全球变暖与陆地生态系统研究中的野外增温装置

由于化石燃料燃烧和森林砍伐等人类活动引起的地球大气层中温室气体(主要是二氧化碳)的富集已导致全球平均温度在20世纪升高了0.6 ℃,并将在本世纪继续上升1.4~5.8 ℃。这种地质历史上前所未有的全球变暖将对陆地植物和生态系统产生深远影响,并通过全球碳循环的改变反馈于全球气候变化。作为全球变化生态学的主要研究方法之一,生态系统增温实验能够为生态模型提供参数估计和模型验证。然而由于在世界各地使用的增温装置不同,使得各个生态系统之间的结果比较和整合难以实施,增加了模型预测的不确定性。该文通过比较几种常见的野外增温装置在模拟全球变暖情形时的优缺点,指出利用不同增温装置进行全球变暖研究中应注意的一些问题;同时探讨了全球变暖控制实验研究中的一些关键性的科学问题。     

开放式昼夜不同增温对单季稻影响的试验研究

全球变暖趋势日益明朗,且存在明显的季节性差异和昼夜不对称性。水稻是我国最重要的粮食作物,研究水稻生产力对昼夜不同增温的响应与适应对我国未来粮食安全战略决策至关重要。为此,作者在江苏南京设计我国首个稻田开放式增温（FATI：Free Air Temperature Increased) 系统,在2007—2008年对水稻进行昼夜不同增温（全天增温、白天增温和夜间增温）的试验研究。结果表明,该增温系统可以形成4 m2均匀且稳定的增温范围,全天、白天和夜间增温处理平均分别可以使水稻全生育期冠层日均温升高2.0℃、0.6℃和0.9℃。白天增温使水稻全生育期冠层白天温度平均升高1.1℃,夜间增温使夜间温度平均升高1.8℃,与未来的升温幅度相似。全天、白天和夜间增温处理下,水稻冠层温度日较差变化分别为0.1℃、0.6℃和-0.9℃。同时,在该系统的3种增温情景下,水稻分蘖期、孕穗期和灌浆期的田间冠层温度日变化趋势基本与常规对照区一致,全生育期的日平均温度变化趋势也基本一致。两年的增温试验表明,不同增温情景均对水稻的生育进程、成熟期地上生物量和产量产生了明显的影响。其中全天、白天和夜间增温分别使水稻从移栽到始穗平均的日期缩短3.5 d、2 d和2.5 d,但对始穗至成熟期的影响不明显;全天、白天和夜间增温分别使水稻地上生物量降低7.7%、6.6%和2.8%,但差异均不显著;白天和夜间增温分别使水稻产量下降8.9%和4.5%,而全天增温下水稻产量略有上升,但均未达到显著水平。从产量构成来看,增温下有效穗数和结实率呈现递增趋势,每穗粒数和千粒重呈现下降趋势。增温对水稻株高的影响不明显。上述结果表明,该稻田开放式增温系统能满足水稻系统生产力对未来气候变暖响应与适应的试验研究要求,气候变暖对水稻生产力影响的相关模型分析结果也尚需进一步的田间实际增温试验验证,模型所需的相关参数也需要进一步完善。     

Development of a single mode electromagnetic resonant cavity for rewarming of cryopreserved biomaterials

An electromagnetic (EM) heating system is developed to achieve the rapid and uniform warming of cryopreserved biomaterials. Using the heating system, a rectangular resonant cavity is excited in TE101 mode at frequencies near 434 MHz. In experiments, a spherical phantom of biomaterial with a diameter of 36 mm is placed at the center of the cavity. The phantom is first cooled down to about -80 degrees C within the cavity and then thawed by EM absorption. Results show that EM warming can produce much higher warming rate than conventional water-bath warming method. The spatial temperature distribution in the phantom during EM warming is also more uniform than that during the water-bath warming.     

