Next Article in Journal
A 36-Year Assessment of Mangrove Ecosystem Dynamics in China Using Kernel-Based Vegetation Index
Previous Article in Journal
Phenotypic Variability of Juglans neotropica Diels from Different Provenances During Nursery and Plantation Stages in Southern Ecuador
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Forests
Volume 16
Issue 7
10.3390/f16071137
forests-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Modeling the Effects of Climate and Site on Soil and Forest Floor Carbon Stocks in Radiata Pine Stands at Harvesting Age

by
Daniel Bozo
1,2,†,
Rafael Rubilar
1,2,*,
Óscar Jara
1,2,
Marianne V. Asmussen
1,2,
Rosa M. Alzamora
2,3,
Juan Pedro Elissetche
2,3,
Otávio C. Campoe
4 and
Matías Pincheira
5
1
Cooperativa de Productividad Forestal, Departamento de Silvicultura, Facultad de Ciencias Forestales, Universidad de Concepción, Concepción 4030555, Chile
2
Centro Nacional de Excelencia para la Industria de la Madera (CENAMAD—ANID BASAL FB210015), Pontificia Universidad Católica de Chile, Santiago 7820436, Chile
3
Departamento de Manejo de Bosques y Medio Ambiente, Facultad de Ciencias Forestales, Universidad de Concepción, Concepción 4030000, Chile
4
Forest Productivity Cooperative, Departamento de Ciências Florestais, Universidade Federal de Lavras, Lavras 37200, MG, Brazil
5
Forestal Mininco S.A., Avenida Alemania 751, Los Ángeles 4440000, Chile
*
Author to whom correspondence should be addressed.
This work was part of the Ph.D. thesis of the first author Daniel Bozo.
Forests 2025, 16(7), 1137; https://doi.org/10.3390/f16071137
Submission received: 30 May 2025 / Revised: 1 July 2025 / Accepted: 8 July 2025 / Published: 10 July 2025
(This article belongs to the Section Forest Ecology and Management)
Browse Figures
Versions Notes

Abstract

Forests are a key terrestrial carbon sink, storing carbon in biomass, the forest floor, and the mineral soil (SOC). Since Pinus radiata D. Don is the most widely planted forest species in Chile, it is important to understand how environmental and soil factors influence these carbon pools. Our objective was to evaluate the effects of climate and site variables on carbon stocks in adult radiata pine plantations across contrasting water and nutrient conditions. Three 1000 m2 plots were installed at 20 sites with sandy, granitic, recent ash, and metamorphic soils, which were selected along a productivity gradient. Biomass carbon stocks were estimated using allometric equations, and carbon stocks in the forest floor and mineral soil (up to 1 m deep) were assessed. SOC varied significantly, from 139.9 Mg ha−1 in sandy soils to 382.4 Mg ha−1 in metamorphic soils. Total carbon stocks (TCS) per site ranged from 331.0 Mg ha−1 in sandy soils to 552.9 Mg ha−1 in metamorphic soils. Across all soil types, the forest floor held the lowest carbon stock. Correlation analyses and linear models revealed that variables related to soil water availability, nitrogen content, precipitation, and stand productivity positively increased SOC and TCS stocks. In contrast, temperature, evapotranspiration, and sand content had a negative effect. The developed models will allow more accurate estimation estimates of C stocks at SOC and in the total stand.

1. Introduction

The accumulation and stabilization of soil organic carbon (SOC) are critical components of global carbon (C) cycling and climate change mitigation [1]. Globally, forest ecosystems store approximately 861 Pg C, with over 40% sequestered in soils, often exceeding the C stored in aboveground and belowground biomass [2,3,4,5,6]. SOC represents a long-term carbon sink whose dynamics are modulated by various biotic and abiotic factors. These include stand age, vegetation type, soil characteristics, climate, and forest management [7,8]. Due to the growing interest in carbon neutrality and sustainable forest development, accurately quantifying and modeling of SOC is essential for national greenhouse gas inventories and implementing sustainable forest management practices. Therefore, accurate estimates and models of carbon stocks both in aboveground biomass (the most studied component) and in belowground components (which can represent over 60% of a stand’s C stocks depending on the soil type) [4,5,6] are essential.
In Chile, Pinus radiata D. Don is the most widely planted tree species, covering over 1.3 million hectares and constituting around 56% of the total area under plantation [9]. Due to its rapid growth, adaptability to various environmental limitations, and high productivity under intensive silvicultural practices, it dominates the Chilean forestry sector alongside Eucalyptus sp. plantations [9,10,11,12,13]. Numerous studies have investigated the productivity and aboveground carbon stocks of radiata pine stands, particularly with respect to biomass. However, research on forest floor and belowground carbon, particularly SOC, has received comparatively less attention, especially in mature stands [4,5,6,14]. SOC comprises a significant portion of the total ecosystem carbon, particularly in the deep mineral horizons which function as long-term carbon reservoirs [15,16]. Therefore, improving our understanding of SOC in intensively managed radiata pine plantations is crucial for optimizing national carbon budgets and developing site-specific management strategies.
The diversity of soil types in south-central Chile, ranging from volcanic ash in the Andes, sandy soils in the central valley, and granitic and/or metamorphic substrates in the Coastal Range and coastal zone, adds complexity to SOC assessments [4,17]. Volcanic ash soils, particularly Andisols, have been shown to exhibit high SOC retention. This phenomenon is attributed to the presence of amorphous minerals such as allophane, imogolite, and iron oxides. These minerals stabilize soil organic matter (SOM), the organic material embedded in mineral soil [18], leading to low bulk density and high carbon concentrations [19,20,21,22]. Conversely, sandy soils have low water holding capacity and limited nutrient availability. This characteristic accelerates SOM decomposition and reduces SOC storage [4,5]. Granitic soils, characterized by their coarse texture and limited nutrient-holding capacity [22], exhibit the potential to enhance long-term SOC accumulation through intensive forestry practices, such as fertilization. These practices promote vegetation growth and the accumulation of SOM [4,6]. Metamorphic soils, characterized by their complex mineral compositions, have been shown to exert a regulatory effect on the rate of SOM decomposition, thereby contributing to stabilizing the SOC [6]. Recent studies in southern and central Chile suggest that the carbon stocks in adult radiata pine plantations can vary by more than 40% depending on soil type [4,5,6]. This highlights the necessity of incorporating soil properties, such as soil texture, soil water holding capacity, and fertility, into the estimation of SOC to ensure precision and accuracy.
The variability of SOM and SOC is influenced by a combination of soil properties and climatic factors, as these elements affect microbial activity and the turnover rate of organic matter [18,23]. Climatic variables, particularly precipitation, temperature, and potential evapotranspiration, play a key role in forest growth, productivity, and biomass accumulation of forests [10,12]. Furthermore, they have been shown to influence the following: organic matter inputs to the soil, soil respiration, and the decomposition rates of SOM, affecting both the carbon dynamics in the forest floor and mineral soil [24]. Many studies have identified a negative correlation between mean temperature and C stock, while a positive correlation has been observed with annual precipitation [25,26,27]. For example, higher SOC stocks are typically observed in humid temperate regions than in warm zones due to slower decomposition of SOM and higher litter accumulation [4,8,15,28].
Although mineral soil is the main long-term carbon pool, the forest floor plays a crucial role in short-term carbon dynamics and nutrient cycling. It contributes organic matter to mineral soil from aboveground biomass. The forest floor is composed of accumulated leaf litter, decomposing woody material, and humus [29]. The structure and biomass of the forest floor are highly sensitive to environmental conditions, stand age, species, and soil fertility [4,18,30,31]. Volcanic soils often support thick, slowly decomposing organic layers, while sandy soils tend to have thinner, rapidly cycling litter layers [4]. However, not all studies reflect this trend, suggesting that soil types may interact with climatic factors in forest soil carbon stocks [5,32]. Integrating forest floor carbon evaluations with SOC assessments provides a more comprehensive understanding of total ecosystem carbon stocks and temporal dynamics.
In the current climate change context, where temperature increases and precipitation decreases are expected [33], it is especially important to understand how climate, soil, and site characteristics affect carbon stocks in forest plantations. In our study, we developed empirical models to estimate carbon stocks in the total biomass, the mineral soil (SOC), and the forest floor in sites with adult Pinus radiata plantations. We used environmental variables that can be easily acquired, as well as soil variables that were measured and sampled in situ, such as soil bulk density, texture, nitrogen content, and soil water availability. Field data were collected from plots in central Chile across soils of different parent materials (granitic, sandy, metamorphic, and recent ash), enabling us to calibrate predictive linear models for SOC at depths of up to 1 m. Our fitted models require data that can be easily collected in the field. Unlike other models, such as process-based models or spatially explicit models [34,35,36], ours do not require large amounts of input data. Our objectives were therefore to assess the aboveground and belowground carbon stocks in radiata pine plantations across four different soil types, and to model these carbon stocks in relation to climate and soil properties.

