Coastal vegetation structures and their functions in tsunami protection: experience of the recent Indian Ocean tsunami

This study explored the effects of coastal vegetation on tsunami damage based on field observations carried out after the Indian Ocean tsunami on 26 December 2004. Study locations covered about 250 km (19 locations) on the southern coast of Sri Lanka and about 200 km (29 locations) on the Andaman coast of Thailand. The representative vegetation was classified into six types according to their habitat and the stand structures of the trees. The impact of vegetation structure on drag forces was analyzed using the observed characteristics of the tree species. The drag coefficient, including the vertical stand structures of trees, C _d-all, and the vegetation thickness (cumulative trunk diameter of vegetation in the tsunami direction) per unit area, dN _u (d: reference diameter of trees, N _u : number of trees per unit area), varied greatly with the species classification. Based on the field survey and data analysis, Rhizophora apiculata and Rhizophora mucronata (hereafter R. apiculata-type), kinds of mangroves, and Pandanus odoratissimus, a representative tree that grows in beach sand, were found to be especially effective in providing protection from tsunami damage due to their complex aerial root structure. Two layers of vegetation in the vertical direction with P. odoratissimus and Casuarina equisetifolia and a horizontal vegetation structure of small and large diameter trees were also important for increasing drag and trapping floating objects, broken branches, houses, and people. The vertical structure also provided an effective soft landing for people washed up by the tsunami or for escaping when the tsunami waves hit, although its dN _u is not large compared with R. apiculata-type and P. odoratissimus. In addition, the creeks inside mangroves and the gaps inside C. equisetifolia vegetation are assumed to be effective for retarding tsunami waves. This information should be considered in future coastal landscape planning, rehabilitation, and coastal resource management.     

Water status of Hinoki cypress (<Emphasis Type="Italic">Chamaecyparis obtusa</Emphasis>) under reduced hydraulic conductance estimated from diurnal changes in trunk diameter

To estimate the water status of Hinoki cypress (Chamaecyparis obtusa) under reduced hydraulic conductance, we measured diurnal changes in the trunk diameter of two 20-year-old trees during a hot dry summer. One tree showed a greatly reduced water-transport area in its trunk cross-section and leaf specific hydraulic conductivity. Diurnal changes in trunk diameter were measured at the xylem surface using a strain-gauge method. At the start of the experiment, the diurnal changes in trunk diameter were similar in both trees with shrinking during the day and swelling at night. However, in the trunk of the tree with reduced hydraulic conductance, the maxima and minima decreased rapidly as days passed. These differences in trunk diameter changes might be caused by the differences in the leaf-specific hydraulic conductance.     

Scaling of tree height and trunk diameter as a function of ring number

 Phipps (1967) showed, in suppressed maples and oaks, that on average the cross-sectional area of successive tree rings is independent of ring number. From that empirical result I argued that mean ring width and mean ring diameter scale as the inverse square root and square root, respectively, of ring number (Prothero 1997). Here I give an illustrative argument as to how macroscopic trunk variables may be related quantitatively to microscopic ring variables. First, evidence is presented consistent with the theory of Greenhill (1881) and the empirical evidence of McMahon (1973) that tree height in a diversity of species scales as about the two-thirds power of trunk diameter. Here I report further evidence bearing on the same question. From these combined results I suggest that tree height, and by implication trunk height, and other parameters governing macroscopic tree trunk proportions, can all be expressed as powers of a microscopic variable, namely ring number, where the scaling exponents are all proper fractions. I suggest that at least one of these relationships is, in principle, non-adaptive. Received: 9 June 1998 / Accepted: 4 February 1999     

Development of a Compatible Taper Function and Stand-Level Merchantable Volume Model for Chinese Fir Plantations