基于红外增温的草地生态系统响应全球变暖的研究进展

为了更好地了解全球变暖对草地生态系统的影响机制, 该文介绍了红外加热技术的原理、增温效应及其优缺点, 重点从植物物候、光合生理、生长发育、群落结构和功能、土壤特性, 特别是植物群落地下过程方面, 系统综述了基于红外加热技术模拟气候变暖对草地生态系统影响的最新研究进展, 在此基础上探讨了未来草地生态系统响应全球变暖研究拟重视的研究领域。     

Adjustment of Forest Ecosystem Root Respiration as Temperature Warms

Adjustment of ecosystem root respiration to warmer climatic conditions can alter the autotrophic portion of soil respiration and influence the amount of carbon available for biomass production. We examined 44 published values of annual forest root respiration and found an increase in ecosystem root respiration with increasing mean annual temperature (MAT),but the rate of this cross-ecosystem increase (Q10 = 1.6) is less than published values for short-term responses of root respiration to temperature within ecosystems (Q10 = 2-3). When specific root respiration rates and root biomass values were examined, there was a clear trend for decreasing root metabolic capacity (respiration rate at a standard temperature) with increasing MAT. There also were tradeoffs between root metabolic capacity and root system biomass, such that there were no instances of high growing season respiration rates and high root biomass occurring together. We also examined specific root respiration rates at three soil warming experiments at Harvard Forest, USA, and found decreases in metabolic capacity for roots from the heated plots. This decline could be due to either physiological acclimation or to the effects of co-occurring drier soils on the measurement date. Regardless of the cause, these findings clearly suggest that modeling efforts that allow root respiration to increase exponentially with temperature, with Qt0 values of 2 or more, may over-predict root contributions to ecosystem CO2 efflux for future climates and underestimate the amount of C available for other uses,including net primary productivity.     

Climate sensitivity of conifer growth doesn’t reveal distinct low–high dipole along the elevation gradient in the Wolong National Natural Reserve,SW China

Recent climate warming is usually hypothesized to cause tree growth decline in the semi-arid regions where forests are particularly vulnerable to warming induced increases of water deficit. But there is still a large knowledge gap of climate warming effects on tree growth of cold temperate forest in the sub-humid region. Here we assess how climate warming has affected tree growth in the Wolong National Natural Reserve, Southwestern China, where recent warming might not cause tree growth decline because of the cold-humid climatic conditions. Tree-ring data from four co-dominant coniferous species (Larix potaninii var. macrocarpa, Tsuga chinensis, Abies faxoniana and Juniperus saltuaria) along an elevation gradient (from 2700 m to 3700 m) all imprinted temperature signals, and were both positively and significantly correlated with instrumental record of temperature data during the analyzed period of 1954–2010. Furthermore, the rising temperature since 1980 induced pervasive tree growth increases and stronger temperature signals for the coniferous species along the elevation gradient. The tree-ring chronology recorded a strong coherence with instrumental temperature since 1980 and was successful to keep up with the pace of climate warming rate. If climate warming continues, further increases in forest growth could be expected, and the terrestrial carbon sink will be strengthened for the local forest ecosystem in the future.     

寒地春玉米生长发育及产量对花前夜间增温的响应

采用田间开放式夜间增温试验方法,研究雨养农区寒地春玉米生长发育及产量对花前夜间增温的响应.结果表明:夜间增温条件下,0 ～ 10 cm耕层土壤夜间温度升高1.7℃,土壤水分略有下降;夜间增温使春玉米物候期明显提前,花前生育期缩短ld,花后生育期延长1d;夜间增温明显促进春玉米幼苗生长,提高根系长度,单株绿叶面积和棒三叶面积分别比对照提高13.5％和14.6％;与对照相比,春玉米地上生物量和籽粒产量分别显著增高8.2％和9.3％,百粒重显著增高7.1％.东北地区气候变暖尤其是日最低温度升高对春玉米的直接影响效应可能以增产为主.     

