Fluctuations of the soil environment and fine root growth in a young Sitka spruce plantation

Summary From soil cores extracted at 5 day intervals from 3 May to 6 August it was found that the biomass of fine roots in a Sitka spruce plantation, 14 years old, fluctuated with maxima in late May and mid July. The earlier peak coincides with increasing soil temperatures during a period of high incident precipitation and the latter developed when the soil profile was rewetted. Fine root biomass and soil moisture tension (SMT) were significantly and negatively correlated in three of four soil horizons. Root mortality occurred whenever incident precipitation failed to maintain soil moisture tension near zero. In the very open pored horizons the critical SMT for root death was unexpected small, <0.1 bars; in the peat horizons it wasc 0.2 bars.     

土壤水分胁迫对设施番茄根系及地上部生长的影响

为了研究土壤水分胁迫对番茄生长的影响,以番茄‘金粉2号’(Jingfen 2)品种为试材,于2013年5—8月间在南京信息工程大学可控试验温室设计正常灌溉(T1)、轻度胁迫(T2)、中度胁迫(T3)、重度胁迫(T4)4个土壤水分处理,观测不同处理番茄植株根系及地上部分的生长状况。结果表明:不同处理的番茄根系生长指标(根系总长度、总表面积、总平均直径、根尖数)的最大值均表现为:T2T3T1T4,比较峰值发现,T2、T3和T4的根系总长度分别为T1的1.8、1.0和0.4倍,总表面积分别为T1的2.3、1.1和0.4倍,总平均直径分别为T1的1.3、1.1和0.6倍,根尖数分别为T1的1.1、1.0和0.5倍;T1、T2和T3处理的番茄根系均集中分布在5—10 cm土层内,而在T4处理下根系集中分布在15—25 cm土层内;番茄的株高、茎粗和叶面积指数大小表现为:T1T2T3T4,T2、T3和T4的番茄株高分别比T1下降11.49%、28.6%和43.98%,茎粗以T4处理最低,为T1的73.57%,T2、T3和T4的叶面积指数分别为T1的81.33%、64.62%和43.37%,各处理间叶面积指数在5%水平下呈现显著性差异。相关分析表明,番茄地上部分和地下部分各项生长指标与土壤体积含水率呈正相关。研究认为轻度土壤水分胁迫对番茄植株地上部分的生长影响不显著,利于根系生长,中、重度土壤水分胁迫明显抑制了番茄植株地上部分的生长,降低根系在土壤中的分布层,研究为设施番茄水分管理提供科学依据。     

杨树人工林根际古菌群落随细根生长的演变

研究细根不同生长时期根际土壤古菌群落组成结构差异,对深入了解林木细根与土壤微生物互作关系具有重要理论意义.依据细根表面颜色,采集杨树一级细根不同生长时期(白色新生根、黄色成熟根、褐色衰老根)根际土壤并提取微生物总DNA,采用特异性引物对古菌16S rDNA V4-V5区进行扩增,利用Illumina MiSeq平台进行古菌高通量测序分析.结果表明: 新生根和衰老根根际土壤古菌群落操作分类单元(OTU)丰富度相似,而成熟根根际土壤古菌群落OTU数量较少.新生根和成熟根根际土壤共同含有134个OTU;成熟根和衰老根根际土壤共同含有87个OTU,新生根和衰老根根际土壤共同拥有90个OTU.α多样性分析表明,成熟根根际土壤古菌群落Chao1指数和ACE指数显著低于新生根和衰老根根际土壤,而衰老根根际土壤古菌群落Simpson指数和Shannon指数显著低于新生根和成熟根根际土壤.PERMANOVA分析表明,新生根和衰老根根际土壤古菌群落组成有显著差异.物种注释显示,杨树根际土壤共包含12个古菌属,其中新生根5个、成熟根10个、衰老根6个.β多样性指数表明,杨树根际土壤古菌群落相似度随着细根的生长逐渐下降,不同生长阶段细根根际土壤的古菌群落结构有较大差异.其中,占绝对优势的古菌为氨氧化古菌Candidatus_Nitrososphaera,其相对丰度超过70%.且随细根生长发育,该类古菌在根际土壤中的丰度呈现上升趋势,表明其可能与细根的生长发育关系密切.     