Chinese fir (Cunninghamia lanceolata [Lamb.] Hook) is one of the most important plantation tree species in China with good timber quality and fast growth. It covers an area of 8.54 million hectare, which corresponds to 21% of the total plantation area and 32% of total plantation volume in China. With the increasing market demand, an accurate estimation and prediction of merchantable volume at tree- and stand-level is becoming important for plantation owners. Although there are many studies on the total tree volume estimation from allometric models, these allometric models cannot predict tree- and stand-level merchantable volume at any merchantable height, and the stand-level merchantable volume model was not seen yet in Chinese fir plantations. This study aimed to develop (1) a compatible taper function for tree-level merchantable volume estimation, and (2) a stand-level merchantable volume model for Chinese fir plantations. This “taper function system” consisted in a taper function, a merchantable volume equation and a total tree volume equation. 46 Chinese fir trees were felled to develop the taper function in Shitai County, Anhui province, China. A second-order continuous autoregressive error structure corrected the inherent serial autocorrelation of different observations in one tree. The taper function and volume equations were fitted simultaneously after autocorrelation correction. The compatible taper function fitted well to our data and had very good performances in diameter and total tree volume prediction. The stand-level merchantable volume equation based on the ratio approach was developed using basal area, dominant height, quadratic mean diameter and top diameter (ranging from 0 to 30 cm) as independent variables. At last, a total stand-level volume table using stand basal area and dominant height as variables was proposed for local forest managers to simplify the stand volume estimation.     

Changes in hydraulic conductance of citrus trees following a reduction in wetted soil volume

Abstract The effcct of the transition from fully to partially wetted soil voluine on transpiration rate and hydraulic conductance of mature citrus trees was examined in a 23-year-old, coninicrcial, sprinklerirrigated, Shanio u t i orange orchard. I rriga t i on frequency was determined by the rate of water loss from the soil, a s measured by neutron probes. The hydraulic conductance of tlic tree was coniputed from the rclationship between sap flow i n the trunk and leaf water potential. The diurnal valucs of leaf water potential and sap flow shifted towards lower levels as tlie water stored in the root zone was depleted. In the fully wetted soil volume the tree hydraulic conductance remained constant throughout the irrigation period, from June to Novcniber. However, partial wetting of the soil volume (40%) caused a reduction in the hydraulic conductance of the tree. Tlie decreased hydraulic conductance is attributed to tlie permanent interruption of water transport in part of tlie root system. Tlie rcsults of tlie experiment suggest that despite tlie increase of irrigation frequency, partial wetting intensifies water stress in tlie trees.     

Stilt Root Structure in the Neotropical Palms Iriartea deltoidea and Socratea exorrhiza1

Many arborescent palms develop a stilt root cone that provides increased mechanical support on steep hillsides, better root aeration under waterlogged conditions, resprouting after mechanical damage, and rapid stem elongation. However, for most species the role of stilt roots is not well understood. We determined how palm size and slope inclination affected the structure of stilt roots in the neotropical palms Iriartea deltoidea and Socratea exorrhiza. We expected palm height to be lower on steep slopes because the effectiveness of root support could decrease as slope inclination increases, and thus, the structure of the root cone would vary mostly with slope. Alternatively, if stilt root development is determined by palm size, their production should match stem height, with taller palms having larger cones. We measured the stilt root cone of 31 Iriartea and 36 Socratea palms in San Ramón Biological Reserve and Golfito Wildlife Refuge, Costa Rica. We divided the cone into five variables (horizontal projections of the cone base and stilt root height up and down the slope, and width of the cone base), from which we extracted the first two principal components and used them to measure the effects of slope and palm size on stilt root structure. We found stilt roots to be determined by palm size, not by slope conditions. Stilt roots matched palm size, with larger palms having taller and larger cones, maintaining stability under diverse slope conditions.     

Drought alters the canopy architecture and micro-climate of Hevea brasiliensis trees

 In this study a comparison of the canopy architecture and the growth and distribution of roots was made in 10-year-old trees of Hevea brasiliensis grown in a severely drought-prone area on the west coast of India under rainfed and irrigated conditions. LAI and light interception increased significantly in the irrigated compared to the rainfed trees. Girth and height of the tree were 29 and 19% more while width and height of the canopy were 19 and 20% more in the irrigated than rainfed trees. There were 22% more primary branches which had 26% more diameter in the irrigated trees than rainfed trees. The branches were inserted on the main trunk at an angle of 58.36° in the irrigated and 44.22° in rainfed trees. The above changes led to more light penetration which altered the light distribution inside the rainfed trees during summer and inhibited leaf photosynthesis particularly in the top canopy leaves. In the rainfed trees most of the growth occurred during the short favorable season immediately after the monsoon between June and October and no growth or even shrinking of the trunk was seen during summer. In the irrigated trees a higher growth was seen throughout the year and summer had no adverse effect. Although there was some difference in the root distribution pattern, the total root density per unit soil volume did not vary between the irrigated and rainfed trees. Key words  Hevea brasiliensis· Drought · Crown architecture · Micro-climate · Root growth Received: 8 May 1998 / Accepted 8 October 1998     