陆地生态系统野外增温控制实验的技术与方法

由于人类活动导致的碳排放急剧增加, 工业革命以来全球地表温度显著增加约1 ℃, 未来全球气候还将持续变暖, 到21世纪末最高可升温4 ℃。这种前所未有的气候变化不仅影响陆地植被的适应策略, 也深刻影响生态系统的结构和功能。其中陆地生态系统碳收支对全球变暖的反馈, 是决定未来气候变化强度的关键因素, 因此全球已经开展了大量的生态系统尺度的野外增温控制实验, 研究生态系统碳收支对气温升高的响应, 从而提高地球系统模型的预测精度。然而由于增温技术和方法的不同, 不同研究的结果之间难以进行比较。该文系统总结了常见的野外增温技术和方法, 包括主动增温和被动增温, 阐述了其优缺点、适用对象以及相关研究成果。同时简要介绍了野外增温控制实验的前沿研究方向——新一代野外增温技术(包括全土壤剖面增温和全生态系统增温)和基于新一代增温技术开展的野外增温联网实验。     

Allee effects under climate change

Understanding how climate change affects population dynamics is crucial for assessing future of biodiversity. Here I ask how can Allee effects, occurring when mean individual fitness is reduced in rare populations, respond to increasing temperature. Despite the role Allee effects play in ecology of invasive, threatened and harvested populations, impacts of climate change on Allee effects are practically unknown. Analysis of two population models reveals that whereas the Allee effect driven by predation generally weakens as temperature increases, the Allee effect due to need of finding mates is predicted to become stronger when warming occurs. For the former model, the metabolic theory suggests that with increasing temperature prey growth rate should increase faster than predator attack rate. Increasing temperature thus weakens the Allee effect. In the latter, gypsy moth population model, mating rate increases with warming due to enhanced female?male encounter rate and temperature‐induced modifications in female and male adult emergence distributions. However, male and female mortality rates increase, too and the net effect is strengthening of the Allee effect. These results have repercussions also for pest control, indicating that augmentation of biocontrol agents may perhaps be not as effective as using pesticides or disrupting mating.     

Effects of warming on seed germination of woody species in temperate secondary forests

• Seed germination, a critical stage of the plant life cycle providing a link between seeds and seedlings, is commonly temperature-dependent. The global average surface temperature is expected to rise, but little is known about the responses of seed germination of woody plants in temperate forests to warming.
• In the present study, dried seeds of 23 common woody species in temperate secondary forests were incubated at three temperature sequences without cold stratification and after experiencing cold stratification. We calculated five seed germination indices and the comprehensive membership function value that summarized the above indicators.
• Compared to the control, +2 and +4 °C treatments without cold stratification shortened germination time by 14% and 16% and increased the germination index by 17% and 26%, respectively. For stratified seeds, +4 °C treatment increased germination percentage by 49%, and +4 and +2 °C treatments increased duration of germination and the germination index, and shortened mean germination time by 69%, 458%, 29% and 68%, 110%, 12%, respectively. The germination of Fraxinus rhynchophylla and Larix kaempferi were most sensitive to warming without and with cold stratification, respectively. Seed germination of shrubs was the least sensitive to warming among functional types.
• These findings indicate warming (especially extreme warming) will enhance the seedling recruitment of temperate woody species, primarily via shortening the germination time, particularly for seeds that have undergone cold stratification. In addition, shrubs might narrow their distribution range

     

Asymmetric effects of daytime and nighttime warming on alpine treeline recruitment

Trees at their upper range limits are highly sensitive to climate change, and thus alpine treelines worldwide have changed their recruitment patterns in response to climate warming. However, previous studies focused only on daily mean temperature, neglecting the asymmetric influences of daytime and nighttime warming on recruitments in alpine treelines. Here, based on the compiled dataset of tree recruitment series from 172 alpine treelines across the Northern Hemisphere, we quantified and compared the different effects of daytime and nighttime warming on treeline recruitment using four indices of temperature sensitivity, and assessed the responses of treeline recruitment to warming-induced drought stress. Our analyses demonstrated that even in different environmental regions, both daytime and nighttime warming could significantly promote treeline recruitment, and however, treeline recruitment was much more sensitive to nighttime warming than to daytime warming, which could be attributable to the presence of drought stress. The increasing drought stress primarily driven by daytime warming rather than by nighttime warming would likely constrain the responses of treeline recruitment to daytime warming. Our findings provided compelling evidence that nighttime warming rather than daytime warming could play a primary role in promoting the recruitment in alpine treelines, which was related to the daytime warming-induced drought stress. Thus, daytime and nighttime warming should be considered separately to improve future projections of global change impacts across alpine ecosystems.     

