree-ring growth to climate sensitivity of Pinus tabuliformis Carr. and Sabina przewalskii Kom. in the eastern Qilian Mountains, China

Individual tree-ring width chronologies and mean chronologies from Pinus tabuliformis Carr. (Chinese pine) and Sabina przewalskii Kom. (Qilian juniper) tree cores were collected and analyzed from two sites in the eastern Qilian Mountains of China. The chronologies were used to analyze individual and time-varying tree-ring growth to climate sensitivity with monthly mean air temperature and total precipitation data for the period 1958–2008. Climate–growth relationships were assessed with correlation functions and their stationarity and consistency over time were measured using moving correlation analysis. Individuals’ growth–climate correlations suggested increased percentages of individuals are correlated with certain variables (e.g., current June temperature at the P. tabuliformis site; previous June, December and current May temperature and May precipitation at the S. przewalskii site). These same climatic variables also correspond to the mean chronology correlations. A decreased percentage of individuals correlated with these climatic variables indicates a reduced sensitivity of the mean chronology. Moving correlation analysis indicated a significant change over time in the sensitivity of trees to climatic variability. Our results suggested: (1) that individual tree analysis might be a worthwhile tool to improve the quality and reliability of the climate signal from tree-ring series for dendroclimatology research; and (2) time-dependent fluctuations of climate growth relationships should be taken into account when assessing the quality and reliability of reconstructed climate signals.     

Application of Picea wilsonii roots to determine erosion rates in eastern Qilian Mountains, Northwest China

As a consequence of global change and human activities, processes of soil erosion are expected to increase in forested areas, resulting in exposed roots. Dendrogeomorphic research was conducted by analyzing exposed roots of Picea wilsonii subjected to continuous denudation along a main road in Tulugou National Forest Reserve, eastern Qilian Mountains, to reconstruct the local soil erosion dynamics. We determined the start of the exposure by examining the shifts in the ring-growth patterns from concentric to eccentric and by analyzing the detailed changes of wood anatomical features of exposed roots. We also find that the width of growth ring, the percentage of latewood and the average cell size of earlywood tracheids are all remarkable signs for soil lowering. According to the analysis of ANOVA (Fisher’s least significant difference method), the reduction of the cell size of earlywood tracheids is verified to be the key indicator for dating the first year of exposure and occurs prior to the other two indicators. Using 40 roots from 23 trees spread along the road, it has been found that erosion rates vary between 3.3 and 13.5 mm/year with an average value about 5.3 ± 2.1 mm/year. The intensity and occurrence of soil erosion may be influenced by the increase of human activities.     

Forward modeling analyses of Qilian Juniper <Emphasis Type="Italic">(Sabina przewalskii)</Emphasis> growth in response to climate factors in different regions of the Qilian Mountains,northwestern China

Key message

The process-based Vaganov–Shashkin model simulations accurately represent the nonlinear process of Qilian Juniper growth–climate relationship over different regions of the Qilian Mountains.

Abstract

The Qilian Mountains (QM), northeastern edge of the Tibetan Plateau (TP), is one of the most studied areas in China for tree-ring research; considerable dendroclimatic reconstructions have been carried out and a series of important achievements made over this region. However, most reconstructions were primarily based on empirical relationships between tree growth and climate factors identified through statistical analysis. Reliable information on the physiological processes of tree responses to climate change in different regions is still scarce. Here, the process-based Vaganov–Shashkin (VS) model was used to simulate regional patterns of climate–tree growth relationships using observed temperature and precipitation over the different regions of the QM. Results showed that the sequences of simulated growth curves were broadly consistent with the actual tree-ring chronologies in all three regions of the QM. VS model simulations accurately represented the effect of climatic controls on the growth of Qilian Juniper (Sabina przewalskii). VS model outputs closely corresponded to statistical relationships between tree-ring width and climate factors as well as observational physiological behavior; i.e., available water in May and June had the largest contribution to ring formation in Qilian Juniper over the QM. The simulated and actual data analyses revealed that the radial growth of trees in the western QM was more sensitive to moisture conditions in May and June, compared with growth in the central and eastern QM. Tree growth in this region is representative of large areas in northwestern China with drought conditions.

     

升温对祁连山东部青海云杉径向生长的影响

在祁连山东部西营河流域不同海拔采集年轮样品,利用树木年代学方法建立高海拔(3000 m)、中海拔(2750 m)、低海拔(2500 m)青海云杉标准化年表,将年轮宽度指数与不同时段气温和降水分别进行相关分析,研究祁连山东部不同海拔青海云杉径向生长对气候变暖的响应。结果表明: 水热是祁连山东部青海云杉径向生长的主要限制因子,不同海拔树木的生长限制因子基本一致。在显著升温之前(1961—1986年),低、中、高海拔3个样点的青海云杉径向生长均与上一年7—8月和当年8月平均最高温呈显著负相关,与当年6月相对湿度呈显著正相关。显著升温之后(1986—2014年),高、中、低海拔树木生长与气温仍呈显著负相关,而与当年2月的相对湿度由升温前的不显著负相关转为显著正相关,与6月降水和相对湿度由升温前的显著正相关转为不显著的负相关。升温导致祁连山东部各海拔青海云杉树轮生长变慢,其中高海拔所受影响最大。气候变暖导致的干旱胁迫可能是青海云杉径向生长发生变化的主要原因。     