Factors controlling the timing of root elongation intensity in a mature upland oak stand

We examined the timing of root elongation intensity (REI) – the production of newly elongating roots measured in length per unit soil volume per unit time – in a mature white oak-chestnut oak forest in Tennessee, USA, over a 4-year period. We used a network of minirhizotrons to (1) examine environmental control of soil moisture and temperature over REI, (2) evaluate the control of phenology over REI (3) develop a multivariate regression equation using the variables of soil temperature, soil water potential and phenology to predict REI, and (4) delineate soil water potentials that were optimum for growth. Fifteen minirhizotron tubes were installed on the upper slope of an upland oak stand on Walker Branch Watershed in Oak Ridge, Tennessee. Measurements of REI were examined over three growing seasons in the upper 30 cm of the soil profile. Composited sets of data on REI, soil water potential, soil temperature and phenology were analyzed to determine the strength of relationships between the latter three variables and REI. There was no statistically significant relationship between REI and soil temperature during the growing season (March–November). The highly significant (p < 0.0001) relationship between soil water potential and REI was best described as log linear, using log₁₀ (-) vs. log₁₀ (REI). The correlation between a phenology index and REI was also highly significant (p < 0.0001), as the 24 highest REI levels occurred between late April and early August. Whereas soil water potential played a major role in controlling REI, our data indicate that at times phenologically related factors appeared to override environmental variables. The fact that REI generally peaked every year following completion of leaf expansion is congruent with the fixed shoot growth pattern of many temperate-zone deciduous tree species. In an attempt to explain the importance of phenology in controlling REI, we refer to the concept of `phenological programming'. This concept contrasts with more environmentally determinant explanations of the timing of root growth. Those theories cannot explain either our data or that of others, wherein, during late summer and early autumn, REI does not return to early summer rates, even though soil moisture and temperature conditions are equally, if not more, favorable. The particular type of `phenological programming' hypothesized in this study may be limited to mature deciduous trees exhibiting a fixed growth pattern of shoot expansion and growing in a temperate climate with a mid-summer drought period.     

Fine root growth phenology,production, and turnover in a northern hardwood forest ecosystem

A large part of the nutrient flux in deciduous forests is through fine root turnover, yet this process is seldom measured. As part of a nutrient cycling study, fine root dynamics were studied for two years at Huntington Forest in the Adirondack Mountain region of New York, USA. Root growth phenology was characterized using field rhizotrons, three methods were used to estimate fine root production, two methods were used to estimate fine root mortality, and decomposition was estimated using the buried bag technique. During both 1986 and 1987, fine root elongation began in early April, peaked during July and August, and nearly ceased by mid-October. Mean fine root ( 3 mm diameter) biomass in the surface 28-cm was 2.5 t ha^–1 and necromass was 2.9 t ha^–1. Annual decomposition rates ranged from 17 to 30% beneath the litter and 27 to 52% at a depth of 10 cm. Depending on the method used for estimation, fine root production ranged from 2.0 to 2.9 t ha^–1, mortality ranged from 1.8 to 3.7 t ha^–1 yr^–1, and decomposition was 0.9 t ha^–1 yr^–1. Thus, turnover ranged from 0.8 to 1.2 yr^–1. The nutrients that cycled through fine roots annually were 4.5–6.1 kg Ca, 1.1–1.4 kg Mg, 0.3–0.4 kg K, 1.2–1.7 kg P, 20.3–27.3 kg N, and 1.8–2.4 kg S ha^–1. Fine root turnover was less important than leaf litterfall in the cycling of Ca and Mg and was similar to leaf litterfall in the amount of N, P, K and S cycled.     