Allometry and stilt root structure of the neotropical palm Euterpe precatoria (Arecaceae) across sites and successional stages

The lack of secondary meristems shapes allometric relationships of the palms, influencing species segregation according to their capacity to adjust form and function to spatial and temporal changes in environmental conditions. We examined the stem height vs. diameter allometry of Euterpe precatoria across environmental gradients and measured how terrain inclination and palm size affected stilt root structure at two sites in Costa Rica. We dissected the root cone into eight variables and used principal component analysis to summarize their correlation structure. The fit of the stem diameter-height relationship to the stress, elastic, and geometric similarity models was examined using data from 438 palms. Terrain inclination did not affect stilt roots, whose structure was determined by palm size. Palms under 1 m showed geometric similarity, whereas palms above 1 m had slope values that were one and a half times higher, independent of successional stage, and did not adjust to any mechanical model. Taller palms departed from these models when they were large because they had stilt root support. We conclude that height in E. precatoria is constrained by structural support at the base and that diameter at the base of the stem and stilt roots balances height increments over all the size ranges examined.     

Vegetative Life History of a Dominant Rain Forest Canopy Tree1

Tetramerista glabra has a remarkable combination of life history traits. It is a dense-wooded, large, common canopy tree in primary peat swamp rain forest. Its seedlings, although shade tolerant, can grow rapidly in high light conditions, but frequently lack structural stability. Most juvenile stems (94% in the understory and 38% in canopy gaps) collapse under their own weight or from branchfalls. Fallen stems then ramify into vegetative sprouts, which in turn may collapse, perpetuating a vegetative juvenile cycle. Most recruitment is from sprouts rather than from seed. Structural analysis of stem dimensions shows that stems 2–8 cm DBH (diameter at breast height) are close to the theoretical buckling limit, especially for those dependent on neighboring vegetation to maintain vertical form. Trees > 4 cm DBH persisting as upright stems develop stilt root support and become structurally independent at ca 8 cm DBH. Eventually, as stems thicken, stilt roots anastamose and trees adopt the cylindrical growth form of mature canopy trees (up to 150 cm DBH). Thus, the vegetative life history strategy of the species is to: (i) regenerate a large “ramet bank” from the majority of juveniles that fail structurally while suppressed in the understoty, and (ii) to maximize height growth at the expense of diameter growth in high light conditions. The growth pattern and plastic form of T. glabra shows how a shade tolerant species may adapt to utilize the ephemeral light resource in canopy gaps. The growth strategy of this species allows it to circumvent the normal trade-off between shade tolerance and rapid growth in canopy gaps.     

Developmental patterns of above-ground hydraulic conductance in a Scots pine (Pinus sylvestris L.) age sequence

Hydraulic resistance to water flow was measured in branches and stems of Scots pine trees ranging from 7 to 59 years of age in Thetford (East Anglia, UK). On the basis of these measurements, tree above-ground conductance was calculated and related to the amount of leaf area sustained by each tree. Branches at the crown bottom had a lower proportion of sapwood area and a lower total hydraulic conductance than branches of the same diameter at the tree top. Within branches, most of the hydraulic resistance was located near the needles. Tree above-ground conductance was positively related to tree diameter and inversely related to tree height. Compared with young trees, mature trees had about 4 times less above-ground conductance per unit of leaf area. Apparently, the increase in pathway length associated with tree height growth could be only partially compensated for by the increase in conductive capacities resulting from diameter growth. We argue that this reduction may account for reported decreases of stomatal conductance with tree age. It is suggested that the increase in branchiness associated with tree maturation may represent a compensation mechanism to reduce the overall resistance to water flow in the crowns.     

