Carbon dynamics and budget in a Zoysia japonica grassland, central Japan

The ecosystem carbon budget was estimated in a Japanese Zoysia japonica grassland. The green biomass started to grow in May and peaked from mid-July to September. Seasonal variations in soil CO₂ flux and root respiration were mediated by changes in soil temperature. Annual soil CO₂ flux was 1,121.4 and 1,213.6 g C m⁻² and root respiration was 471.0 and 544.3 g C m⁻² in 2007 and 2008, respectively. The root respiration contribution to soil CO₂ flux ranged from 33% to 71%. During the growing season, net primary production (NPP) was 747.5 and 770.1 g C m⁻² in 2007 and 2008, respectively. The biomass removed by livestock grazing (GL) was 122.1 and 102.7 g C m⁻², and the livestock returned 28.2 and 25.6 g C m⁻² as fecal input (FI) in 2007 and 2008, respectively. The decomposition of FI (DL, the dry weight loss due to decomposition) was very low, 1.5 and 1.4 g C m⁻², in 2007 and 2008. Based on the values of annual NPP, soil CO₂ flux, root respiration, GL, FI, and DL, the estimated carbon budget of the grassland was 1.7 and 22.3 g C m⁻² in 2007 and 2008, respectively. Thus, the carbon budget of this Z. japonica grassland ecosystem remained in equilibrium with the atmosphere under current grazing conditions over the 2 years of the study.     

Measurement of net ecosystem production and ecosystem respiration in a Zoysia japonica grassland,central Japan,by the chamber method

Measuring light, temperature, soil moisture, and growth provides a better understanding of net ecosystem production (NEP), ecosystem respiration (R _eco), and their response functions. Here, we studied the variations in NEP and R _eco in a grassland dominated by a perennial warm-season C₄ grass, Zoysia japonica. We used the chamber method to measure NEP and R _eco from August to September 2007. Biomass and leaf area index (LAI) were also measured to observe their effects on NEP and R _eco. Diurnal variations in NEP and R _eco were predicted well by light intensity (PPFD) and by soil temperature, respectively. Maximum NEP (NEP_max) values on days of year 221, 233, 247, and 262, were 2.44, 2.55, 3.90, and 4.17 μmol m⁻² s⁻¹, respectively. Throughout the growing period, the apparent quantum yield (α) increased with increasing NEP_max that ranged from 0.0154 to 0.0515, and NEP responded to the soil temperature changes by 44% and R _eco changes by 48%, and R _eco responded from 88 to 94% with the soil temperature diurnally. NEP’s light response and R _eco’s temperature response were affected by soil water content; more than 27% of the variation in NEP and 67% of the variation in R _eco could be explained by this parameter. NEP was strongly correlated with biomass and LAI, but R _eco was not, because environmental variables affected R _eco more strongly than growth parameters. Using the light response of NEP, the temperature response of R _eco, and meteorological data, daily NEP and R _eco were estimated at 0.67, 0.81, 1.17, and 1.56 g C m⁻², and at 2.88, 2.50, 3.51, and 3.04 g C m⁻², respectively, on days of year 221, 233, 247, and 262. The corresponding daily gross primary production (NEP + R _eco) was 3.5, 3.3, 4.6, and 4.6 g C m⁻².     

环境因子和生物因子对黄河三角洲滨海湿地土壤呼吸的影响

采用Li-8150多通道土壤呼吸自动测量系统对黄河三角洲滨海湿地土壤呼吸进行全年连续测定,同步测量了温度、土壤含水量、地上生物量以及叶面积指数等环境因子和生物因子.结果表明: 土壤呼吸日动态在全年尺度上多呈单峰型,但在受到土壤封冻和地表积水干扰时,土壤呼吸日动态呈多峰型.土壤呼吸具有明显的季节动态特征,总体呈单峰型,年平均土壤呼吸速率为0.85 μmol CO₂·m^-2·s^-1,生长季平均土壤呼吸速率为1.22 μmol CO₂·m^-2·s^-1.在全年尺度上,土壤温度是滨海湿地土壤呼吸的主要控制因子,可解释全年土壤呼吸87.5%的变化.在生长季尺度上,土壤含水量和叶面积指数对土壤呼吸的协同影响达到85%.     

