Abstract
The aim of this study was to evaluate the effect of thinning intensity and different harvest types on ecosystem P conservation in 20-year-old Pinus taeda plantation ecosystems at Misiones province, Argentina. The plantation was established in 1985, thinned at three intensities—0, 33, and 66% of basal area of control plots removed by thinning—and harvested in 2005. The nutrient content at harvest was determined for tree, shrub, and herb layers, the forest floor and upper mineral soil. Two harvest types were simulated: stem only and whole tree. Total P content was 56.8, 46.8, and 38.6 kg· ha−1 for 0, 33, and 66% thinning, respectively. Total P exported by harvest was different among treatments, the highest at 0% thinning treatment. Phosphorus stability index values indicated that the P most conservative management option is 66% thinning, harvest of stem only and retention of forest floor, understory, and harvest residues.
1. Introduction
Pinus taeda L. (loblolly pine) is the most widely planted tree species in Argentina [1]. Misiones, with a subtropical humid climate, is the province having the largest planted area with 300,000 ha [2]. Plantations are established mostly on deep red soils of the order Ultisols [3] where the main fertility problems are associated with low availability of P and K [4, 5].
Thinning reduces stand density favoring dominant trees and those with better form, increases the growth rate of retained trees, and results in stands with uniform tree diameters. These are important features in managing fast-growing plantations [6] and providing the increase of the remnant stand basal area to obtain more volume of quality wood at the end of the rotation [7, 8].
Thinning also influences ecosystem development [9], including modifying the availability and use of light, nutrients, and water for trees [10] and also affecting the understory [11]. Despite the fact that the understory represents a small fraction of total biomass, dependent on plantation basal area [12], it may act as an important nutrient repository in the plantation ecosystem [13]. This is supported by observations which show differences in ecosystem nutrient content between unthinned and thinned plots [14] at the end of a rotation.
Intensively thinned plots have higher sun energy inputs to forest floor, modifying site conditions for decomposers and speeding up decomposition [15–21]. The result is a reduction of organic matter accumulated on the forest floor. Harvesting causes the greatest nutrient losses [22] and can change the C balance [23] including changes in decomposition conditions. Additionally, nutrient losses can increase with inappropriate management of plant residues during site preparation for a new plantation [24]. These losses affect the remnant nutrient content [25] and nutrition of pines [26] because soils cannot supply the high-nutrient-demanding fast-growing species [27], and, consequently, the productive capacity of the site diminishes during the following several rotations [28].
Nutrient export at harvest of high-density 20-year-old P. taeda plantations at Misiones results in plantation stability index values that indicate P deficiencies after 1.2 rotations [25]. This result suggests that nutrient management decisions are crucial to sustain the productive capacity of sites during consecutive rotations.
In Misiones, unthinned 15-year-old P. taeda stands can accumulate a maximum of 518 m3·ha−1 (stem wood + stem bark) in trees of 24.4 cm mean DBH. Intense thinning (66% of basal area) diminishes total volume (to 433 m3·ha−1) improving product quality through mean DBH increase to 46.1 cm [29].
In Misiones, the first rotation of Pinus species were established on high productivity sites [30]. At present, plantations in these sites are finishing the second rotation, and, therefore there is a need for techniques that can sustain the productivity of these soils and the expression of the potential high growth of the new pine type obtained through genetic improvement [31].
The objective of this study was to evaluate the effect of three thinning intensities and two different harvest types on phosphorus (P) conservation in 20-year-old Pinus taeda plantations.
2. Materials and Methods
2.1. Site and Stand Description
Field work was done in a private estate located in the province of Misiones, Argentina (25°59′S, 54°24′ W). Soil is a Kandiudult [3], a red soil with m depth profile, a sequence of horizons A-Bt-C, without stoniness or big rock fragments, moderate permeability, and well drained. Mean annual temperature is 21°C, and the precipitation regime is isohydric with ca. 2000 mm·y−1 [32].