Stand fine root biomass and fine root morphology in old-growth beech forests as a function of precipitation and soil fertility

Only very limited information exists on the plasticity in size and structure of fine root systems, and fine root morphology of mature trees as a function of environmental variation. Six northwest German old-growth beech forests (Fagus sylvatica L.) differing in precipitation (520 – 1030 mm year^–1) and soil acidity/fertility (acidic infertile to basic fertile) were studied by soil coring for stand totals of fine root biomass (0–40 cm plus organic horizons), vertical and horizontal root distribution patterns, the fine root necromass/biomass ratio, and fine root morphology (root specific surface area, root tip frequency, and degree of mycorrhizal infection). Stand total of fine root biomass, and vertical and horizontal fine root distribution patterns were similar in beech stands on acidic infertile and basic fertile soils. In five of six stands, stand fine root biomass ranged between 320 and 470 g m^–2; fine root density showed an exponential decrease with soil depth in all profiles irrespective of soil type. An exceptionally small stand fine root biomass (<150 g m^–2) was found in the driest stand with 520 mm year^–1 of rainfall. In all stands, fine root morphological parameters changed markedly from the topsoil to the lower profile; differences in fine root morphology among the six stands, however, were remarkably small. Two parameters, the necromass/biomass ratio and fine root tip density (tips per soil volume), however, were both much higher in acidic than basic soils. We conclude that variation in soil acidity and fertility only weakly influences fine root system size and morphology of F. sylvatica, but affects root system structure and, probably, fine root mortality. It is hypothesized that high root tip densities in acidic infertile soils compensate for low nutrient supply rates, and large necromasses are a consequence of adverse soil chemical conditions. Data from a literature survey support the view that rainfall is another major environmental factor that influences the stand fine root biomass of F. sylvatica.     

土壤增温对杉木幼苗细根生长量及形态特征的影响

为了揭示杉木人工林对全球变暖的地下响应,在福建省三明市陈大国有林场开展杉木(Cunninghamia lanceolata)幼苗土壤增温试验,采用内生长环法探讨增温实验开始后第2年(2015年1月、7月取样)和第3年(2016年1月、7月取样)杉木幼苗细根生长量和形态特征(比根长,SRL;比表面积,SRA;组织密度,RTD)的变化。结果表明:(1)随着苗木的生长,土壤增温对细根生长量的影响趋势是先抑制,再无显著影响,最后促进。(2)土壤增温对细根形态特征的影响在不同取样时间有差异:土壤增温对7月份(夏季)取样的细根SRL或SRA有显著促进作用,对1月份(冬季)取样的细根SRL、SRA均无显著影响。(3)土壤增温对第二、第三次取样的1—2 mm细根RTD有促进作用。表明土壤增温对杉木幼苗细根生长量的影响与苗木生长阶段有关;同时苗木可通过细根形态的调整(增大SRL和RTD)以适应土壤增温引起的土壤资源变化和环境胁迫,维持自身的生长。     

Simulation model of soil compaction and root growth

Soil compaction is a widespread cause of reduced plant productivity. If the effects of soil compaction on plant growth are to be reproduced in simulation models, then the processes through which compaction reduces root elongation must be expressed mathematically and then tested against experimental data. The mathematical theory by which these processes may be represented is given in the accompanying article. In this article, the behavior of a simulation model based on this theory is tested against data for root growth and soil gas concentration recorded from soil columns of which the middle layers were compacted to different bulk densities. The model was able to reproduce the failure of the root system to penetrate the compacted middle layer within the period of the experiment when bulk density exceeded 1.55 Mg m^-3. The model also reproduced decreases in O₂ concentrations, and increases in CO₂ concentrations, in the atmospheres of the compacted layer and of the uncompacted layer below it as bulk density of the compacted layer increased. The simulated time course of O₂ and nutrient uptake and of O₂ concentrations in the compacted layer at different depths is presented and its consistency with experimental findings is examined. As part of a larger ecosystem model, this model will be useful in estimating site-specific effects of soil compaction on carbon cycling in agroecosystems.     