退化高寒草地土壤真菌群落与土壤环境因子间相互关系

【目的】为探究祁连山高寒草地退化过程中土壤真菌群落分布特征与土壤环境因子间的相互关系。【方法】利用Illumina Miseq PE250高通量测序技术对轻度、中度和重度退化草地土壤真菌群落结构变化及其多样性进行分析,并对土壤真菌群落与土壤环境因子的相互关系进行冗余分析(RDA)。【结果】随着退化程度加剧,土壤pH呈现出升高趋势,电导率呈现出先升高后降低趋势,土壤含水量、有机碳、全氮、全磷和全钾含量均逐渐降低。高通量测序共得到750575条有效序列和5788个OTUs;各试验点样地中真菌群落Chao1指数和Shannon-Wiener指数变化各异。在门分类水平上,子囊菌门(Ascomycota)、担子菌门(Basidiomycota)、接合菌门(Zygomycota)、球囊菌门(Glomeromycota)和壶菌门(Chytridiomycota)是各草地土壤的优势类群。RDA分析表明,土壤速效钾、全氮、速效氮和有机碳是祁连山不同退化高寒草地土壤真菌群落分布的主要驱动因子。【结论】祁连山不同退化高寒草地土壤真菌群落间差异明显,土壤环境因子是影响土壤真菌群落分布的重要因素。     

半干旱草原土壤呼吸组分区分与菌根呼吸的贡献

土壤呼吸组分的区分对于理解地下碳循环过程非常重要。而菌根真菌在地下碳循环过程中扮演着重要的角色, 但是有关菌根呼吸在草原生态系统中的研究相对较少。该研究在内蒙古半干旱草原应用深浅环网孔法, 结合浅环、深环(排除根系)和一个带有40 μm孔径窗口的土壤环(排除根系但是有菌根菌丝体)将根和菌丝物理分离, 来区分不同的呼吸组分。结果表明: 异养呼吸对总呼吸的贡献比例为51%, 根呼吸的贡献比例为26%, 菌根呼吸的贡献比例为23%, 菌根呼吸的比例3年变化范围为21%-26%。与国内外研究相比, 此方法提供了一个相对稳定的菌根呼吸测量精度范围, 在草原生态系统中切实可行。对菌根呼吸的准确定量将有助于预测草原生态系统土壤碳释放过程对未来气候变化的响应。     

Partitioning of soil respiration components and evaluating the mycorrhizal contribution to soil respiration in a semiarid grassland

土壤呼吸组分的区分对于理解地下碳循环过程非常重要。而菌根真菌在地下碳循环过程中扮演着重要的角色, 但是有关菌根呼吸在草原生态系统中的研究相对较少。该研究在内蒙古半干旱草原应用深浅环网孔法, 结合浅环、深环(排除根系)和一个带有40 μm孔径窗口的土壤环(排除根系但是有菌根菌丝体)将根和菌丝物理分离, 来区分不同的呼吸组分。结果表明: 异养呼吸对总呼吸的贡献比例为51%, 根呼吸的贡献比例为26%, 菌根呼吸的贡献比例为23%, 菌根呼吸的比例3年变化范围为21%-26%。与国内外研究相比, 此方法提供了一个相对稳定的菌根呼吸测量精度范围, 在草原生态系统中切实可行。对菌根呼吸的准确定量将有助于预测草原生态系统土壤碳释放过程对未来气候变化的响应。     