P. taeda (Marion origin) was established using 1644 pl·ha−1 in 1985. In 1991, the plantation was thinned reducing the stand density to 894 pl·ha−1. In 1993, an intensity thinning assay was installed using a randomized complete block experimental design with 3 blocks and 3 low-thinning treatments: control (0%), intermediate intensity (33%), and strong intensity (66%) for the basal area of control (29.2, 40.8, 46.6, and 47.2 m2·ha−1 at 8, 12, 16, and 20 y, resp.). The thinning from below treatments were repeated in 1997 and 2001, leaving plant canopy residues on site and harvesting the stems. The P in stems, exported during thinning, was 3.3 and 5.3 kg·ha−1, respectively, for 33 and 66% thinning intensity. The final size of each of the 9 plots measured was 806 m2. In 2005, harvest was done in plots with a density of 711, 364, and 122 pl·ha−1 for the thinning treatments 0, 33 and 66%, respectively, with a mean diameter at breast height (DBH) of 28.7, 34.6, and 45.9 cm, respectively. Each harvested tree was inventoried and DBH measured with callipers and height with hypsometers.
Phosphorus content was calculated for each layer (arboreal, shrubs, and herbaceous), the forest floor and the mineral soil at each treatment plot.
The understory of un-thinned plots was mainly of Gramineae with dominance of Olyra latifolia L. Additionally, there were some Blechnum brasiliense Desv. ferns. Thinned plots with a reduction of 66% had a heliophilous grass lower strata (Paspalum sp.) and an upper understory mainly with Setaria poiretiana (Schult) Kunth, Cecropia pachystachya Trécul young trees and lianes of the genera Mikania.
2.2. Aboveground Biomass
The weight of trees was obtained by dimensional analysis [33]. A total of 45 trees were felled, 15 at each treatment,5 per plot replicate. Trees were separated into the following compartments: stem (without bark), stembark, branches >5 cm diameter, branches <5 cm diameter, dead branches, leaves, and cones. The tree trunk length and diameter were measured in total and by sections to obtain volume. The most frequent section length was 3.5 m. However, the lower sections with wider diameters were 4.3 m according to commercial product destination. Stem biomass per tree was calculated multiplying volume per wood density of different sections and adding them. Wood density was determined by the volumetric method employing a modified version of IRAM 9544. We used wood probes of 2 × 2 × (X) cm where the height (X) of the probe varied according to the size of the cross-section sample units obtained in the field for this purpose. Sample units were obtained from each of the trunk sections. A total of 2700 probes were employed with around 60 probes per tree from axial and longitudinal positions. The probes were saturated with water and its volume determined according to the Archimedes principle submerging the probes in distilled water into precipitation flasks and employing a precision balance. Finally, the probes were dried in an oven at 100 ± 3°C and the density was determined as the quotient dry weight/volume. Bark dry weight was calculated taking into account its mass percentage in different stem sections. Branches, needles, and cones were separated and weighted fresh in the field. Samples of these compartments were obtained and dried at 70°C before weighing. Dry weight/fresh weight ratios were applied to field obtained fresh weights to obtain the dry weight of each felled tree compartment. Double-logarithmic regressions were developed (lnB = a + b * ln DBH) for each tree compartment. Later, they were applied to each inventoried tree individual to estimate the aboveground tree layer biomass.
Aboveground biomass of shrub layer was harvested in 90–2 m² quadrats, 10 per each one of the 9 plots of trees. Shrubs were separated into leaves and woody compartments. The aboveground biomass of the herbaceous layer was harvested in 90–1 m² quadrats, 10 per each one of the 9 plots of trees. Shrub and herbaceous compartments were dried at 70°C before weighing.
2.3. Forest Floor Necromass
Forest floor litter was collected in 90–0.25 m2 quadrats, 10 per each of the 9 plots of trees. Fine litter was collected in L and H + F layers (sensu Hesselman 1926 cited by Pritchett, [34]). Woody detritus was also collected as a third compartment. All samples were dried at 70°C to constant weight.