2. Materials and Methods

2.1. Study Area and Experimental Design

This study includes the sites presented and detailed by Bozo et al. [5] and Asmussen et al. [6]. In brief, twenty sites were selected to represent a productivity gradient of adult radiata pine plantations under intensive management at harvesting age (18–25 years old, the age at which radiata pine plantations are typically harvested in Chile) (Table 1 and Figure 1). These sites cover a significant portion of the productive area of radiata pine plantations in Chile [9]. The sites were located in central and south-central Chile, spanning from the Maule (35°25′ S) and Araucanía (38°54′ S) administrative regions, and from 72°58′ W to 71°43′ W from west to east. The altitudes ranged from 106 to 849 m above sea level. The soils were classified as coarse volcanic sand, granitic, metamorphic, and recent volcanic ash [17,37]. The selected stands at each soil site were planted between 1998 and 2004, with an initial planting density ranging from 1000 to 1250 trees ha−1.
Table 1. Site characteristics of selected locations that consider a range of productivity sites for contrasting sandy, granitic, metamorphic, and recent ash soils.
Table 1. Site characteristics of selected locations that consider a range of productivity sites for contrasting sandy, granitic, metamorphic, and recent ash soils.
SoilSoil Order aDBHHeightVHAAge
(cm)(m)(m3 ha−1)(Years)
SandyEntisol29.228.3333.822
SandyEntisol34.327.4431.421
SandyEntisol35.630.2470.822
SandyEntisol34.430.0517.523
SandyEntisol36.936.3625.423
GraniticInceptisol29.127.3363.019
GraniticInceptisol30.430.6397.920
GraniticUltisol34.225.8437.422
GraniticUltisol36.630.6574.621
GraniticInceptisol36.034.2669.825
Recent AshAndisol35.531.3387.621
Recent AshAndisol33.832.0432.221
Recent AshAndisol34.837.1512.620
Recent AshAndisol41.130.5549.122
Recent AshAndisol38.237.0646.323
MetamorphicEntisol27.722.7252.720
MetamorphicInceptisol29.727.1381.521
MetamorphicAlfisol32.030.0402.820
MetamorphicAlfisol35.830.2530.121
MetamorphicUltisol40.633.5690.425
a [38]. DBH = mean DBH (diameter at breath height, 1.3 m); Height = mean total height; VHA = mean stand volume (calculated as the DBH, Height, and VHA mean of three plots measured at each site.
Forests 16 01137 g001
Figure 1. Location of Pinus radiata D. Don stands evaluated by soil type and climate characteristics and soil water holding capacity. (a) Study area in central-south Chile (black frame); (b) sites and mean summer (January to March) temperature (°C, Sum. temp.); (c) sites and annual precipitation (mm yr−1, MAP); (d) sites and soil water holding capacity up to 1 m deep (mm, SWHC) [39].
Figure 1. Location of Pinus radiata D. Don stands evaluated by soil type and climate characteristics and soil water holding capacity. (a) Study area in central-south Chile (black frame); (b) sites and mean summer (January to March) temperature (°C, Sum. temp.); (c) sites and annual precipitation (mm yr−1, MAP); (d) sites and soil water holding capacity up to 1 m deep (mm, SWHC) [39].
Forests 16 01137 g001
Soil preparation for all sites included subsoiling to a depth of 60 cm and disking. Traditional operational fertilization was applied at a rate of 100 to 150 g per plant of an NPK mix (10 to 15 g of nitrogen, 10.9 to 13.2 g of phosphorus, and 8.3 to 12.5 g of potassium), plus 2 to 3 g per plant of boron after planting. Weed control operations considered the pre-planting total area and included two years of banded weed control after planting in most conditions. All selected stands were pruned to a minimum height of 5.5 m and thinned using one or two commercial thinning practices according to the silvicultural program applied to each site’s stand. Final stand stocking at harvest reached 400 to 500 trees ha−1.
Field measurements were conducted at sandy and volcanic ash soil sites between March and May 2022, and at granitic and metamorphic soil sites between May and November 2023. At each site, three 1000 m2 inventory plots were established to measure the diameter at breast height (DBH, in cm at a height of 1.3 m) and the total height (H, in m) of all trees. The forest floor and mineral soil were also sampled within each inventory plot. A total of 60 plots (15 plots per soil type) were measured across all sites.

2.2. Volume and Carbon Stocks of Above- and Belowground Biomass Estimations

We used individual tree measurements from each plot (considering the number of trees, DBH, and H) to estimate tree over bark volume (V, m3 tree−1). The calculations considered a local volume equation of individual trees developed by CMPC Forestal Mininco Company [40] (Equation (1)).
V = 0.00214 + 0.0000295 D 2 + 0.001349 H + 0.00002486 D 2 H
where V is the individual tree over bark volume (m3 tree−1), D is the DBH (cm), and H is the total height (m).
We estimated the aboveground biomass of each tree component (stem, bark, branches, and needles) using the allometric equations for radiata pine published by Sandoval et al. [41]. Then, we calculated the total aboveground biomass (AGB, kg tree−1) as the sum of each tree component’s biomass. We calculated the belowground biomass (BGB, kg tree−1) using the allometric equation for the radiata pine root component published by Zerihun and Montagu [42]. We estimated the carbon stock of the aboveground and belowground tree biomass by multiplying the AGB and the BGB by a carbon factor (CF), corresponding to the carbon fraction of the biomass. We used 0.48, as recommended by the IPCC [43].
Finally, individual plot stocking (NHA, trees ha−1), stand volume (VHA, m3 ha−1), aboveground biomass carbon stock (AGBC, Mg ha−1), and belowground biomass carbon stock (BGBC, Mg ha−1) were estimated by adding and scaling to a hectare level the numbers of trees per plot, individual tree volume, aboveground biomass carbon, and belowground biomass carbon. The sum of the last two estimates provided the total biomass carbon stocks (TBC, Mg ha−1).