球囊霉素相关土壤蛋白与根系形态的相关性研究

球囊霉素相关土壤蛋白(GRSP)是丛枝菌根(AM)真菌菌丝分泌的糖蛋白,能够促进土壤团聚体的形成。多种因素影响GRSP的产量,植物根系形态是否通过碳素竞争机制影响GRSP产量目前尚不清楚。以Glomus mosseae的两个生态型菌株和红三叶草Trifolium repense为试材,通过砂培试验探讨宿主的根系形态与GRSP产量的相关性。发现接种AM真菌导致宿主细根的比例降低,粗根的比例增加,但对总根长和根表面积没有影响;侵染率和菌丝长度随着时间的延长而增加,菌株之间存在显著差异;接种AM真菌导致GRSP产量显著提高;GRSP产量与根系形态没有显著的相关性,但是与侵染率和菌丝长度显著相关。结果表明,尽管宿主根系形态建成和AM真菌都对碳素具有竞争关系,但是前者并没有抑制GRSP的形成,可能存在根系碳素分配的自调控机制。     

草地早熟禾草坪土壤水分动态与根系生长分布

对草地早熟禾草坪土壤水分动态和根系生长发育状况进行研究,结果发现不同土壤层次水分变化有所不同,0～15cm变化最大,15～30cm次之,30cm以下土层水分变化不大;草地早熟禾的根系生长呈现双峰曲线模式,5月中旬和8月中下旬总根量处于峰值;其主体根系主要分布在0～30cm土层内,占总根量的85%以上;根重密度随土层深度呈指数衰减关系,0～30cm土层下降幅度较大,30cm以下土层根重密度相差不大;在0～30cm土层内不同层次根量占总根量的比例在不同时期亦有差异,春秋季节10～20cm和20～30cm土层内根量比例较大,说明此时期主体根系分布在较深的土层;综合分析认为草地早熟禾草坪主要利用土壤浅层水分,在降雨较少的春秋季节,根系较深,适宜深层灌溉,在降雨频繁的夏季,根系较浅,适宜浅层灌溉。     

Asynchronicity in root and shoot phenology in grasses and woody plants

Phenology is central to understanding vegetation response to climate change, as well as vegetation effects on plant resources, but most temporal production data is based on shoots, especially those of trees. In contrast, most production in temperate and colder regions is belowground, and is frequently dominated by grasses. We report root and shoot phenology in 7‐year old monocultures of 10 dominant species (five woody species, five grasses) in southern Canada. Woody shoot production was greatest about 8 weeks before the peak of root production, whereas grass shoot maxima preceded root maxima by 2–4 weeks. Over the growing season, woody root, and grass root and shoot production increased significantly with soil temperature. In contrast, the timing of woody shoot production was not related to soil temperature (r=0.01). The duration of root production was significantly greater than that of shoot production (grasses: 22%, woody species: 54%). Woody species produced cooler and moister soils than grasses, but growth forms did not affect seasonal patterns of soil conditions. Although woody shoots are the current benchmark for phenology studies, the other three components examined here (woody plant roots, grass shoots and roots) differed greatly in peak production time, as well as production duration. These results highlight that shoot and root phenology is not coincident, and further, that major plant growth forms differ in their timing of above‐ and belowground production. Thus, considering total plant phenology instead of only tree shoot phenology should provide a better understanding of ecosystem response to climate change.     

耕作播种方式对稻茬小麦根系发育、土壤水分和硝态氮含量的影响

2016—2018年,以深旋耕播种模式为对照,研究了浅旋耕播种和免耕带旋播种模式对稻茬小麦根系发育、土壤水分和硝态氮含量的影响。结果表明: 孕穗期以前免耕带旋播种和浅旋耕播种处理耕层土壤含水量高于深旋耕播种处理,而硝态氮含量低于深旋耕播种处理。拔节和开花期根重密度和根表面积密度处理间差异不显著。2016—2017年,3种耕播方式的产量和地上部分氮吸收量无显著差异;2017—2018年,免耕带旋播种和浅旋耕播种处理的产量较深旋耕播种分别增加10.9%和10.5%,地上部分氮吸收量分别增加17.5%和12.0%。与深旋耕播种和浅旋耕播种处理相比,免耕带旋播种处理播种效率高、断垄率低。综上,免耕带旋播种处理可提高稻茬小麦的播种质量,增强土壤保墒能力,降低氮淋溶风险,促进产量和环境效益的协同提升。     