2.4. Soil Sampling
One composite sample formed by 8 sub-samples was obtained at each plot from horizon A (0–10 cm) and BA (10–30 cm), respectively. Five single samples per plot were collected from horizon B (30–60 cm) [35].
Bulk density of each soil horizon was determined by the cylinder method [36]. Undisturbed soil samples were taken with steel cylinders of 92,37 cm3 volume and dried at 103 ± 2°C to constant weight. Bulk density was calculated as the dry weight/volume ratio. We used 8 single samples from horizon A and BA and 5 samples from horizon B [37].
2.5. Chemical Analysis and P Content of Plants and Soil
Tree biomass samples were obtained from each plant: for the small compartments, aliquots were obtained from the total of the compartment and fragmented when woody and hard (e.g., cones), and for the trunk and big branches aliquots from different diameter, sections were mixed without a precise proportional mass weighting and fragmented to small chips. The dried herbs and shrubs were homogenized, and aliquots were taken for analysis. The vegetation and litter samples from each compartment were grinded in a Wiley mill using a 0.5 mm mesh. A total of 370 tree samples were chemically analyzed. Phosphorous extraction was done using acid digestion with a mix of nitric-percloric acid to free inorganic and organic P. Phosphorous concentration was determined through induced plasma emission spectrometry using an ICP-AES" [38]. Phosphorus content at each compartment, layer, and plot was obtained multiplying the biomass or necromass for the mean P concentration of the respective compartment.
Available P on the mineral soil horizons was determined by Bray and Kurtz method [39]. Phosphorus content to 60 cm depth was calculated as the sum of the products of bulk density per P concentration at each soil horizons.
2.6. Phosphorus Exports and Indices
To estimate P exports at final harvest of both types, the biomass and P mineral mass (equal to P content in the respective biomass) from the involved compartments were employed: (1) stem only (SO): sum of contents in stem + stembark of tree layer and (2) whole tree (WT): sum of contents in all aboveground compartments of tree layer.
For both harvest types, the phosphorus export index (EI) was calculated as the harvested biomass/P mineralmass ratio [40]. The nutrient stability index of plantation (SIP) was calculated as the ratio of the exported P content/soil available P content [41]. Two calculations were applied considering different storages of P immediately available to plants: option (1): Mineral soil available P and option (2): Sum of mineral soil available P, plus P in forest floor, plus P in understory biomass and in harvest residues of tree layer.
2.7. Statistics
The means of biomass of compartments and layers, necromass of forest floor compartments, soil horizon bulk density, and P concentration and content of layers of vegetation, forest floor and mineral soil from treatments, were compared through ANOVA. When differences were significant, treatments means were compared with the Tukey test. In both analyses, the significance level used was 95% [42]. We report probability results into three categories: , (when and <.05), and . The software used was INFOSTAT version 2010.
3. Results
3.1. Biomass and P Content of Vegetation Layers
Total and stem, bark and branches <5 cm biomass, and mass of dead branches were significantly different () among thinning intensity treatments (Figure 1). Leaf biomass did not show significant differences among thinning treatments (). A decreased trend was observed for leaf biomass when thinning intensity increased (Figure 1). Phosphorus concentration in tree compartments were not significantly different () among thinning treatments. The comparison test among compartments means (for trees) defined three groups in the following order: needles > cones > branches < 5 cm + stem + branches > 5 cm + bark + dead branches.
Phosphorous content in the tree layer was significantly different () among thinning treatments (Table 1). The stem compartment accumulated the main P percentage with 75, 73, and 68%, in 0, 33, and 66% intensity of thinning, respectively.
The shrub layer biomass was 0.26, 0.70, and 5.29 Mg·ha−1 for 0, 33, and 66% thinning, respectively. The value for 66% thinning was significantly different () from the other two. Phosphorous concentration was not different () among treatments, and consequently P content changed in proportion to biomass accumulation (Table 1).
The herbaceous layer biomass (1.33, 1.25, and 1.07 Mg·ha−1 for 0, 33, and 66% thinning, resp.) and P concentration (1.27, 1.37, and 1.61 mg·g−1 for 0, 33, and 66% thinning, resp.) and content did not differ significantly among treatments (; Table 1).