2.3. Forest Floor Carbon Sampling and Calculations

Samples of the forest floor from the organic horizons (Oi, Oe, and Oa layers) were collected using a 25 cm diameter circular cutting frame (490.9 cm2) at ten systematically selected sampling points within each plot. At each point, litter (pine needles in all stages of decomposition) and coarse woody debris were collected separately. A total of 1200 forest floor samples were collected from all evaluated plots (20 sites × 3 plots × 10 sampling points × 2 forest floor sampling types). Each sample was stored in a labeled paper bag, and taken to the laboratory, where it was dried at 65 °C until it reached a constant weight. The dry weight of the litter and woody debris was recorded for each sample using a balance with a precision of 0.01 g. After weighing, the samples of each forest floor type (litter and woody debris) were composited and homogenized separately for each plot. Each pair of composite samples per plot was ground separately using a 250 μm sieve blade mill. Five-gram subsample aliquots were obtained for analyzing the carbon concentration in the litter and woody debris components of each plot.
The carbon stock of litter and coarse woody debris was determined by multiplying the dry biomass weight at each sample point by the average plot carbon concentration of each component (%), then expanding it to the hectare level (Mg ha−1) and averaging it for each plot. The total forest floor carbon stock (FFC) was finally estimated by summing the carbon stocks of the organic horizons and the coarse woody debris estimated from each plot.

2.4. Soil Properties and Organic Carbon Sampling and Calculations

Estimates of the organic carbon stock in the mineral soil (up to 1 m deep) were obtained by taking composite samples from 20 points distributed systematically within each plot. These composite samples were obtained using a soil auger at three depths: 0–20 cm, 20–40 cm, and 40–100 cm. A total of 180 composite mineral soil samples were obtained from all the evaluated sites in the study. The soil samples were air-dried at 30 °C, passed through a 2 mm sieve to remove all root and plant debris, and a 10 g subsample aliquot was taken and dried at 65 °C for 24 h, and then ground. Finally, a 5 g aliquot was obtained to determine the organic carbon (C) and total nitrogen (N) concentrations using an Infrared Mass Spectrometer analyzer (IRMS, SERCON Scientific Inc., Cheshire, UK) (Table 2).
At each site, a 1 m depth soil pit was dug to describe the visual characteristics of the soil profile. Bulk density (BD) samples were obtained using a 100 cm3 metal cylinder at depths of 0–20 cm, 20–40 cm, and 40–100 cm. Each soil sample was stored and taken to the laboratory, where it was dried at 65 °C until it reached a constant weight. A total of 60 soil bulk density samples were obtained from all the sampled sites. Additionally, a 0.5 kg bulk soil sample was taken at each sampled depth for subsequent Boyoucos soil texture analyses and to determine the soil organic matter (O.M.) content [44]. This sample was also used to estimate the permanent wilting point (PWP) and field capacity (FC) moisture retention curve points using a pressure plate apparatus (Soil Moisture Inc., Goleta, CA, USA). The soil water holding capacity (SWHC) for each soil sample was estimated as the difference between the PWP and the FC. Analyses of both forest floor and the soil were carried out in the Soil, Water, and Forest Research Laboratory (LISAB) at the Faculty of Forest Sciences of the University of Concepción, Chile.
The soil organic carbon stock at each depth (SOCd, Mg ha−1) was calculated by using Equation (2) [45]:
S O C d = C d D d B D d 1 δ d   0.1
where SOCd is the soil organic carbon stock at depth d (Mg ha−1), Cd is the soil organic carbon concentration at depth d (g kg−1), Dd is the soil thickness at depth d (cm), BDd is the bulk density at depth d (g cm−3), and δd is the proportion of rock fragments at depth d (>2 mm).
The total soil organic carbon stock (SOC) until 1 m of depth for each plot was calculated by summing the SOCd estimates at each depth.

2.5. Climate Data

Temperature, precipitation, and solar radiation data from 1995 to 2023 were acquired using Google Earth Engine (https://earthengine.google.com) (accessed on 15 May 2025) from the ERAS5 climate dataset [46]. This data was previously correlated and validated with climate stations close to each sampling site belonging to the Chilean government agencies, the Dirección General de Aguas (https://snia.mop.gob.cl/BNAConsultas/reportes) (accessed on 15 May 2025), and the Instituto de Investigaciones Agropecuarias, (https://agrometeorologia.cl/) (accessed on 15 May 2025). For precipitation we calculated cumulative annual precipitation (Pp). Vapor pressure deficit (VPD, mBar) was estimated using Equation (3) [47]:
V P D = 6.1078 e 17.269 T m a x 237.3 + T m a x ) 6.1078 e 17.269 T m i n 237.3 + T m i n ) 2
where VPD is the vapor pressure deficit (mBar), Tmax is the maximum daily temperature (°C), and Tmin is the minimum daily temperature (°C).
We estimated the reference evapotranspiration for each site using the method described by Hargreaves and Samani [48]. Finally, we calculated the soil water deficit index (SWDI) using Equation (4):
S W D I = P p E T + S W H C
where SWDI is the water deficit index during the year (mm year−1), Pp is the cumulative annual precipitation (mm year−1), ET is the evapotranspiration during a year (mm year−1), and SWHC is the soil water holding capacity (mm).

2.6. Canopy Estimates

The leaf area index (LAI) is a key ecophysiological parameter that is closely related to stand growth, productivity, and the physiological processes occurring within stand canopies [12,49,50]. Due to the strong correlation between LAI and the spectral vegetation indices (VIs) [51], we estimated VIs using Sentinel-2 images. We downloaded a one Level-1C Sentinel-2 image with less than 10% cloud cover from the Copernicus Open Access Hub online repository, that was acquired close to the carbon sampling date on each site.
We converted digital numbers (DN) from Sentinel-2 images to at-sensor spectral radiance [52] and then we calculated the top-of-atmosphere (TOA) reflectance [53]. Only bands 4 (Red: 0.665 µm) and 8 (near infrared band, NIR: 0.834 µm) of the multispectral images with a 10 m spatial resolution were used in this analysis. For each plot, we calculated two commonly used VIs: the simple ratio index (SR), which is calculated as (NIR/Red) [54], and the normalized difference vegetation index (NDVI), which is calculated as ((NIR − Red)/(NIR + Red)) [55].

2.7. Data Analysis

The total carbon stock (TCS) for each plot was estimated as the sum of the evaluated components: total biomass carbon (TBC), soil organic carbon (SOC), and forest floor carbon (FFC) stocks. We evaluated carbon stocks, stand volume, and soil properties for normality using a Shapiro–Wilk test (PROC UNIVARIATE) and a Levene’s test for heteroscedasticity. Data that were not normally distributed were transformed using a Box–Cox transformation (PROC TRANSREG). An analysis of variance (ANOVA) was performed (PROC GLM) to evaluate the effects of soil type on each above- and belowground component, total carbon stock, stand volume, and in the soil properties at each depth. When significant differences were detected (p < 0.05), a Tukey’s Honestly Significant Difference (HSD) test was applied for multiple comparisons among soil type means (LSMEANS was applied with the ADJUST = TUKEY option).
In the regression analysis, the carbon stocks (TBC, SOC, FFC, and TCS) were considered the dependent variables. The independent variables were grouped as follows:
  • Climate: solar radiation (Rad), mean annual precipitation (Pp), potential evapotranspiration (ETP), soil water deficit (SWD), soil water deficit index (SWDI), minimum temperature (Tmin), mean temperature (Tmean), maximum temperature (Tmax), mean vapor pressure deficit (VPDmean), and summer vapor pressure deficit (VPDsum).
  • Stand attributes: stand volume (VHA), simple ratio (SR), and normalized difference vegetation index (NDVI).
  • Soil properties: nitrogen content at 20 cm depth (N20); C:N ratio at 20 cm depth (CN20), C:N ratio at 1 m depth (CNm), percentage of clay at 20 cm depth (Clay20), percentage of sand at 20 cm depth (Sand20), percentage of sand at 1m depth (Sandm), and soil water holding capacity (SWHC).
  • Site: altitude (Alt), and distance from sea (Dist).
An exploratory analysis was performed to identify and remove outliers, defined as observations more than 2.5 times the standard deviation from the mean. A principal component analysis (PCA) was performed to avoid multicollinearity among possible predictor variables and to identify those that contributed significantly to variability (PROC PRINCOMP was applied with the STD option to standardize the data). Then, we performed a correlation analysis to evaluate the effect of the most relevant independent variables from the PCA on each dependent variable (carbon stock) (PROC CORR).
We then performed multiple linear regressions to examine the effects of the independent variables (climate, stand attributes, soil properties, and site) on each carbon pool (TBC, SOC, and FFC) and the total carbon stock (TCS). For each carbon pool, we adjusted the linear models in two steps. First, we fitted a complete model using all the variables selected from PCA and correlation analysis (PROC REG). Then, we used a stepwise process to fit a reduced model that included only significant variables (p < 0.05).
We evaluated and diagnosed the fitted models through graphical and analytical analyses to verify the assumptions of linearity (graphical analysis), normality (Kolmogorov–Smirnov test), homoscedasticity (Breusch–Pagan test), and residual independence (Durbin–Watson test). To identify the best model and compare the performance of each approach, we calculated the adjusted coefficient of determination (adj-R2), root mean square error (RMSE), and Akaike’s information criterion (AIC) values during the fitting process (PROC GLMSELECT). All statistical analyses and fitting procedures were carried out using SAS software (version 9.4, SAS Institute, Inc., Cary, NC, USA). All tests were considered significant at a level of α = 0.05.