城市绿地土壤呼吸速率的变化特征及其影响因子

城市绿地土壤呼吸作用深刻影响着城市生态系统碳循环过程,强化城市绿地土壤呼吸速率(Rs)的变化特征及其影响因素的研究,可揭示绿地在城市生态系统碳循环过程中的作用,为优化布局城市绿地和实现低碳排放目标提供科学依据。以广州市海珠湖公园的疏林、灌丛和草地3种典型植被类型的土壤为研究对象,于2013年11月-2014年10月采用静态箱—气相色谱法对公园绿地Rs进行跟踪观测。结果表明:海珠湖公园城市绿地在干湿季节中Rs差异显著;干季Rs较低且波动幅度较小疏林、灌丛和草地的凡变化范围分别为(1.66±0.18)-(3.26±0.20)μmol m~(-2)s~(-1)、(1.27±0.15)-(3.67±0.16)μmol m~(-2)s~(-1)和(1.94±0.08)-(6.82±1.13)μmol m~(-2)s~(-1);湿季Rs较高且波动幅度较大,疏林、灌丛和草地的Rs变化范围分别为(3.53±0.46)-(13.81±1.31)μmol m~(-2)s~(-1)、(2.82±0.22)-(12.72±1.16)μmol m~(-2)s~(-1)和(2.80±0.30)-(9.83±0.96)μmol m~(-2)s~(-1)。T_(10)和VWC_(10)均对土壤呼吸过程有重要的影响,进一步通过回归分析得出,土壤10cm处温度(T_(10))和体积含水量(VWC_(10))分别解释Rs时间变异的40%左右和10-24%左右。T_(10)和VWC_(10)相互影响、共同作用于土壤呼吸过程,双因素复合模型的解释能力较单因素模型明显提高,均在50%以上,复合模型为Rs=α·exp(β·T_(10)+γ·VWC_(10))。干湿季土壤呼吸的温度敏感性(Q_(10))有明显差异,湿季的Q_(10)比干季的分别高0.44、0.70和0.46。     

Carbon sequestration in soil in a semi‐natural Miscanthus sinensis grassland and Cryptomeria japonica forest plantation in Aso,Kumamoto, Japan

Although Miscanthus sinensis grasslands (Misc‐GL) and Cryptomeria japonica forest plantations (Cryp‐FP) are proposed bioenergy feedstock systems, their relative capacity to sequester C may be an important factor in determining their potential for sustainable bioenergy production. Therefore, our objective was to quantify changes in soil C sequestration 47 years after a Misc‐GL was converted to a Cryp‐FP. The study was conducted on adjacent Misc‐GL and Cryp‐FP located on Mt. Aso, Kumamoto, Japan. After Cryp‐FP establishment, only the Misc‐GL continued to be managed by annual burning every March. Mass C and N, δ¹³C, and δ¹⁵N at 0–30 cm depth were measured in 5 cm increments. Carbon and N concentrations, C:N ratio, δ¹³C, and δ¹⁵N were measured in litter and/or ash, and rhizomes or roots. Although C input in Misc‐GL by M. sinensis was approximately 36% of that in Cryp‐FP by C. japonica, mean annual soil C sequestration in Misc‐GL (503 kg C ha^?1 yr^?1) was higher than that in Cryp‐FP (284 kg C ha^?1 yr^?1). This was likely the result of larger C input from aboveground litter to soil, C‐quality (C:N ratio and lignin concentration in aboveground litter) and possibly more recalcitrant C (charcoal) inputs by annual burning. The difference in soil δ¹⁵N between sites indicated that organic C with N had greater cycling between heterotrophic microbes and soil and produces more recalcitrant humus in Misc‐GL than in Cryp‐FP. Our data indicate that in terms of soil C sequestration, maintenance of Misc‐GL may be more advantageous than conversion to Cryp‐FP in Aso, Japan.     

Contribution of root respiration to soil respiration in a C3/C4 mixed grassland

The spatial and temporal variations of soil respiration were studied from May 2004 to June 2005 in a C₃/C₄ mixed grassland of Japan. The linear regression relationship between soil respiration and root biomass was used to determine the contribution of root respiration to soil respiration. The highest soil respiration rate of 11-54 Μmol m^-2 s^-1 was found in August 2004 and the lowest soil respiration rate of 4.99 Μmol m^-2 s^-1 was found in April 2005. Within-site variation was smaller than seasonal change in soil respiration. Root biomass varied from 0.71 kg m^-2 in August 2004 to 102 in May 2005. Within-site variation in root biomass was larger than seasonal variation. Root respiration rate was highest in August 2004 (5.7 Μmol m^-2 s^-1) and lowest in October 2004 (1.7 Μmol m^-2 s^-1). Microbial respiration rate was highest in August 2004 (5.8 Μmol m^-2 s^-1) and lowest in April 2005 (2.59 Μmol m^-2 s^-1). We estimated that the contribution of root respiration to soil respiration ranged from 31% in October to 51% in August of 2004, and from 45% to 49% from April to June 2005.     