Safety and efficiency conflicts in hydraulic architecture: scaling from tissues to trees

Tree hydraulic architecture exhibits patterns that propagate from tissue to tree scales. A challenge is to make sense of these patterns in terms of trade-offs and adaptations. The universal trend for conduits per area to decrease with increasing conduit diameter below the theoretical packing limit may reflect the compromise between maximizing the area for conduction versus mechanical support and storage. Variation in conduit diameter may have two complementary influences: one being compromises between efficiency and safety and the other being that conduit tapering within a tree maximizes conductance per growth investment. Area-preserving branching may be a mechanical constraint, preventing otherwise more efficient top-heavy trees. In combination, these trends beget another: trees have more, narrower conduits moving from trunks to terminal branches. This pattern: (1) increases the efficiency of tree water conduction; (2) minimizes (but does not eliminate) any hydraulic limitation on the productivity or tissue growth with tree height; and (3) is consistent with the scaling of tree conductance and sap flow with size. We find no hydraulic reason why tree height should scale with a basal diameter to the two-thirds power as recently claimed; it is probably another mechanical constraint as originally proposed. The buffering effect of capacitance on the magnitude of transpiration-induced xylem tension appears to be coupled to cavitation resistance, possibly alleviating safety versus efficiency trade-offs.     

鸡公山风景区针阔混交林藤本植物在树干不同方位的依附规律北大核心CSCD

为了揭示森林藤本植物在树干表面的分布规律,在鸡公山风景区的枫香(Liquidambar formosana)-马尾松(Pinus massoniana)针阔混交林内,采用样方法和定量调查法分析了以气生根为攀缘策略的络石(Trachelospermum divaricatum)在枫香和马尾松树干表面不同方位分布的数量差异。结果表明,络石在枫香和马尾松树干不同方位的分布状况因树高而异。在枫香树干基径(5 cm)处,西北方位附着的络石数量(6.6 ind./tree)显著高于东北方位(4.6 ind./tree)和东南方位(4.3 ind./tree);在胸径(130 cm)处,西南和东南方位附着的络石数量则显著高于西北方位;络石在基径和胸径处的死亡率均表现为南侧低,北侧高。在马尾松基径处,西北方位的络石具有最高的死亡率(35.1%),导致存活数量最少(4.6 ind./tree);胸径处则东南方位络石最多;并且南侧的络石死亡率低于北侧。因此,络石在攀缘林木不同方位的分布存在显著差异,且与树干高度和林木胸径密切相关,这是树干微环境和藤本植物自身生理特征共同作用的结果。     

木荷树干夜间水分补充的季节动态及其与树形特征和叶片生物量的关系

利用热消散探针(TDP)法对位于中国科学院华南植物园的木荷(Schima superba)人工纯林的15株样树进行了树干液流监测, 并结合光合有效辐射(PAR)和土壤含水量的测定, 探讨了不同季节的夜间水分补充量与树形特征和叶片生物量的关系。结果表明: 1)夜间液流活动时间与PAR同步, 但其结束时间不受PAR影响; 春、夏季夜间液流明显比秋冬季活跃。2)春、夏、秋季的夜间水分补充量与样树的胸径、冠幅、边材面积、叶片生物量呈极显著线性关系, 与树高仅在春季呈显著线性关系。3)春、夏季的夜间水分补充量主要受样树冠幅影响, 成正相关; 秋季主要受胸径影响, 成正相关; 冬季仅受树高影响。该试验说明木荷夜间水分补充与树形特征、叶片生物量关系密切, 但起主要作用的树形特征和具体关系具有季节差别。     

Comparison of Trunk and Branch Sap Flow with Canopy Transpiration in Pecan

Trunk and branch sap flow were compared with canopy transpirationin a 5-year-old pecan tree (Carya illinoensis ‘Wichita’).Total trunk sap flow, measured by a heat balance trunk flowgauge, was 122.8 kg over a 24 h period, corresponding closelyto the 113.4 kg of canopy transpiration measured by a largeprecision weighing lysimeter. Branches, less than half the diameterof the main trunk, had a total sap flow an order of magnitudeless than the total flow in the trunk. Sap flow in a branchwith a northern exposure was 41% less than that with a southernexposure. When sap flow was normalized per unit tree or branchleaf area, peak sap flow in the south branch matched that inthe main trunk. Tree transpiration and the sap flow in trunkand branches began concurrently, indicating little dynamic waterstorage in the trunk above the gauge. The hydraulic conductanceof the entire tree was 8 to 14 x 10^–14 m s^–1 Pa^–1,similar to values found for a number of woody and herbaceousspecies. Key words: Sap flow, Carya illinoensis, transpiration, lysimeter, trunk flow gauge     