3. Results

3.1. Physical and Chemical Properties of Evaluated Soil Types

Metamorphic, granitic, and sandy soil types exhibited the highest bulk density (BD) at all three depths of the soil profile compared to the recent ash soil site (p < 0.05) (Table 2). Meanwhile, the carbon (C) and nitrogen (N) content was highest in the recent ash and metamorphic soils at all depths compared to the other two soil types (p < 0.05). At the three evaluated depths, the recent ash soil type presented the lowest C/N ratio values. (Table 2). Metamorphic and granitic soils had the highest clay content throughout the soil profile, with the lowest mean values found in sandy soils. The sand content was greater than 70% in the sandy soil type at all three depths, increasing with depth (Table 2).

3.2. Variation in Carbon Stocks Among Soil Types and Their Relationships to Site Productivity

There were no significant differences in stand volume or total biomass carbon stock (TBC) among soil types (p = 0.66). However, the mean values indicated that TBC was slightly higher in recent ash soils than in metamorphic soils, which had the lowest TBC (Table 3). Metamorphic sites had the highest soil organic carbon (SOC) stocks up to 1 m deep. These stocks differed significantly from those of granitic and sandy soils (p < 0.05). Sandy soils had the lowest SOC stocks, and no significant differences were observed between them and granitic soils (Table 3). In the three soils with the highest SOC stock (granitic, recent ash, and metamorphic), SOC accounted for over 50% of the total carbon stock (TCS). The forest floor (FFC) carbon pool was the lowest carbon pool on all sites, with a higher FFC stock in granitic soils than in recent ash soils (p < 0.05). No differences in FFC were observed between the other soil types. At the total stand level, a similar trend was observed for total carbon stock (TCS) and SOC. Metamorphic sites had the highest TCS, differing significantly from granitic and sandy soils (p < 0.05). Sandy soils had the lowest TCS, and no significant differences were observed between them and granitic soils.

3.3. Selected Environmental Variables

Figure 2 shows that principal component analysis (PCA) accounted for 60.6% of the variability in the data. The first PCA component accounted for 39.8% of the variation. This component was strongly influenced by variables directly related to stand growth and productivity, such as stand volume, NDVI, precipitation, nitrogen content, and soil water availability. These variables were associated with ash and metamorphic soil types. There was a negative relationship between this axis and variables related to nutrient-poor soils and water stress, such as VPD, evapotranspiration, and sand content. The second PCA component explained 20.8% of the variability in the data. Variables related to water stress and nutrient-poor soils were clearly associated with sandy soil type, while those variables related to water availability and soil fertility were associated with the ash, granitic, and metamorphic types.
The PCA test reduced the dimensionality of the dataset that would be used as predictor variables and greatly reduced the multicollinearity of highly correlated variables. The PCA test revealed 11 continuous independent variables with high eigenvalues (Table 4). Additionally, soil type was considered a factor due to the clear grouping of plots between all soil types evaluated (p < 0.05). The PCA analysis revealed that the environmental, soil, and site variables associated with nutritional and water limitations (e.g., Tmean, VPD, ETP, and Sand20) were higher in the sandy soils. In contrast, the variables related to stand growth and productivity (e.g., NDVI, Pp, N20, and SWHC) were higher in the recent ash, granitic, and metamorphic soils.
Then, a correlation analysis was performed between all continuous variables derived from PCA, including both the predictor variables (climatic, soil, and site characteristics) and the dependent variable (all carbon pools) (Figure 3). Total biomass carbon stock (TBC) exhibited a clear, strong direct relationship with the stand volume (VHA) (r = 0.99, p < 0.001), due to the use of allometric equations for both estimates. Therefore, the VHA variable was excluded from subsequent multiple regression analyses for this carbon pool.
Correlation analyses revealed a direct relationship between the TBC, SOC, and TCS stocks and the variables related to stand productivity (such as Alt, NDVI, Pp, SWHC, SWI, and N20). However, negative correlations were found between these carbon stocks and the drought-related variables (Tmean, VPDmean, and ETP), as well as with limiting soil factors, such as sand content (Sand20). These results demonstrate the significant impact of variables related to soil fertility, available water, and stand conditions on the SOC and TCS of the stands. However, the FFC stock exhibited a significant positive correlation with stand volume (VHA), evapotranspiration (ETP), and sand content (Sand20). Nevertheless, the FFC stock showed a negative correlation with SWHC, suggesting a relationship with water-stress-related variables.

3.4. Modeling Carbon Stocks Using Climate, Soil, Stand, and Site Variables

To model the total biomass carbon stock (TBC), we first performed a full multiple linear regression analysis using all potentially predictive variables (excluding VHA, due to the use of allometric equations to estimate tree volume and biomass). Despite an R2 value of 0.47, the full model was not significant (p > 0.05). Then, using a stepwise process, we included five variables in the reduced model (p < 0.05): mean vapor pressure deficit (VPDmean), mean precipitation (Pp), potential evapotranspiration (ETP), soil water deficit index (SWDI), and sand content (Sand20) (Table 5 and Figure 4a).
We performed a full multiple linear regression analysis using all potentially predictive variables to model the forest floor carbon stock (FFC). As with TBC, the full model was not significant (p > 0.05) despite having an R2 value of 0.53. Then, we used a backward process to model the FFC, including three predictor variables in the reduced model (p < 0.001): stand volume (VHA), evapotranspiration (ETP), and soil water holding capacity (SWHC) (Table 6 and Figure 4b).
The full model was significant (p < 0.05) for estimating the soil organic carbon (SOC) stock, though not all the predictors were significant (p > 0.05). The most important variables in the model were those related to soil fertility and water availability, such as nitrogen content at 20 cm depth (N20), sand content, and soil water holding capacity (SWHC). N20 and sand content negatively affected SOC, while SWHC positively affected it. The next most important variables were those related to water stress, such as evapotranspiration (ETP) and mean temperature (Tmean), which had negative coefficients, and the normalized difference vegetation index (NDVI), which relates to stand productivity and had a positive coefficient. Then, we fitted a reduced model (p < 0.001) that included stand volume (VHA), nitrogen content (N20), and evapotranspiration (ETP) as significant environmental and soil property predictors to model SOC using a backward process (Table 7 and Figure 4c).
Finally, we performed a full multiple linear regression analysis using all the potentially predictive variables to model the total carbon stock (TCS). As with SOC, the model was significant (p < 0.05) and had a high R2 value of 0.85. However, not all the predictors were significant (p > 0.05). Then, we used a backward process to model the TCS using only the significant variables. This reduced model (p < 0.001) included the same three significant predictor variables as the SOC model: stand volume (VHA), evapotranspiration (ETP), and nitrogen content at 20 cm depth (N20) (Table 8 and Figure 4d).