Seasonally different response of photosynthetic activity to daytime and night‐time warming in the Northern Hemisphere

Over the last century the Northern Hemisphere has experienced rapid climate warming, but this warming has not been evenly distributed seasonally, as well as diurnally. The implications of such seasonal and diurnal heterogeneous warming on regional and global vegetation photosynthetic activity, however, are still poorly understood. Here, we investigated for different seasons how photosynthetic activity of vegetation correlates with changes in seasonal daytime and night‐time temperature across the Northern Hemisphere (>30°N), using Normalized Difference Vegetation Index (NDVI) data from 1982 to 2011 obtained from the Advanced Very High Resolution Radiometer (AVHRR). Our analysis revealed some striking seasonal differences in the response of NDVI to changes in day‐ vs. night‐time temperatures. For instance, while higher daytime temperature (T_max) is generally associated with higher NDVI values across the boreal zone, the area exhibiting a statistically significant positive correlation between T_max and NDVI is much larger in spring (41% of area in boreal zone – total area 12.6 × 10⁶ km²) than in summer and autumn (14% and 9%, respectively). In contrast to the predominantly positive response of boreal ecosystems to changes in T_max, increases in T_max tended to negatively influence vegetation growth in temperate dry regions, particularly during summer. Changes in night‐time temperature (T_min) correlated negatively with autumnal NDVI in most of the Northern Hemisphere, but had a positive effect on spring and summer NDVI in most temperate regions (e.g., Central North America and Central Asia). Such divergent covariance between the photosynthetic activity of Northern Hemispheric vegetation and day‐ and night‐time temperature changes among different seasons and climate zones suggests a changing dominance of ecophysiological processes across time and space. Understanding the seasonally different responses of vegetation photosynthetic activity to diurnal temperature changes, which have not been captured by current land surface models, is important for improving the performance of next generation regional and global coupled vegetation‐climate models.     

Can amphibians take the heat? Vulnerability to climate warming in subtropical and temperate larval amphibian communities

Predicting the biodiversity impacts of global warming implies that we know where and with what magnitude these impacts will be encountered. Amphibians are currently the most threatened vertebrates, mainly due to habitat loss and to emerging infectious diseases. Global warming may further exacerbate their decline in the near future, although the impact might vary geographically. We predicted that subtropical amphibians should be relatively susceptible to warming‐induced extinctions because their upper critical thermal limits (CT_max) might be only slightly higher than maximum pond temperatures (T_max). We tested this prediction by measuring CT_max and T_max for 47 larval amphibian species from two thermally distinct subtropical communities (the warm community of the Gran Chaco and the cool community of Atlantic Forest, northern Argentina), as well as from one European temperate community. Upper thermal tolerances of tadpoles were positively correlated (controlling for phylogeny) with maximum pond temperatures, although the slope was steeper in subtropical than in temperate species. CT_max values were lowest in temperate species and highest in the subtropical warm community, which paradoxically, had very low warming tolerance (CT_max–T_max) and therefore may be prone to future local extinction from acute thermal stress if rising pond T_max soon exceeds their CT_max. Canopy‐protected subtropical cool species have larger warming tolerance and thus should be less impacted by peak temperatures. Temperate species are relatively secure to warming impacts, except for late breeders with low thermal tolerance, which may be exposed to physiological thermal stress in the coming years.     