3.2. Phosphorous Content of Forest Floor and Mineral Soil
Forest floor necromass totaled 25.0 (±8.2), 18.3 (±5.5), and 16.6 (±4.1) Mg·ha−1, for the 0, 33 and 66% thinning, respectively, without significant differences () among treatments as also shown for the P concentration and content (; Table 1). Phosphorus concentration in forest floor compartments increased top-down: fine woody detritus (0.19, 0.20, and 0.31) < L layer (0.32, 0.30, and 0.26) < H + F layer (0.55, 0.44, and 0.52), for 0, 33, and 66% thinning, respectively. Comparing the same compartments, differences were not significant for P concentrations among treatments ().
The mineral soil bulk density and concentration of available P were not different among treatments (). Mean concentration of available P for all treatments was 2.16, 0.83, and 0.40 ppm for A, BA, and B horizons, respectively. Available P content to 60 cm depth is reported in Table 1 and soil bulk density in Table 2.
3.3. Phosphorous Content and Management of Plantation Ecosystem
At the end of rotation period, total ecosystem P content showed an inverse relationship with thinning intensity. Differences were significant () among the 66% thinned plots and the 0 and 33% thinned plots treatments (Table 1).
Understory, due to shrubs, increased its percentage of P storage with the increase in thinning intensity. The P content at 66% thinned plots was fivefold (16.3% of total available P) of that of 0% thinned plots (control treatment with 3.3% of total available P; Table 1).
Phosphorous mass exported at final harvest in both harvest types (SO and WT) was different among treatments ( (SO and WT)). Phosphorus remaining at the site after harvest did not change significantly with thinning intensity ( (SO and WT)); Table 3). The harvest system WT exported 10.9, 9.5, and 8.1 kg·ha−1 more P than its similarly thinned from harvest system SO, respectively, for the thinning treatments 0, 33, and 66%, showing significant differences for the three treatments ().
The highest wood biomass harvested per unit P exported was obtained with the SO harvest type and a thinning intensity of 66%, as shown by EI in Table 4. The most P conservative scenario for a site was obtained when 66% thinning, and SO harvest was combined with the retention in the ground of organic debris from forest floor, damaged understory, and harvest residues as shown in option (2) of SIP.
4. Discussion
4.1. Biomass and P Content in the Plantation Ecosystem
The higher density of un-thinned (control) plantation favored the increase of intraspecific competition. As a consequence, trees in non-thinned treatment near rotation end had (1) a lower mean DBH (28.7, 34.8, and 45.9 cm in 0, 33, and 66% intensity of thinning, resp.), (2) suppressed individuals, (3) a reduced tree canopy size, and (4) a lower foliar biomass proportion (2.6, 3.7, and 4.3% in 0, 33, and 66% intensity of thinning, resp.). Similar results were reported elsewhere [43, 44]. For example, a 17-year-old P. taeda plantation from a West Gulf Coastal Plain site in Louisiana, that was thinned ca. 15% of BA at 7 and 14 y, increased the plantation mean DBH and length of the canopy suggesting that stand density management is important to induce vigor and potential growth of trees [44]. Moreover, foliar percentage in canopy was higher in thinned plantations with a proportional increase of 4.6% at 17-year-old [44]. In another site, with a different environment and lower growth rates, a plantation thinned 40% of BA significantly increased its biomass and canopy components with respect to control, 12 y after thinning [7].
On the opposite side, the lower competition in intermediate and strongly thinned plots (33 and 66%) allowed for a better expression of the hereditary plant architecture of the species with a greater development of individual canopy, a larger mean DBH of trees near final cut time and the highest biomass of plantation canopy. Several studies coincide in these trends [44–47]. For instance, a summary of 7 research studies about the production dynamics of intensively managed P. taeda from Southern USA reported thinning as one of the best strategies to increase productivity and monetary value of stands [47]. In this sense, thinned plots showed features found in non-full-stocked forest sites [48, 49]. Relative to P, different P contents among thinned plots and control have been reported in other studies [14].