4. Discussion

Similar to other studies, we found that high carbon stocks were present in the radiata pine plantations at pre-harvesting age, particularly in recent ash and metamorphic soils compared to sandy soil [4]. Our results showed that the stand carbon stocks in radiata pine plantations are strongly related to climatic variables and soil properties (Figure 2 and Figure 3). As in other studies, sites with lower water and nutritional limitations tended to have the highest SOC and total carbon stock [4,56].
Precipitation (Pp) and soil water available showed a high positive correlation with stand growth, biomass, and soil organic carbon (SOC) [10,12,25]. Water stress was a clear limiting factor in the accumulation of carbon accumulation in the evaluated radiata pine stands. Studies evaluating the productivity and growth of Pinus radiata D. Don stands in Chile have shown that environmental variables, such as Pp and available soil water, directly affect growth and leaf area index (LAI) across different sites, while the soil water deficit inversely affects both variables [10,12]. This is related to the correlation analyses for TBC (Figure 3 and Table 5), in which Pp, SWHC, and SWDI had a positive coefficient of correlation, indicating that an increase in water availability increases stand growth and biomass.
Conversely, the variables related to water stress, such as evapotranspiration (ETP), temperature (Tmean), and VPDmean, presented negative coefficients of correlation. These results are consistent with those of Olmedo et al. [4], who found that the most restrictive sites in terms of water availability had the lowest carbon stocks in above- and belowground biomass when evaluated by climatic zones. This indicates that, as observed in other studies, reduced water availability decreases LAI, and consequently, growth and biomass accumulation [10]. Temperature affects tree growth and decomposition and respiration rates. These factors impact on the forest productivity and the carbon capture into biomass, mineral soil, and the forest floor [8,26,57,58]. In a radiata pine plantation, a direct relationship was observed between an increase in soil respiration (CO2 flux) and temperature [59]. This could be related to the negative correlation between SOC and temperature in our study, which could be due to an increase in organic matter decomposition caused by this environmental variable [18].
The type of soil, specifically related to texture, has been described as a key factor in the stand growth [60], affecting the soil water available to the trees, and consequently, the accumulation of carbon in above- and belowground biomass. Similar to what was found by Olmedo et al. [4], soil organic carbon content and soil organic stock (SOC) were higher in metamorphic and volcanic ash soils than in granitic or sandy soils (Table 2 and Table 3). Our results, from both the correlation analyses and the fitted linear model (Figure 3 and Table 7), clearly indicate that SOC is positively influenced by variables related to soil nutrients and water storage (e.g., nitrogen, clay, and silt content), precipitation, and stand productivity (e.g., positive correlation with stand volume and LAI). According to our analyses, soil texture affects soil attributes such as water storage capacity (Table 2 and Table 4), soil carbon stock, and the stand growth, which is related to the total carbon biomass of the stand. Key characteristics that affect soil carbon in mineral soil include the aggregation of its particles, clay and silt content, and the mineralogy and specific surface area of clays [8,28,61]. These factors have different capacities for accumulation, stabilization, and protection of soil organic matter (SOM) [18,21,62]. Furthermore, clay content contributes to the retention and availability of water and nutrients in the soil, aggregation and formation of micropores, which promote the long-term accumulation of organic matter in the soil and improve stand productivity and soil carbon stock [24,63]. Our results and those of Olmedo et al. [4] and Crovo et al. [22], who evaluated the SOC in radiata pine plantations in Chile, suggest that due to the clay type and higher content of clay + silt content in recent volcanic ash, those soils store and maintain high levels of organic matter and available water over time [20,61,64]. Soils with recent volcanic ash soils, such as Andisols, contain secondary minerals, including short-range-order (SRO) minerals, such as allophane and imogolite [19]. These clay type and soil aggregates have a high specific surface area and variable charge. They provide physical and chemical protection and stabilization for SOM [8,21]. This evidence shows that Andisols are among the most productive soils in the world [65]. Conversely, soils with a high sand content have a lower potential for storing high soil carbon stocks due to their coarse texture, larger pore size, and lower water and nutrient availability, which affects stand productivity, as well as the speed of decomposition and storage of organic matter [4,66,67].
Accurately estimating this carbon stock is important because, in our study, it was the most important carbon pool for granitic, metamorphic, and recent ash soil sites, and the second most important carbon stock for sandy soil sites. Furthermore, many studies have found that SOC is the component with the highest proportion of the carbon pool in forests [4,68,69]. Therefore, a model that considers stand volume, fertility, and climate characteristics would be helpful in quantifying SOC up to one meter deep (Table 7 and Table 8, Figure 4). In our fitted models for SOC estimation, which combine soil characteristics, climate, and stand productivity, the predictor variables are easy and quick to obtain, allowing for good estimates of this carbon stock. As Paula et al. [28] indicated, climatic variables are important for estimating of carbon, but soil characteristics must also be considered to improve SOC estimates.
The lowest carbon stock in our study was found in the forest floor (FFC), and significant differences were observed among soil types (Table 3). In our study, the highest forest floor carbon stock was found in the granitic and sandy soil sites. Although these sites have higher mean temperatures than metamorphic and recent ash soil sites, they have less available water (Table 4). This could be related to the fact that greater aridity decreases the litter decomposition rates [70]. Therefore, in our evaluated sites, the higher SWHC and Pp in the metamorphic and recent ash sites could have affected the decomposition rates of the FFC, resulting in a lower carbon stock than in the granitic and sandy soil sites. Lower humidity and higher temperatures have been observed to decrease litter decomposition rates [71], due to reduced biological activity of soil organisms, which could explain the higher biomass in our granitic and sandy soil sites. In metamorphic and recent ash soil sites, organic matter can more quickly incorporate into mineral soil and become associated with and protected within aggregates or mineral clay particles [18]. López-Senespleda et al. [31] estimated forest floor carbon stocks in Spain, using linear and Random Forest models. They found significant climate and environmental variables similar to those in our study, such as precipitation and temperature. These variables have been reported to significantly impact decomposition rates of the forest floor [72,73,74]. Many studies have reported an increase in litter decomposition with increasing temperature and precipitation [72,75].
Furthermore, this carbon stock was the only one that weakly correlated with the stand productivity [5,6]. In many studies [4,31,76,77], the forest floor has the lowest proportion of carbon stock in adult stands, accounting for about 5% of the total carbon stock in the world’s forests [2]. However, the forest floor is a key component in the site carbon and nutrient dynamics and contributes to soil mineral carbon and acts as a nutrient reservoir for successive rotations [18,30].
We acknowledge the limitations of our study and recommend exercising caution when using carbon stock estimates from the models we have developed. Our models are limited to Pinus radiata plantations that are close to harvest age, and they may not be accurate when applied to younger stands with the same productivity. Similarly, as our models were developed using four soil parent materials, their application to other soils (e.g., marine sediments or red clay) may not provide accurate estimates of soil and stand carbon stocks. Future work will consider measurement and sampling in other soil types to cover a wide range of Pinus radiata plantations and eroded soils to compare with our results. Measurement and sampling will also be conducted at sites with characteristics similar to those in our study to validate the generated models. In addition, we will consider other factors, such as different silvicultural practices, to assess their potential impact on soil carbon stocks.