Productive phenology of tropical montane forests: Fertilization experiments along a moisture gradient

Phenological responses of leaves and roots were studied in the tropical montane forests of Mount Kinabalu, Borneo. Soil nutrient supply, in addition to the supply of light and water, is a potential abiotic factor influencing plant phenology in the tropics. The main objective of this study was to evaluate the contribution of soil nutrient supply to plant productive phenology. Fertilization experiments, including controls, nitrogen fertilized and nitrogen and phosphorus fertilized treatments, were conducted on three vegetation types in different moisture environments. Responses of leaves and roots were compared among treatments and among vegetation types. Leaf flushing was induced by nitrogen fertilization in the upper montane forest, where extremely wet moisture conditions are associated with cloud cover. This induction of leaf flushing by fertilization was not observed in the other forests. Root growth was suppressed by fertilization when leaf flushing was not induced by fertilization. These results indicate that soil pulsed nutrient release could be a cue for leaf flushing in a tropical wet environment, and that leaf phenology could be regulated by external abiotic factors and root phenology could be regulated by internal plant demands.     

Modelling the effect of varying soil water on root growth dynamics of annual crops

We present a simple framework for modelling root growth and distribution with depth under varying soil water conditions. The framework considers the lateral growth of roots (proliferation) and the vertical extension of roots (root front velocity). The root front velocity is assumed to be constant when the roots descend into an initially wet soil profile. The lateral growth of roots is governed by two factors: (1) the current root mass or root length density at a given depth, and (2) soil water availability at that depth.Under non-limiting soil water conditions, the increase in root mass at any depth is governed by a logistic equation so that the root length density (R _v) cannot exceed the maximum value. The maximumR _v, is assumed to be the same for all depths. Additional dry matter partitioned to roots is initially distributed according to the current root mass at each depth. As the root mass approaches the maximum value, less dry matter is partitioned to that depth.When soil water is limiting, a water deficit factor is introduced to further modify the distribution of root dry matter. It is assumed that the plant is an energy minimiser so that more root mass is partitioned to the wetter regions of the soil where least energy will be expended for root growth. Hence, the model allows for enhanced root growth in areas where soil water is more easily available.Simulation results show that a variety of root distribution patterns can be reproduced due to varying soil water conditions. It has been demonstrated that broad patterns of root distribution reported in the literature can also be simulated by the model.     

No-tillage effects on soil properties and maize (Zea mays L.) production in Western Nigeria

Summary The grain yields in the no-tillage plots were equivalent to those of conventionally plowed treatments. No-tillage treatments had higher organic matter content and, by controlling soil erosion, the silt and clay content than the plowed plots. The water holding capacity and moisture release characteristics of the surface soil horizon were significantly different for the two tillage treatments. A decrase in the maximum soil temperature and favourable moisture regime in the no-tillage plots stimulated biological activity e.g. earthworms. While the fertilizer had no response on the plowed plots, irrigation had a negative effect due probably to severe leaching losses. No-tillage techniques have a potential in achieving continuous cultivation on otherwise highly erodible and shallow tropical soils.     

Influence of pastoral fallow on plant root growth and soil physical and chemical characteristics in a hill pasture

Pastoral fallowing over a growing season (October–May) has a profound effect on standing biomass and sward structure, and should have an impact on below ground plant growth and soil biological activities. Two field studies were conducted to compare the effects of pastoral fallow with rotational grazing on root growth and soil physical and chemical properties. Root growth and distribution was altered by pastoral fallowing and there was significantly (P < 0.01) less root biomass at 0–50 mm depth of soil in the fallowed sward than the grazed sward. Compared with the grazed treatment, pastoral fallow increased soil air permeability at 500 mm tension by 38%, saturated hydraulic conductivity by 26%, unsaturated hydraulic conductivity at 20 mm tension by 67% and soil moisture by 10–15%, and reduced soil bulk density by 11%. Fallowing had little effect on soil nutrients both at the end of fallowing, except for small reductions in K and Mineral N levels at 0–75 mm soil depth, and two to three years after fallowing.     