Population trends of European common birds are predicted by characteristics of their climatic niche

Temperate species are projected to experience the greatest temperature increases across a range of modelled climate change scenarios, and climate warming has been linked to geographical range and population changes of individual species at such latitudes. However, beyond the multiple modelling approaches, we lack empirical evidence of contemporary climate change impacts on populations in broad taxonomic groups and at continental scales. Identifying reliable predictors of species resilience or susceptibility to climate warming is of critical importance in assessing potential risks to species, ecosystems and ecosystem services. Here we analysed long‐term trends of 110 common breeding birds across Europe (20 countries), to identify climate niche characteristics, adjusted to other environmental and life history traits, that predict large‐scale population changes accounting for phylogenetic relatedness among species. Beyond the now well‐documented decline of farmland specialists, we found that species with the lowest thermal maxima (as the mean spring and summer temperature of the hottest part of the breeding distribution in Europe) showed the sharpest declines between 1980 and 2005. Thermal maximum predicted the recent trends independently of other potential predictors. This study emphasizes the need to account for both land‐use and climate changes to assess the fate of species. Moreover, we highlight that thermal maximum appears as a reliable and simple predictor of the long‐term trends of such endothermic species facing climate change.     

昆虫对全球气候变暖的响应

过去的100年全球地表平均温度显著上升,全球气候变暖对生物的影响引起世界范围内的广泛关注。和其他生物一样,昆虫也受到了气候变暖的影响,如繁殖发育速度增快、遗传变异、种群多样性降低、分布区扩大、种群爆发、外来入侵、种群灭绝等等。全球变暖引起的昆虫响应对农林业以及人类健康存在潜在风险,因此本文主要从物候、分布区、生长发育及繁殖、形态、行为与生理、分子水平这些方面综述全球气候变暖背景下昆虫如何响应,并讨论了目前研究动态和未来的研究方向,意在为气候变化条件下昆虫科学管理策略(如种群监控、模型预测、风险评估、遗传多样性、抗性遗传等)提供指导意义。     

Climate changes could jeopardize a main source of livelihood in Africa’s drylands

Climate change in Africa poses a serious threat to many ecosystems and livelihoods, making them vulnerable to climate-related risks. Gum and resin bearing tree species as the genus Boswellia are the main economic and livelihood sources in most dryland areas of Africa. We use species distribution models to find critical sites where Boswellia species may no longer occur in the future. Our models identify potential regions that could benefit from their cultivation and promote conservation efforts for the species to thrive. We projected models to new CMIP6 scenarios and different dispersal profiles. Despite the prevailing aridity already imposed on the species, Boswellia distribution shows a dramatic reduction. Future investments in Boswellia restoration and strategies to promote sustainable extraction of resources may be key to sustain populations and Boswellia dominated forests in many parts of the African continent.     

Pollen and climatic change

Summary There has been increasing interest shown in the literature over the possible implications of global warming on the climate, ecology and economy of the world community. Aerobiologists in Europe could play an important strategic role in monitoring and predicting ecological change and in providing useful information for climatologists. The problems of identification and co-ordination are briefly discussed.     

Rapid shifts in the thermal sensitivity of growth but not development rate causes temperature–size response variability during ontogeny in arthropods

Size at maturity in ectotherms commonly declines with warming. This near‐universal phenomenon, formalised as the temperature–size rule, has been observed in over 80% of tested species, from bacteria to fish. The proximate cause has been attributed to the greater temperature dependence of development rate than growth rate, causing individuals to develop earlier but mature smaller in the warm. However, few studies have examined the ontogenetic progression of the temperature–size response at high resolution. Using marine planktonic copepods, we experimentally determined the progression of the temperature–size response over ontogeny. Temperature–size responses were not generated gradually from egg to adult, contrary to the predictions of a naïve model in which development rate was assumed to be more temperature‐dependent than growth rate, and the difference in the temperature dependence of these two rates remained constant over ontogeny. Instead, the ontogenetic progression of the temperature–size response in experimental animals was highly episodic, indicating rapid changes in the extent to which growth and development rates are thermally decoupled. The strongest temperature–size responses occurred temporally mid‐way through ontogeny, corresponding with the point at which individuals reached between ~5 and 25% of their adult mass. Using the copepod Oithona nana, we show that the temperature‐dependence of growth rate varied substantially throughout ontogeny, whereas the temperature dependence of development rate remained constant. The temperature‐dependence of growth rate even exceeded that of development rate in some life stages, leading to a weakening of the temperature–size response. Our analyses of arthropod temperature–size responses from the literature, including crustaceans and insects, support these conclusions more broadly. Overall, our findings provide a better understanding of how the temperature–size rule is produced over ontogeny. Whereas we find support for the generality of developmental rate isomorphy in arthropods (shared temperature dependence of development rate across life stages), this concept appears not to apply to growth rates.     