5. Conclusions

Soil type was a key factor in carbon stocks in the adult radiata pine stands evaluated. We found significantly more total carbon stock in the metamorphic and recent ash soils than in the granitic or sandy soil sites. In all soil types, a high carbon stock was found in the mineral soil up to 1 m deep. The forest floor represented the lowest carbon pool of the stands in the four soil types. The climate, soil, and stand productivity variables were highly related to all carbon stocks in our radiata pine stands, being good predictors in our adjusted models, with high significance estimating each carbon stock (biomass, forest floor, mineral soil, and total carbon stock). Those variables related to soil water availability (minor sand content and more soil water holding capacity), fertility (nitrogen content), annual precipitation, and stand productivity (stand volume and NDVI) were strongly and directly related to all carbon stocks, while those variables related to poor-nutrients sites, and drought and water stress, such as temperature, VPD, soil water deficit index, evapotranspiration, and higher sand content, decreased the carbon stock of stands. Those results indicate that increasing growth and stand productivity could increase the potential capacity of forests to capture and store carbon. Our developed models to estimate carbon stocks presented good fits, with variables that were easy to acquire, measure, and sample, which could help in the analysis of estimating the effects of different scenarios of climate change on forests.

Author Contributions

Conceptualization, R.R., R.M.A. and J.P.E.; methodology, R.R., D.B. and O.C.C.; software, D.B.; validation, D.B., R.R. and M.V.A.; formal analysis, D.B., R.R. and M.V.A.; investigation, R.R., D.B., Ó.J. and M.V.A.; resources, M.P., R.R., R.M.A. and J.P.E.; data curation, Ó.J., D.B. and M.V.A.; writing—original draft preparation, D.B.; writing—review and editing, R.R. and R.M.A.; visualization, R.R.; supervision, R.R., R.M.A. and O.C.C.; project administration, Ó.J., R.R. and R.M.A.; funding acquisition, R.R. and M.P. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the Forest Productivity Cooperative at Universidad de Concepción and the Chilean National Commission for Scientific and Technological Research (Project Grant ANID BASAL FB210015 “CENAMAD”).

Data Availability Statement

Restrictions apply to the datasets. The datasets presented in this article are not readily available because the data are part of an ongoing study.

Acknowledgments

We acknowledge funding and scientific support from the Forest Productivity Cooperative at Universidad de Concepción and the Chilean National Commission for Scientific and Technological Research (Project Grant ANID BASAL FB210015 “CENAMAD”, ANID-Chile, project ANID-ANILLO ACT210060: FiRING:), and the Scholarship Program, DOCTORADO BECAS CHILE/2024-21240118; and we gratefully acknowledge CMPC S.A. (Forestal Mininco) for support to access to forest farms.

Conflicts of Interest

The author M.P. was employed by the Forestal Mininco SpA. company. The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as potential conflicts of interest. The author M.P. had the following involvement with the study: conclusions and support to access to forest farms.