不同中间砧木对寒富苹果生长、产量和果实品质的影响

本研究以10个矮化中间砧木嫁接的寒富苹果为试材,分析了不同矮化中间砧对葫芦岛产区的寒富苹果生长、产量和果实品质的影响,以期为葫芦岛产区选配优良的苹果砧穗组合。结果表明: 不同矮化中间砧对寒富苹果生长势、产量和果实品质指标的影响存在显著差异,株高、枝量、叶片鲜重、枝条鲜重、根鲜重、根系总体积、根系平均直径和总根尖数均以GM256嫁接树最高,基径、枝长、根系总长度和总表面积以CX5嫁接树最高;果实硬度、可溶性固形物和可溶性糖含量以M26嫁接树最大,果实纵径、横径和单果鲜重均以GM256嫁接树最大。采用模糊评价法综合评价显示,在葫芦岛地区,10种中间砧木嫁接寒富苹果的综合性状得分由高到低排序为: GM256、CX5、B9、JM7、CG80、辽砧2号、M26、青砧3号、SH38、MD001。建议GM256和CX5可作为冷凉气候区理想的矮化砧木。     

Effects of root architecture, physical tree characteristics, and soil shear strength on maximum resistive bending moment for overturning Salix babylonica and Juglans ailanthifolia

Effects of root architecture, physical tree characteristics, and soil shear strength on overturning moment due to flooding were investigated using Salix babylonica and Juglans ailanthifolia, exotic and invasive plants in Japanese rivers. Tree-pulling experiments that simulated flood action were conducted, and the resulting damage was examined to assess the effects of physical tree characteristics and root architecture on the maximum resistive bending moment (M _max) for overturning. In situ soil shear strength tests were conducted to measure soil strength parameters. The effects of species differences on the M _max were examined by analyzing root architecture. S. babylonica has a heart-root system that produces a greater overturning moment due to the strong root anchorage and the large amount of substrate that must be mobilized during overturning. J. ailanthifolia has a plate-root system that produces a smaller overturning moment. However, trees with the plate-root system may withstand overturning better due to an increased root:shoot ratio. The results of the study show that the M _max of a tree for overturning had significant (P < 0.05) correlations with a tree’s physical characteristics, including height (H), trunk diameter at breast height (D _bh), D _bh², height multiplied by the second power of D _bh (trunk volume index H × D _bh²), and root–soil plate depth (R _d), and root–soil plate radius (R _r). Considering the strategy of J. ailanthifolia to increase the root:shoot ratio for anchoring in the substrate, the trunk volume index (H × D _bh²) is a better parameter than D _bh² because it indirectly involves the difference in below-ground volume and surface area. Different soil cohesion values were found at different experimental sites, and the average M _max for overturning each species decreased linearly with increasing soil cohesion.     

Linking physiological processes with mangrove forest structure: phosphorus deficiency limits canopy development, hydraulic conductivity and photosynthetic carbon gain in dwarf Rhizophora mangle

Spatial gradients in mangrove tree height in barrier islands of Belize are associated with nutrient deficiency and sustained flooding in the absence of a salinity gradient. While nutrient deficiency is likely to affect many parameters, here we show that addition of phosphorus (P) to dwarf mangroves stimulated increases in diameters of xylem vessels, area of conductive xylem tissue and leaf area index (LAI) of the canopy. These changes in structure were consistent with related changes in function, as addition of P also increased hydraulic conductivity ( K _s), stomatal conductance and photosynthetic assimilation rates to the same levels measured in taller trees fringing the seaward margin of the mangrove. Increased xylem vessel size and corresponding enhancements in stem hydraulic conductivity in P fertilized dwarf trees came at the cost of enhanced midday loss of hydraulic conductivity and was associated with decreased assimilation rates in the afternoon. Analysis of trait plasticity identifies hydraulic properties of trees as more plastic than those of leaf structural and physiological characteristics, implying that hydraulic properties are key in controlling growth in mangroves. Alleviation of P deficiency, which released trees from hydraulic limitations, reduced the structural and functional distinctions between dwarf and taller fringing tree forms of Rhizophora mangle .     