Different responses of soil respiration to environmental factors across forest stages in a Southeast Asian forest

Soil respiration (SR) in forests contributes significant carbon dioxide emissions from terrestrial ecosystems and is highly sensitive to environmental changes, including soil temperature, soil moisture, microbial community, surface litter, and vegetation type. Indeed, a small change in SR may have large impacts on the global carbon balance, further influencing feedbacks to climate change. Thus, detailed characterization of SR responses to changes in environmental conditions is needed to accurately estimate carbon dioxide emissions from forest ecosystems. However, data for such analyses are still limited, especially in tropical forests of Southeast Asia where various stages of forest succession exist due to previous land‐use changes. In this study, we measured SR and some environmental factors including soil temperature (ST), soil moisture (SM), and organic matter content (OM) in three successional tropical forests in both wet and dry periods. We also analyzed the relationships between SR and these environmental variables. Results showed that SR was higher in the wet period and in older forests. Although no response of SR to ST was found in younger forest stages, SR of the old‐growth forest significantly responded to ST, plausibly due to the nonuniform forest structure, including gaps, that resulted in a wide range of ST. Across forest stages, SM was the limiting factor for SR in the wet period, whereas SR significantly varied with OM in the dry period. Overall, our results indicated that the responses of SR to environmental factors varied temporally and across forest succession. Nevertheless, these findings are still preliminary and call for detailed investigations on SR and its variations with environmental factors in Southeast Asian tropical forests where patches of successional stages dominate.     

氮添加对多伦草原土壤微生物呼吸及其温度敏感性的影响

人类活动导致氮和磷输入到草原生态系统,对土壤有机碳循环产生影响,但是土壤微生物呼吸(Soil microbial respiration,Rs)及其温度敏感性(Q₁₀)对于氮沉降和磷有效性增加的响应还存在争议。因此,依托多伦草原氮添加样地(0、50 kg N hm^-2 a^-1和100 kg N hm^-2 a^-1),并添加磷进行室内恒温培养(10℃和15℃),研究氮添加和磷有效性增加对Rs及其Q₁₀的影响。结果发现:氮添加显著降低胞壁酸含量和显著增加真菌丰富度(Fungal richness, F-richness)。与N0处理相比,N50和N100处理使累积呼吸量显著降低了61.2%和67.1%,但Q₁₀显著升高了32.7%和50.8%;磷有效性增加没有对累积呼吸量及其Q₁₀产生显著影响。逐步回归结果表明,F-richness和pH值分别是累积呼吸量及其Q₁₀最重要的影响因子。研究表明氮添加...     

Alpine grassland ecosystem respiration variation under irrigation in Northern Tibet

Grassland ecosystems are important parts of terrestrial ecosystems and play an important role in the global carbon cycle. In recent years, the grasslands in Northern Tibet have experienced warming, and its precipitation has also increased. Alpine grassland irrigation measures could be a reasonable pathway to redistribute and make full use of the increased precipitation. In this study, we measured the soil respiration in alpine grassland in Northern Tibet under sprinkler head irrigation in the growing season to determine the relationships between soil temperature /water and ecosystem/soil respiration, soil moisture and Q₁₀, and soil temperature and Q₁₀. The results showed that after 2 years irrigation, alpine grassland aboveground biomass increased significantly, with 2010 higher than 2009. There was significant annual, seasonal and daily variation of soil respiration. Under irrigation, ecosystem respiration and soil respiration increased 75% and 64% respectively; soil water increase can promote the respiration of ecosystem and its components. In our results, the Q₁₀ value was 2.23–2.81, over the global average. The irrigation can promote ecosystem respiration temperature sensitivity. There was a positive linear correlation between ecosystem respiration and grassland aboveground biomass. The aboveground biomass accounted for 32.8% of ecosystem respiration variation. Soil respiration accounted for more than 70% of ecosystem respiration, indicating that the contribution to carbon emissions of soil respiration is very high. In short, we can project that in grasslands biomass and ecosystem respiration will increase under future precipitation change, which will significantly affect the function of alpine grassland carbon storage.     