Although it is not significant, the consistent trend toward a lower leaf biomass (and then LAI) with thinning increase suggests a lower capacity of strongly thinned non-full-stocked stands to capture available sunlight at rotation end as found in another study [47]. From a silvicultural point of view, 66% thinning may be excessive for wood production because it results in incomplete use of available resources and lower yields [29]. At the other extreme, the highest proportion of dead branches observed at 0% thinning may be due to a lower half-life, early mortality, and temporal delay of branch fall at tree canopy due to growth under strong competition conditions. Decreased canopy parameters in un-thinned plantations have been reported elsewhere [43, 44].
Phosphorus concentration values found in aboveground tree biomass compartments were similar to other reported in Misiones [50]. Accordingly, P concentration accomplished through the same concentration trend: leaves, fine branches, and fruits had higher P concentration than stem and coarse branches as generally observed in woody plants [17, 25, 51–53]. However, P concentration in leaves from this study was lower than in the same compartment and species reported for different sites in the USA [54]. This may be related to low P availability in soils of the region herein studied [5], taking into account that thinning intensity did not affect soil density (Table 2), and, consequently, P content was similar among treatments. Low P concentration in leaves and branches <5 cm influenced P content in both compartments with an added maximum of 29% of total P content in the tree layer. Other studies report that both may sum up to 50% of total P content in trees [18].
Pinus taeda bark had 2 to 3% of P content in aboveground tree biomass, a value considered low for this compartment. Stembark separation from stem-only harvest type for leaving bark in the field is considered an important nutrient conservative practice for those species with a high nutrient content in bark [55]. In the present study, P content in stembark was 4.1, 4.5, and 3.3% of total P mass in stem only for 0%, 33%, and 66% thinning treatments, respectively. Then, avoiding bark retention at site appears to be a small P loss with harvest export [49]. Notwithstanding, it may be not left aside the bark role—as mulch and source of nutrients to the soil—for ecological management considering an adequate use of harvest residues and the relative contribution of bark P return with respect to the soil available P.
Creating canopy gaps through thinning induces changes in growth and composition of understory [11, 56, 57]. We found that shrubs benefited most from intense thinning as shown by the increase in shrub biomass and P mineralmass with increase in thinning intensity. As mentioned earlier, higher sunlight availability for lower layers may be one of the main factors triggering understory growth [43]. The 6.3 kg P·ha−1 stored in the understory is not far from the maximum of ca. 8 kg·ha−1 reported in the literature [58]. Understory may be a potential source of P after harvest [16] by clear cutting or thinning and also a P sink diminishing P losses from ecosystem [59].
The higher necromass in the forest floor of the un-thinned control was probably partially due to a lower half-life of canopy leaves. The leaf mass produced by the closed structure of these stands [60] reduces light available to plant organs in lower locations [43, 61], so favouring litter fall and litter accumulation in denser plantations [62]. The lower density in strongly thinned plots allows for higher energy inputs in the forest floor, and, together with other environmental variables, modifies site conditions for decomposers and stimulates faster decomposition rates [15–21]. Thus, it reduces organic matter storage in the forest floor. The trend found in this study and the attributed causes are similar to those reported by other authors [63–67].
The L and H + F layers are the result of several processes involved in inputs, outputs, and physical-chemical transformation of matter in the forest floor. The highest P concentration at H + F layer compared to L layer was probably caused by nutrient immobilization by microorganisms decomposing a nutrient-poor litter. Organic matter at H + F layer decomposed for a longer time than recent fallen material forming the L layer and, as microorganism tissues have a lower C/P ratio than litter; they progressively change nutrient stoichiometry of the organic particles-microorganisms complex [68]. Other studies obtained similar results [25, 69, 70].