References

  1. Rubilar, R.A.; Valverde, J.C.; Barrientos, G.; Campoe, O.C. Water and Temperature Ecophysiological Challenges of Forests Plantations under Climate Change. Forests 2024, 15, 654. [Google Scholar] [CrossRef]
  2. Pan, Y.; Birdsey, R.A.; Fang, J.; Houghton, R.; Kauppi, P.E.; Kurz, W.A.; Phillips, O.L.; Shvidenko, A.; Lewis, S.L.; Canadell, J.G.; et al. A Large and Persistent Carbon Sink in the World’s Forests. Science 2011, 333, 988–993. [Google Scholar] [CrossRef]
  3. Lal, R. Soil carbon sequestration to mitigate climate change. Geoderma 2004, 123, 1–22. [Google Scholar] [CrossRef]
  4. Olmedo, G.F.; Guevara, M.; Gilabert, H.; Montes, C.R.; Arellano, E.C.; Barría-Knopf, B.; Gárate, F.; Mena-Quijada, P.; Acuña, E.; Bown, H.E.; et al. Baseline of Carbon Stocks in Pinus radiata and Eucalyptus spp. Plantations of Chile. Forests 2020, 11, 1063. [Google Scholar] [CrossRef]
  5. Bozo, D.; Rubilar, R.; Campoe, O.C.; Alzamora, R.M.; Elissetche, J.P.; Valverde, J.C.; Pizarro, R.; Pincheira, M.; Valencia, J.C.; Sanhueza, C. Soil and Site Productivity Effects on Above- and Belowground Radiata Pine Carbon Pools at Harvesting Age. Plants 2024, 13, 3482. [Google Scholar] [CrossRef] [PubMed]
  6. Asmussen, M.V.; Rubilar, R.; Bozo, D.; Alzamora, R.M.; Elissetche, J.P.; Pincheira, M.; Jara, O. Relationship Between Carbon Stock and Stand Cumulative Production at Harvesting Age of Pinus radiata Plantations: A Comparison Between Granitic and Metamorphic Soils. Sustainability 2025, 17, 3614. [Google Scholar] [CrossRef]
  7. Paul, K.I.; Polglase, P.J.; Nyakuengama, J.G.; Khanna, P.K. Change in soil carbon following afforestation. For. Ecol. Manag. 2002, 168, 241–257. [Google Scholar] [CrossRef]
  8. Wiesmeier, M.; Urbanski, L.; Hobley, E.; Lang, B.; von Lützow, M.; Marin-Spiotta, E.; van Wesemael, B.; Rabot, E.; Ließ, M.; Garcia-Franco, N.; et al. Soil organic carbon storage as a key function of soils—A review of drivers and indicators at various scales. Geoderma 2019, 333, 149–162. [Google Scholar] [CrossRef]
  9. Poblete, P.; Gysling, J.; Álvarez, V.; Bañados, J.; Kahler, C.; Pardo, E.; Soto, D.; Baeza, D. Anuario Forestal 2023; Instituto Forestal: Santiago, Chile, 2023. [Google Scholar]
  10. Alvarez, J.; Allen, H.L.; Albaugh, T.J.; Stape, J.L.; Bullock, B.P.; Song, C. Factors influencing the growth of radiata pine plantations in Chile. Forestry 2013, 86, 13–26. [Google Scholar] [CrossRef]
  11. Albaugh, T.J.; Alvarez, J.; Rubilar, R.A.; Fox, T.R.; Allen, H.L.; Stape, J.L.; Mardones, O. Long-Term Pinus radiata Productivity Gains from Tillage, Vegetation Control, and Fertilization. For. Sci. 2015, 61, 800–808. [Google Scholar] [CrossRef]
  12. Ojeda, H.; Rubilar, R.A.; Montes, C.; Cancino, J.; Espinosa, M. Leaf area and growth of Chilean radiata pine plantations after thinning across a water stress gradient. N. Z. J. For. Sci. 2018, 48, 10. [Google Scholar] [CrossRef]
  13. Rubilar, R.; Bozo, D.; Albaugh, T.; Cook, R.; Campoe, O.; Carter, D.; Allen, H.L.; Álvarez, J.; Pincheira, M.; Zapata, Á. Rotation-age effects of subsoiling, fertilization, and weed control on radiata pine growth at sites with contrasting soil physical, nutrient, and water limitations. For. Ecol. Manag. 2023, 544, 121213. [Google Scholar] [CrossRef]
  14. Rubilar, R.A.; Albaugh, T.J.; Allen, H.L.; Alvarez, J.; Fox, T.R.; Stape, J.L. Influences of silvicultural manipulations on above- and belowground biomass accumulations and leaf area in young Pinus radiata plantations, at three contrasting sites in Chile. Forestry 2012, 86, 27–38. [Google Scholar] [CrossRef]
  15. Jobbágy, E.G.; Jackson, R.B. The Vertical Distribution of Soil Organic Carbon and Its Relation to Climate and Vegetation. Ecol. Appl. 2000, 10, 423–436. [Google Scholar] [CrossRef]
  16. Garrett, L.G.; Byers, A.K.; Wigley, K.; Heckman, K.A.; Hatten, J.A.; Wakelin, S.A. Lifting the Profile of Deep Forest Soil Carbon. Soil Syst. 2024, 8, 105. [Google Scholar] [CrossRef]
  17. Stolpe, N.B. Descripciones de los Principales Suelos de la VIII Región de Chile; Universidad de Concepción Concepción: Concepción, Chile, 2006; Volume 1. [Google Scholar]
  18. Prescott, C.E.; Vesterdal, L. Decomposition and transformations along the continuum from litter to soil organic matter in forest soils. For. Ecol. Manag. 2021, 498, 119522. [Google Scholar] [CrossRef]
  19. Garrido, E.; Matus, F. Are organo-mineral complexes and allophane content determinant factors for the carbon level in Chilean volcanic soils? Catena 2012, 92, 106–112. [Google Scholar] [CrossRef]
  20. Matus, F.; Rumpel, C.; Neculman, R.; Panichini, M.; Mora, M.L. Soil carbon storage and stabilisation in andic soils: A review. Catena 2014, 120, 102–110. [Google Scholar] [CrossRef]
  21. Torn, M.S.; Trumbore, S.E.; Chadwick, O.A.; Vitousek, P.M.; Hendricks, D.M. Mineral control of soil organic carbon storage and turnover. Nature 1997, 389, 170–173. [Google Scholar] [CrossRef]
  22. Crovo, O.; Aburto, F.; Albornoz, M.F.; Southard, R. Soil type modulates the response of C, N, P stocks and stoichiometry after native forest substitution by exotic plantations. Catena 2021, 197, 104997. [Google Scholar] [CrossRef]
  23. Six, J.; Conant, R.T.; Paul, E.A.; Paustian, K. Stabilization mechanisms of soil organic matter: Implications for C-saturation of soils. Plant Soil 2002, 241, 155–176. [Google Scholar] [CrossRef]
  24. Pinto, C.B.; Marques, R.; Dalmaso, C.A.; Kulmann, M.S.d.S.; Deliberali, I.; Schumacher, M.V.; de Oliveira Junior, J.C. Relationship between edaphoclimatic attributes and productivity of loblolly pine (Pinus taeda L.) in southern Brazil. For. Ecol. Manag. 2023, 544, 121162. [Google Scholar] [CrossRef]
  25. Becknell, J.M.; Kissing Kucek, L.; Powers, J.S. Aboveground biomass in mature and secondary seasonally dry tropical forests: A literature review and global synthesis. For. Ecol. Manag. 2012, 276, 88–95. [Google Scholar] [CrossRef]
  26. Sun, X.; Ryan, M.G.; Tang, Z.; Wang, B.; Fang, Q.; Sun, O.J. Environmental controls on density-based soil organic carbon fractionations in global terrestrial ecosystems. Land Degrad. Dev. 2023, 34, 4358–4372. [Google Scholar] [CrossRef]
  27. Yang, Y.; Liu, L.; Zhang, P.; Wu, F.; Wang, Y.; Xu, C.; Zhang, L.; An, S.; Kuzyakov, Y. Large-scale ecosystem carbon stocks and their driving factors across Loess Plateau. Carbon Neutrality 2023, 2, 5. [Google Scholar] [CrossRef]
  28. Paula, R.R.; Calmon, M.; Lopes-Assad, M.L.; de Sá Mendonça, E. Soil organic carbon storage in forest restoration models and environmental conditions. J. For. Res. 2021, 33, 1123–1134. [Google Scholar] [CrossRef]
  29. Harmon, M.E.; Franklin, J.F.; Swanson, F.J.; Sollins, P.; Gregory, S.V.; Lattin, J.D.; Anderson, N.H.; Cline, S.P.; Aumen, N.G.; Sedell, J.R.; et al. Ecology of Coarse Woody Debris in Temperate Ecosystems. In Advances in Ecological Research; MacFadyen, A., Ford, E.D., Eds.; Academic Press: Cambridge, UK, 1986; Volume 15, pp. 133–302. [Google Scholar]
  30. Díaz Villa, M.V.E.; Cristiano, P.M.; De Diego, M.S.; Rodríguez, S.A.; Efron, S.T.; Bucci, S.J.; Scholz, F.; Goldstein, G. Do selective logging and pine plantations in humid subtropical forests affect aboveground primary productivity as well as carbon and nutrients transfer to soil? For. Ecol. Manag. 2022, 503, 119736. [Google Scholar] [CrossRef]
  31. Lopez-Senespleda, E.; Calama, R.; Ruiz-Peinado, R. Estimating forest floor carbon stocks in woodland formations in Spain. Sci. Total Environ. 2021, 788, 147734. [Google Scholar] [CrossRef]