氮添加量和施氮频率对温带半干旱草原土壤呼吸及组分的影响

日益加剧的氮沉降已经对陆地生态系统生产力和碳循环过程产生了显著影响。草原生态系统近90%的碳储存在土壤中, 明确土壤呼吸及其组分对氮添加的响应对评估大气氮沉降背景下草原生态系统碳平衡和土壤碳库稳定性是非常重要的。以往关于草原土壤呼吸对氮沉降响应的理解多是基于短期(<5年)和低频(每年1-2次)氮添加实验研究, 而关于长期氮添加和不同施氮频率对土壤呼吸及其组分的影响尚缺乏实验证据。该研究基于2008年建立在内蒙古半干旱草原的长期氮添加实验平台, 包括6个氮添加水平和2个施氮频率处理, 通过连续两年(2018-2019年)土壤呼吸及其组分的测定, 发现: 1)氮添加显著降低了土壤总呼吸速率(R_s), 且R_s下降程度随着氮添加量的增加而增强。土壤异养呼吸速率(R_h)的显著下降是R_s下降的主要原因。2)不同氮添加频率并未显著影响土壤呼吸及其组分对氮添加处理的响应。3)长期氮添加造成的土壤酸化降低了土壤微生物活性并改变了微生物群落结构(真菌/细菌比), 进而导致土壤呼吸及其异养组分呈现显著的负响应。以上结果表明, 长期(>10年)氮添加对土壤地下碳循环过程的抑制作用非常明显, 特别是异养呼吸组分的下降会降低土壤有机碳分解速率, 有助于土壤碳库稳定性的维持。同时, 随着氮添加处理时间的延长, 不同施氮频率影响效应的差异减弱, 表明目前长期的低频氮添加实验监测数据可以为评估自然生态系统对大气氮沉降的响应提供较为可靠的参考。     

Spatial variation in a grassland on soil rich in heavy metals

Abstract. The vegetation in a grassland area in the prefecture of Kilkis (N. Greece), known for its surface Cu-mineralization, was studied. 43 quadrats were established along a transect through an area where the vegetation formed patches of different size. Cover-abundance and frequency estimates for all species were made. Normal Association Analysis revealed five quadrat groups characterized by Trifolium scabrum, Linaria pelisseriana, Anthoxanthum ovatum, Gypsophila muralis and Minuartia hirsuta ssp. falcata. 43 soil samples were analysed for pH, organic C, CaCO₃, total content of Fe, Zn, Pb, Cu, Mn, Ca, Mg, K, Na and soil texture. From a discriminant analysis performed on soil data five soil groups resulted, which are highly related to the five vegetation groups. Thymus sibthorpii, Minuartia hirsuta ssp. falcata and Rumex acetosella are the most important taxa with respect to physiognomy and patchi-ness of the vegetation. The number of species in each group of quadrats is affected by the relative favourableness or severity of the soil conditions. Metal contents, mainly Zn, Cu, Mg and Na, and soil texture are considered to be among the main factors controlling the structure and physiognomy of the vegetation.     

Effects of sieving, drying and rewetting upon soil bacterial community structure and respiration rates

Soil microcosm studies often require some form of soil homogenisation, such as sieving, to provide a representative sample. Frequently, soils are also homogenised following drying and are then rewetted, yet little research has been done to understand how these methods impact upon microbial communities. Here we compared the molecular diversity and functional responses of intact cores from a Scottish grassland soil with homogenised samples prepared by drying, sieving and rewetting or freshly sieving wet soils. Results showed that there was no significant difference in total soil CO₂-C efflux between the freshly sieved and intact core treatments, however, respiration was significantly higher in the dried and rewetted microcosms. Molecular fingerprinting (T-RFLP) of bacterial communities at two different time-points showed that both homogenisation methods significantly altered bacterial community structure with the largest differences being observed after drying and rewetting. Assessments of responsive taxa in each treatment showed that intact cores were dominated by Acidobacterial peaks whereas an increased relative abundance of Alphaproteobacterial terminal restriction fragments were apparent in both homogenised treatments. However, the shift in community structure was not as large in the freshly sieved soil. Our findings suggest that if soil homogenisation must be performed, then fresh sieving of wet soil is preferable to drying and rewetting in approximating the bacterial diversity and functioning of intact cores.     