Drip irrigation,soil characteristics and the root distribution and root activity of olive trees

A study was carried out on the root distribution and root activity of the olive tree (Olea Europaea, L., var. manzanillo) as influenced by drip irrigation and by several soil characteristics such as texture and depth. The experiments were conducted in two plots within a drip-irrigated grove of 20-year-old trees planted at 7×7 m spacing. One soil was a sandy loam, the other a clay-loam. Both cylinder and trench methods were used to determine root distribution. Labelling with ³²P was used to determine root activity. Under dryland conditions the adult tree adapted its rooting system, following the installation of a drip system, by concentrating the roots within the wet soil zones near the drippers. The highest root densities occur in those zones, down to a 0.6 m depth, the most abundant being the <0.5 mm diameter roots. The most intensive root activity was also found in that zone. For a given irrigation system, wet soil bulbs are more extensive and therefore root distribution expands to a larger soil volume when the soil is more clayey and with a hard calcareous pan present at about 0.8 m depth which prevents deep drainage.     

黑色地膜覆盖对旱地玉米土壤环境和植株生长的影响

针对渭北旱塬地区使用普通白色地膜导致玉米生长出现的早衰、减产等问题,2012—2013年开展了黑色地膜覆盖、白色地膜覆盖和裸地玉米栽培试验,系统分析了黑色地膜对土壤温度、水分和玉米生长的影响。结果表明,黑色地膜与白色地膜的土壤保水效果相同,均使0—120cm土壤水分含量显著(P0.05)高于裸地对照。与白色地膜覆盖相比,黑色地膜覆盖能够有效降低0—15 cm土壤白天温度,可以使白天0—15cm土壤日地温平均降低0.8℃。黑色地膜覆盖后,玉米的籽粒灌浆期延长,吐丝后单株干物质积累量快速增加。玉米生殖生长期较裸地栽培延长2—3 d,成熟期单株干物质积累量增加18.11%;较普通白色地膜覆盖玉米生殖生长期延长2 d,成熟期单株干物质积累量提高7.31%。黑色地膜覆盖玉米产量和水分利用效率显著提高(P0.05),较白色地膜分别提高10.36%和10.40%,较裸地对照分别提高22.11%和25.28%。在旱地春玉米区,用黑色地膜代替普通白色地膜,对促进玉米增产具有一定的可行性。     

陇中黄土高原主要造林树种细根生物量分布

以2 mm为粗、细根的划分界限,采用根钻法对黄土高原安家沟流域油松、白杨、山杏、刺槐、沙棘和柠条6个主要造林树种细根分布进行研究,并测定不同林地下土壤含水率和土壤理化性质.结果表明： 在水平方向上,油松细根生物量呈先增大后减小的二次多项式分布,其他5个树种细根生物量均呈对数分布,水平根系发达,细根主要分布在冠幅半径2~3倍的范围内,表明各植被通过水平扩展来获取更多的土壤水分.在垂直方向上,随着土层深度的增加,细根生物量均呈减小趋势.6种植被细根生物量与土壤水分、容重呈显著负相关,与有机质、全N含量呈显著正相关.     

Effect of cyclic wetting and drying of a soil on root hair growth of maize roots

The objective of this study was to investigate the effect of cyclic soil wetting and drying on maize (Zea mays L.) root hair growth. Three soils, Chalmers silty clay loam (Typic Haplaquolls), Raub silt loam (Aquic Argiudolls) and Aubbeenaubbee sandy loam (Aric Ochraqualfs) and two soil moisture contents, −175 (M₀) and −7.5 kPa (M₁), were used to study root hair growth in a controlled-climate chamber. Increasing soil moisture after 7d from M₀ and M₁ resulted in a cessation of root hair growth behind the root cap while drying the soil after 7d from M₁ and M₀ promoted root hair growth on new but not old or existing roots. By maintaining liquid continuity under cyclic wetting and drying of a soil, root hairs may be of far greater significance to the nutrition of the plant than originally thought. Journal Paper No. 11023, Purdue Univ. Agric. Exp. Stn., W. Lafayette, IN 47907. Contribution from the Dep. of Agron.