祁连山东部青海云杉死亡和存活个体径向生长对气候变化的响应差异

研究建立了祁连山东部青海云杉(Picea crassifolia)存活个体与死亡个体的树轮宽度年表和断面生长增量(BAI)序列,对青海云杉存活个体与死亡个体的径向生长特征及其对气候要素的响应关系进行了比较,尝试厘清青海云杉径向生长与气候要素之间的响应机制。结果表明:青海云杉死亡个体的径向生长速率明显低于存活个体(P ＜ 0.001),尤其是在20世纪80年代快速升温后,这一差距进一步加大,青海云杉死亡率也大幅增加。在1951-1986年期间,青海云杉径向生长主要受生长季前(上一年9月到当年2月)干湿状况的影响;而在1987-2020年期间,青海云杉径向生长则更多受生长季(当年6-8月)干湿状况的影响。并且与活树相比,死树对区域干湿状况表现出更高的敏感性,对气温的负响应也更强。随着气候变暖加剧,高温及其带来的干旱胁迫已成为区域内限制青海云杉径向生长的主要气候因素,青海云杉的死亡率可能会继续升高。     

Spatial distribution patterns and association of Picea crassifolia population in Dayekou Basin of Qilian Mountains,northwestern China

研究青海云杉(Picea crassifolia)种群不同发育阶段的空间分布格局及其关联性, 能揭示其种群的发展规律, 推断其潜在的生态学过程或影响机制, 进而为该种群的配置、种植和森林的经营与管理等提供指导。该研究基于祁连山大野口流域10.2 hm²青海云杉动态监测样地调查资料, 分析了青海云杉群落的物种组成和径级结构, 并采用点格局方法, 通过单变量成对相关函数和双变量成对相关函数对不同年龄阶段青海云杉种群的空间分布格局及其空间关联性进行分析。结果表明: (1)青海云杉种群的径级结构呈倒“J”型分布, 属增长型种群, 种群自然更新状况良好。(2)青海云杉种群4个径级的个体在小尺度上呈聚集分布, 但随着空间尺度的增大, 聚集强度逐渐减弱, 趋向随机分布; 较小径级的个体常呈聚集分布, 而随着径级增大, 也趋向于随机分布。(3)青海云杉大树个体在小尺度(<4 m)范围内与其他径级个体都呈负关联, 随着尺度的增加, 大树与幼树表现出正关联且关联性随尺度的增加而减弱, 而与小树、中树则表现为无关联或者微弱的负关联; 径级相近的个体空间关联性为正关联或无关联, 随着个体径级间差距增大, 空间关联性转变为无关联或负关联。研究表明, 祁连山大野口流域青海云杉种群的分布格局及其关联性随空间尺度和发育阶段而变化, 这是由种群自身的生物生态学特性、种内种间关系以及环境条件共同作用的结果。     

祁连山中部祁连圆柏年内径向生长对气候因子的响应

通过对祁连山中部葫芦沟流域的祁连圆柏连续采集微树芯,对其形成层活动和径向生长动态进行了连续两年的监测研究。结果表明,2012年细胞壁加厚和细胞成熟阶段开始时间分别发生在6月26日和7月24日,比2013年细胞壁加厚（6月22日）和细胞成熟阶段（6月26日）开始时间分别晚5 d和28 d。2012年细胞扩大、细胞壁加厚和细胞成熟阶段结束时间分别为7月16日、8月9日和9月8日,比2013年各阶段结束时间分别晚7、28 d和24 d。2012年最大细胞分裂速率为0.33细胞/d,共形成20.9个细胞,细胞分裂速率和木质部细胞总数均高于2013年。通过与附近气象站记录的气象数据进行对比,发现祁连圆柏生长开始时间在温暖年份显著早于寒冷年份,说明祁连圆柏的径向生长开始时间与温度有关。但2013年春季和夏初的高温导致区域干旱程度加剧,使祁连圆柏生长结束时间显著早于2012年,并导致2013年的木质部细胞总量和生长速率都小于2012年。研究表明,在寒冷干旱地区,尽管升温会使生长季提前,但升温导致的干旱胁迫可能对树木的生长速率和木质部细胞总量产生重要影响。     

气候变化对祁连山蒙古扁桃潜在适生区的影响

气候变化将改变物种的生存环境,影响其分布范围,甚至威胁到某些物种的生存。本文通过ArcGIS软件和最大熵(MaxEnt)模型模拟蒙古扁桃(Amygdalus mongolica)在祁连山当前(1970—2000年)和未来(2081—2100年)2个气候时期背景下的地理分布格局,并分析其主要的环境影响因素。结果表明：(1)在当前气候条件下,蒙古扁桃在祁连山的东南部有较好的适生性;(2)未来4种气候情景下(SSP126,SSP245,SSP245和SSP585),蒙古扁桃在祁连山南部及东南部的适生区有消失的风险,扩张区主要集中在祁连山中北部的国家公园附近;(3)蒙古扁桃的分布格局主要向祁连山北部和高纬度地区迁移;(4)最湿月降水量(Bio13)、坡度(Slope)、最冷季度均温(Bio11)和最热月最高温(Bio5)的累计贡献率达到了80%以上,是影响蒙古扁桃适生分布的主要因子。本研究模拟、分析、预测了当前和未来不同情景下蒙古扁桃在祁连山的潜在分布及其变化,为祁连山生态及物种多样性的保护提供科学依据。     

祁连山西部青海云杉径向生长对气候因子的响应

利用树木径向生长监测仪(Dendrometer)和自动气象站在祁连山西部对8棵青海云杉的径向生长及环境因子进行了连续监测研究。结果表明: Gompertz函数拟合结果显示,2018—2020年青海云杉的径向生长分别开始于4月19日、4月17日和4月10日,在日平均气温超过5.5 ℃时径向生长开始;青海云杉生长结束时间分别为8月17日、8月21日和7月19日,生长结束时间与生长季末期降水量有关。研究区青海云杉径向生长量受干旱抑制强烈,其中与7月的日均温(负相关)和日降水量(正相关)相关性最高,与生长季初期(5月)的日降水量的相关关系存在年际间差异。