Estimating the heights and diameters at breast height of trees in an urban park and along a street using mobile LiDAR

Because trees can positively influence local environments in urban ecosystems, it is important to measure their morphological characteristics, such as height and diameter at breast height (DBH). However, measuring these data for each individual tree is a time-consuming process that requires a great deal of manpower. In this study, we investigated the feasibility of using mobile LiDAR to estimate tree height and DBH along urban streets and in urban parks. We compared measurements from a mobile LiDAR unit with field measurements of tree height and DBH in urban parks and streets. The height-above-ground and Pratt circle fit methods were applied to calculate tree height and DBH, respectively. The LiDAR-estimated tree heights were highly accurate albeit slightly underestimated, with a root mean square error of 0.359 m for the street trees and 0.462 m for the park trees. On the other hand, the estimated DBHs were moderately accurate and overestimated, with a root mean square error of 3.77 cm for the street trees and 8.95 cm for the park trees. Densely planted trees in the park and obstacles in urban areas result in “shadows” (areas with no data), reducing accuracy. Irregular trunk shapes and scanned data that did not include full data point coverage of every trunk were the reasons for the errors. Despite these errors, this study highlights the potential of tree measurements obtained with mobile terrestrial LiDAR platforms to be scaled up from point-based locations to neighborhood-scale and city-scale inventories.

     

华南地区常见树种导管特征与树干液流的关系

为探讨树木结构与功能的关系,对华南地区常见8种树木边材的导管特征进行观察,并利用Granier热扩散探针法测量干、湿季树干的液流密度,分析导管特征与树干液流的关系。结果表明,除红锥(Castanopsis hystrix)有两种导管外,大叶相思(Acacia auriculaeformis)、荷木(Schima superba)、火力楠(Michelia macclurei)、藜蒴(C.fissa)、马占相思(A.mangium)、柠檬桉(Eucalyptus citriodora)、尾巨桉(E.urophylla×E.grandis)的导管类型单一。导管特征在种间存在明显差异,且导管长度、密度和孔径之间存在明显相关性,它们与标准化的边材面积呈现显著相关。湿季液流最大值与导管特征无明显相关性,但整树最大蒸腾速率与导管特征呈显著相关;树木的日蒸腾量与导管特征也有明显相关性。因此,树木的液流速率并不受树干的导管影响;而树干的导管孔径与边材面积间的负相关权衡机制,可以降低树种间由于导管孔径差异引起的树干的水分输送速率的差异性。     

Stocks and dynamics of carbon in trees across a rainfall gradient in a tropical savanna

In this study, systematic variation in tree morphology across a rainfall gradient in Australia's tropical savanna biome and its implications for carbon stocks and dynamics were quantified. The aim was to support efforts to manage fire regimes to increase vegetative carbon stocks as a greenhouse gas mitigation strategy. The height of trees for a given trunk diameter declines with decreasing rainfall from 2000 to 300 mm and increasing dry season length across the Australian savanna biome. It is likely that increasing dry season length is the main driver of this decline rather declining rainfall per se. By taking account of the response of total basal area to rainfall and soil type, stand structure, and tree height and diameter relationships, the carbon stocks in live trees were estimated to decline from about 34 t ha^?1 in the wetter savannas to 6 t ha^?1 in the drier savannas. These values are broadly consistent with field‐based estimates. Because of the declining ratio of height to trunk diameter, trees of a given diameter in drier regions will be more likely to be killed by fires of a given intensity than trees in wetter regions. Thus single fires of given intensity are likely to have a greater proportionate impact on live tree carbon stock in drier savannas, but a much greater absolute impact in wetter savannas due to the greater total carbon stock. Projected decreases in early wet season rainfall under climate change scenarios, despite projections of little change in total precipitation in northern Australia, may lead to decreased carbon stock in live trees through two mechanisms: a reduction in total basal area and decreases in tree height for given trunk diameters.