中国草原土壤呼吸作用研究进展

中国草原面积约占国土面积的40%, 且大都位于生态脆弱区, 对气候和环境变化十分敏感, 在未来大气CO₂调控中有着重要的作用。为增进对中国草原土壤呼吸作用的理解, 该文综述了近10年来中国草原土壤呼吸作用的最新研究进展, 指出中国草原土壤呼吸作用的研究主要集中在东北平原、内蒙古高原和青藏高原。草原土壤呼吸作用日动态的主导控制因子是温度, 季节动态的主导控制因子可以是温度、水分或二者的交互作用, 取决于研究地点的限制性环境因子, 而年际动态的主导控制因子为水分。草原土壤呼吸作用还存在着巨大的空间变异, 年降水和土壤全氮含量是不同类型草原土壤呼吸作用空间异质性的主导控制因子。土壤呼吸作用对全球变化的响应比较复杂, 取决于各因子之间相互影响的贡献。现有的土壤呼吸作用模型大多只考虑了水热因子, 很少包含土壤因子和生物因子及其协同作用的影响。在此基础上, 指出未来中国草原土壤呼吸作用拟加强的研究重点: 1)温带荒漠草原土壤呼吸作用研究; 2)非生长季土壤呼吸作用研究; 3)多时空尺度草原土壤呼吸作用的比较研究; 4)草原土壤呼吸作用过程模拟研究; 5)草原土壤呼吸作用的遥感监测评估研究。     

氮添加对沙质草地微生物呼吸与根系呼吸的影响

土壤呼吸可以细化为根系呼吸和微生物呼吸,二者对氮添加的响应有所不同.本文以科尔沁沙质草地为研究对象,探讨氮添加对土壤CO₂排放的影响,并细化为微生物呼吸和根系呼吸的响应特征.结果表明: 在观测期(5—10月),土壤呼吸、微生物呼吸月动态均呈先升高后降低的趋势;微生物呼吸是土壤呼吸的主要贡献者,占82.6%;观测期内根系呼吸贡献率随月份而变化,根系呼吸贡献率两个峰值分别出现在5月(占49.4%)和8月(占41.9%),6个月的平均贡献率为17.4%;在10 ℃条件下,根系呼吸较微生物呼吸对氮添加的响应更为敏感,微生物呼吸速率在氮添加后降低了3.9%,而根系呼吸降低了17.7%;氮添加提高了土壤呼吸、微生物呼吸温度敏感性Q₁₀值,也提高了二者对土壤水分变化的敏感程度.     

玉米生长季土壤呼吸的时间变异性及其影响因素

基于东北地区玉米生态系统土壤呼吸连续2个生长季的观测,阐明了土壤呼吸日、季节变化特征,综合分析了水热因子、土壤性质、生物量及叶面积指数（LAI）对土壤呼吸的影响。结果表明：玉米地土壤呼吸日变化为不对称的单峰型曲线,最小值和最大值分别出现在6：00-7：00和13：00左右。2005年玉米生长季土壤呼吸速率均值为3．16μmol CO2&#183;m^-2&#183;s^-1,最大值为4．77μmol CO2&#183;m^-2&#183;s^-1,出现在7月28日;最小值为1．31μmol CO2&#183;m^-2&#183;s^-1,出现在5月4日。统计分析表明：土壤温度是玉米生态系统土壤呼吸日变化的驱动因素;土壤温度和土壤水分是影响土壤呼吸季节变化的关键因素,二者可以解释玉米生长季土壤呼吸时间变异的87％;LAI和根系生物量与土壤呼吸速率呈正相关,说明生物因子对土壤呼吸季节变化也有影响;土壤有机质、全氮和碳氮比等土壤理化特性与土壤呼吸速率的关系较弱;玉米生长季追施氮肥明显促进土壤呼吸速率。     

杉木人工林去除根系土壤呼吸的季节变化及影响因子

2007年1月至2008年12月,在长沙天际岭国家森林公园内,采用挖壕法研究杉木人工林去除根系后土壤呼吸速率季节动态及其与5 cm土壤温、湿度的相关关系。结果表明:去除根系与对照5 cm土壤温度的差异性不显著(P=0.987),5 cm土壤湿度差异显著(P=0.035)。杉木林去除根系处理后土壤呼吸速率明显降低,2007至2008两年实验期间去除根系与对照处理变化范围分别为0.19-2.01μmol.m-2s-1和0.26-2.61μmo.lm-2s-1,年均土壤呼吸速率分别为0.90μmo.lm-2s-1和1.30μmol.m-2s-1。去除根系土壤呼吸速率降低幅度为9.4%-59.7%,平均降低了30.4%。去除根系和对照的土壤呼吸速率与5 cm土壤温度之间均呈显著指数相关,模拟方程分别为:y=0.120e0.094t(R2=0.882,P=0.000),y=0.291e0.069t(R2=0.858,P=0.000)。Q10值分别为2.56和2.01。