Elevated air temperature alters an old-field insect community in a multifactor climate change experiment

To address how multiple, interacting climate drivers may affect plant–insect community associations, we sampled insects that naturally colonized a constructed old‐field plant community grown for over 2 years under simultaneous CO₂, temperature, and water manipulation. Insects were sampled using a combination of sticky traps and vacuum sampling, identified to morphospecies and the insect community with respect to abundance, richness, and evenness quantified. Individuals were assigned to four broad feeding guilds in order to examine potential trophic level effects. Although there were occasional effects of CO₂ and water treatment, the effects of warming on the insect community were large and consistent. Warming significantly increased Order Thysanoptera abundance and reduced overall morphospecies richness and evenness. Nonmetric multidimensional scaling found that only temperature affected insect community composition, while a Sørensen similarity index showed less correspondence in the insect community between temperature treatments compared with CO₂ or soil water treatments. Within the herbivore guild, elevated temperature significantly reduced richness and evenness. Corresponding reductions of diversity measures at higher trophic levels (i.e. parasitoids), along with the finding that herbivore richness was a significant predictor of parasitoid richness, suggest trophic‐level effects within the insect community. When the most abundant species were considered in temperature treatments, a small number of species increased in abundance at elevated temperature, while others declined compared with ambient temperature. Effects of temperature in the dominant insects demonstrated that treatment effects were limited to a relatively small number of morphospecies. Observed effects of elevated CO₂ concentration on whole‐community foliar N concentration did not result in any effect on herbivores, which are probably the most susceptible guild to changes in plant nutritional quality. These results demonstrate that climatic warming may alter certain insect communities via effects on insect species most responsive to a higher temperature, contributing to a change in community structure.     

Design and performance of combined infrared canopy and belowground warming in the B4WarmED (Boreal Forest Warming at an Ecotone in Danger) experiment

Conducting manipulative climate change experiments in complex vegetation is challenging, given considerable temporal and spatial heterogeneity. One specific challenge involves warming of both plants and soils to depth. We describe the design and performance of an open‐air warming experiment called Boreal Forest Warming at an Ecotone in Danger (B4WarmED) that addresses the potential for projected climate warming to alter tree function, species composition, and ecosystem processes at the boreal‐temperate ecotone. The experiment includes two forested sites in northern Minnesota, USA, with plots in both open (recently clear‐cut) and closed canopy habitats, where seedlings of 11 tree species were planted into native ground vegetation. Treatments include three target levels of plant canopy and soil warming (ambient, +1.7 °C, +3.4 °C). Warming was achieved by independent feedback control of voltage input to aboveground infrared heaters and belowground buried resistance heating cables in each of 72‐7.0 m² plots. The treatments emulated patterns of observed diurnal, seasonal, and annual temperatures but with superimposed warming. For the 2009 to 2011 field seasons, we achieved temperature elevations near our targets with growing season overall mean differences (?T_below) of +1.84 °C and +3.66 °C at 10 cm soil depth and (?T^above) of +1.82 °C and +3.45 °C for the plant canopies. We also achieved measured soil warming to at least 1 m depth. Aboveground treatment stability and control were better during nighttime than daytime and in closed vs. open canopy sites in part due to calmer conditions. Heating efficacy in open canopy areas was reduced with increasing canopy complexity and size. Results of this study suggest the warming approach is scalable: it should work well in small‐statured vegetation such as grasslands, desert, agricultural crops, and tree saplings (<5 m tall).