Available P was only 0.5% of total P in soil, but, as total P to available P replenishment fluxes are unknown, it is not possible to infer the effect of thinning treatments in soil P concentration and content. Furthermore, some nutrients may be lost by lixiviation or immobilized in complex molecules or by competitors [71] after harvesting or a new plantation establishment [24]. In fact, better forestry practices should minimize the modification of sites, including the avoidance of soil nutrients losses to sustain fertility and long-term productivity.
4.2. Impact of Management on P Content of Plantation Ecosystem
Due to the high fraction of nutrients contained in canopy, the whole tree (WT) harvest type resulted in the highest exported mass of P as reported for other forestry species [72, 73]. As P is essential for plant growth and the main limiting nutrient in soils of the region [25], it is necessary to use harvest practices that minimize P losses with products extraction.
The percentages of P, with respect to total P in the ecosystem, exported with WT harvest type, were high (71, 67, and 55% for 0, 33, and 66% thinning, resp.), indicating that most ecosystem P is in trees and that the P percent losses depend on plantation density. The percentages of P were higher than those reported for another P. taeda plantation with lower density (437 pl·ha−1) where P output with harvest was ca. 50% of total P [74].
Phosphorus losses occur in short periods during and immediately after harvest and depend on both harvest type and thinning intensity during rotation. The P mass remaining in the ecosystem depends mainly on harvest type and conservative postharvest management. Comparison of equivalent SIP among harvest types for P. taeda showed that nutrient export with WT harvesting is 2-3 times greater than with SO, as has been reported elsewhere [75].
Understory plants concentrate and temporarily retain absorbed soil nutrients. Moreover, they are a source of labile organic matter able to release nutrients during decomposition. In fact, the positive impact of conserving organic matter from the understory, forest floor, and harvest residues as a source of P and other nutrients source was evident compared with the values of both SIP options (Table 4). The best combination of practices for more efficient use of P included 66% thinning intensity, harvest of stem only, and retention on site of organic matter from necromass and uncollected biomass compartments. This combination resulted in a SIP 12-times lower than the opposite most extreme combination of treatments (0% thinning, whole-tree harvest, and elimination of harvest residues).
Regardless of thinning treatment and harvest type, P remaining in the soil (available P in mineral horizons + P in forest floor + P in harvest residues) may not be sufficient to supply the needs of another rotation of the same species. However, since the index used does not consider P inputs to or outputs from the ecosystem during rotation (with the exception of those related to thinning and final harvest), we cannot accurately estimate the number of rotations that are sustainable. A previous study in Misiones identified at rotation end that P is one of the limiting elements in plantations of P. taeda [25]. The number of rotations that can be planted without nutrient replacement depends not only on tree harvests and the tolerance of the species towards soil changes but also on nutrient replenishment mechanisms of the soil and other losses not considered by the indices used in this work. If we suppose that replenishment of soil available P by total P is continuous until total P becomes exhausted, and taking into account that P is exported during thinning and harvests, the availability of P in the sites might be enough for 86 (SO) to 61 (WT) rotations, independently of the thinning intensity applied. This calculation demonstrates the importance of residue conservation during harvests (thinning and final) and emphasizes the need for research relating to changes in total and available P and the P cycle throughout the rotation in these stands.
5. Conclusions
This study demonstrates that silvicultural decisions regarding thinning intensity, harvest type, forest floor, and harvest residue conservation will influence biomass accumulation in trees and shrub understory and P content but will not influence P concentration in vegetation compartments or the capacity to sustain future rotations of Pinus taeda plantations in this region. Stem-only harvest is a better option than whole-tree harvest regarding P and probably other nutrients. Conservation of organic matter from the forest floor, understory, and harvest residues helps to supply P to soil and to reduce P losses. Consequently, the selection of postharvest practices to prepare land for a new plantation should include considerations on the effect on the above-mentioned compartments.
Our study shows that simple and sensitive indices can be useful for evaluating nutritional stability with regard to P and to the selection of management practices that balance wood production and nutrient conservation.
Acknowledgment
The authors thank LIPSIA SA for local support in the estate and the permission to use their plantations for this study.