  32. Cartes-Rodríguez, E.; Rubilar-Pons, R.; Acuña-Carmona, E.; Cancino-Cancino, J.; Rodríguez-Toro, J.; Burgos-Tornería, Y. Potencial de las plantaciones de Pinus radiata para el aprovechamiento de los residuos de cosecha en suelos característicos del centro-sur de Chile. Rev. Chapingo Ser. Cienc. For. Ambiente 2016, 22, 221–223. [Google Scholar] [CrossRef]
  33. Carrasco, G.; Almeida, A.C.; Falvey, M.; Olmedo, G.F.; Taylor, P.; Santibanez, F.; Coops, N.C. Effects of climate change on forest plantation productivity in Chile. Glob. Change Biol. 2022, 28, 7391–7409. [Google Scholar] [CrossRef]
  34. Nel, L.; Boeni, A.F.; Prohászka, V.J.; Szilágyi, A.; Kovács, E.; Pásztor, L.; Centeri, C. InVEST Soil Carbon Stock Modelling of Agricultural Landscapes as an Ecosystem Service Indicator. Sustainability 2022, 14, 9808. [Google Scholar] [CrossRef]
  35. Flattery, P.; Fealy, R.; Fealy, R.; Lanigan, G.; Green, S. Simulation of Soil Carbon Efflux From an Arable Soil Using the ECOSSE Model: Need for an Improved Model Evaluation Framework? Sci. Total Environ. 2018, 622–623, 1241–1249. [Google Scholar] [CrossRef] [PubMed]
  36. Bārdulis, A.; Lupiķis, A.; Stola, J. Carbon Balance in Forest Mineral Soils in Latvia Modelled with Yasso07 Soil Carbon Model. Res. Rural Dev. 2017, 1, 28–34. [Google Scholar] [CrossRef]
  37. CIREN. Descripción de Suelos, Materiales y Símbolos: Estudio Agrológico VIII Región; CIREN: Santiago, Chile, 1999. [Google Scholar]
  38. Staff, S.S. Keys to Soil Taxonomy, 13th ed.; USDA-Natural Resources Conservation Service: Washington, DC, USA, 2022. [Google Scholar]
  39. Dinamarca, D.I.; Galleguillos, M.; Seguel, O.; Faundez Urbina, C. CLSoilMaps: A national soil gridded database of physical and hydraulic soil properties for Chile. Sci. Data 2023, 10, 630. [Google Scholar] [CrossRef]
  40. Mininco, F. Compendio de Funciones Para Especies de Intereésde Forestal Mininco S.A. Concepción, Technical Report; Forestal Mininco: Concepción, Chile, 1995. [Google Scholar]
  41. Sandoval, S.; Montes, C.R.; Olmedo, G.F.; Acuña, E.; Mena-Quijada, P. Modelling above-ground biomass of Pinus radiata trees with explicit multivariate uncertainty. For. Int. J. For. Res. 2021, 95, 380–390. [Google Scholar] [CrossRef]
  42. Zerihun, A.; Montagu, K.D. Belowground to aboveground biomass ratio and vertical root distribution responses of mature Pinus radiata stands to phosphorus fertilization at planting. Can. J. For. Res. 2004, 34, 1883–1894. [Google Scholar] [CrossRef]
  43. IPCC. Climate Change 2013: The Physical Science Basis, in Contribution of Working Group I (WGI) to the Fifth Assessment Report (AR5) of the Intergovernmental Panel on Climate Change (IPCC); Cambridge University Press: Cambridge, UK, 2013. [Google Scholar]
  44. Sadzawka, A.; Carrasco, M.; Grez, R.; Mora, M.; Flores, H.; Neaman, A. Metodos de análisis recomendados para los suelos de Chile. Inst. Investig. Agropecu. 2006, 34, 164. [Google Scholar]
  45. Poeplau, C.; Vos, C.; Don, A. Soil organic carbon stocks are systematically overestimated by misuse of the parameters bulk density and rock fragment content. Soil 2017, 3, 61–66. [Google Scholar] [CrossRef]
  46. Hersbach, H.; Bell, B.; Berrisford, P.; Hirahara, S.; Horányi, A.; Muñoz-Sabater, J.; Nicolas, J.; Peubey, C.; Radu, R.; Schepers, D.; et al. The ERA5 global reanalysis. Q. J. R. Meteorol. Soc. 2020, 146, 1999–2049. [Google Scholar] [CrossRef]
  47. Allen, R.; Pereira, L.; Raes, D.; Smith, M. FAO Irrigation and Drainage Paper No. 56; Food and Agriculture Organization of the United Nations: Rome, Italy, 1998; Volume 56, pp. 26–40. [Google Scholar]
  48. Hargreaves, G.; Samani, Z. Reference Crop Evapotranspiration from Temperature. Appl. Eng. Agric. 1985, 1, 96–99. [Google Scholar] [CrossRef]
  49. Parker, G.G. Tamm review: Leaf Area Index (LAI) is both a determinant and a consequence of important processes in vegetation canopies. For. Ecol. Manag. 2020, 477, 118496. [Google Scholar] [CrossRef]
  50. Brito, V.V.; Rubilar, R.A.; Cook, R.L.; Campoe, O.C.; Carter, D.R.; Mardones, O. Evaluating remote sensing indices as potential productivity and stand quality indicators for Pinus radiata plantations. Sci. For. 2021, 49, e3316. [Google Scholar] [CrossRef]
  51. Cohrs, C.W.; Cook, R.L.; Gray, J.M.; Albaugh, T.J. Sentinel-2 Leaf Area Index Estimation for Pine Plantations in the Southeastern United States. Remote Sens. 2020, 12, 1406. [Google Scholar] [CrossRef]
  52. Chavez, J.P. Image-Based Atmospheric Corrections—Revisited and Improved. Photogramm. Eng. Remote Sens. 1996, 62, 1025–1036. [Google Scholar]
  53. Chander, G.; Markham, B.L.; Helder, D.L. Summary of current radiometric calibration coefficients for Landsat MSS, TM, ETM+, and EO-1 ALI sensors. Remote Sens. Environ. 2009, 113, 893–903. [Google Scholar] [CrossRef]
  54. Birth, G.S.; McVey, G.R. Measuring the Color of Growing Turf with a Reflectance Spectrophotometer. Agron. J. 1968, 60, 640–643. [Google Scholar] [CrossRef]
  55. Rouse, J.W.; Haas, R.H.; Schell, J.A.; Deering, D.W. Monitoring Vegetation Systems in the Great Plains with ERTS; NASA: Houston, TX, USA, 1973. [Google Scholar]
  56. Kranabetter, J.M. Site carbon storage along productivity gradients of a late-seral southern boreal forest. Can. J. For. Res. 2009, 39, 1053–1060. [Google Scholar] [CrossRef]
  57. Cooper, L.A.; Ballantyne, A.P.; Holden, Z.A.; Landguth, E.L. Disturbance impacts on land surface temperature and gross primary productivity in the western United States. J. Geophys. Res. Biogeosci. 2017, 122, 930–946. [Google Scholar] [CrossRef]
  58. Zhao, H.; Yang, C.; Lu, M.; Wang, L.; Guo, B. Patterns and Dominant Driving Factors of Carbon Storage Changes in the Qinghai–Tibet Plateau under Multiple Land Use Change Scenarios. Forests 2024, 15, 418. [Google Scholar] [CrossRef]
  59. Bown, H.E.; Watt, M.S. Stem and Soil CO2 Efflux Responses of Pinus radiata Plantations to temperature, season, age, time (day/night) adn fertilization. Cienc. Investig. Agrar. 2016, 43, 95–109. [Google Scholar] [CrossRef]
  60. Flores, F.J.; Allen, H.L. Efectos del clima y capacidad de almacenamiento de agua del suelo en la productividad de rodales de pino radiata en Chile: Un análisis utilizando el modelo 3-PG. Rev. Bosque 2004, 25, 11–24. [Google Scholar] [CrossRef]
  61. Georgiou, K.; Jackson, R.B.; Vinduskova, O.; Abramoff, R.Z.; Ahlstrom, A.; Feng, W.; Harden, J.W.; Pellegrini, A.F.A.; Polley, H.W.; Soong, J.L.; et al. Global stocks and capacity of mineral-associated soil organic carbon. Nat. Commun. 2022, 13, 3797. [Google Scholar] [CrossRef]
  62. Denef, K.; Six, J. Clay mineralogy determines the importance of biological versus abiotic processes for macroaggregate formation and stabilization. Eur. J. Soil Sci. 2005, 56, 469–479. [Google Scholar] [CrossRef]
  63. Bronick, C.J.; Lal, R. Soil structure and management: A review. Geoderma 2005, 124, 3–22. [Google Scholar] [CrossRef]
  64. Soto, L.; Galleguillos, M.; Seguel, O.; Sotomayor, B.; Lara, A. Assessment of soil physical properties’ statuses under different land covers within a landscape dominated by exotic industrial tree plantations in south-central Chile. J. Soil Water Conserv. 2019, 74, 12–23. [Google Scholar] [CrossRef]
  65. Shoji, S.; Nanzyo, M.; Dahlgren, R. (Eds.) Chapter 8 Productivity and Utilization of Volcanic Ash Soils. In Developments in Soil Science; Elsevier: Amsterdam, The Netherlands, 1993; Volume 21, pp. 209–251. [Google Scholar]
  66. Chendev, Y.; Novykh, L.; Sauer, T.; Petin, A.; Zazdravnykh, E.; Burras, L. Evolution of Soil Carbon Storage and Morphometric Properties of Afforested Soils in the U.S. Great Plains. In Soil Carbon; Springer: Berlin/Heidelberg, Germany, 2014; pp. 475–482. [Google Scholar]
  67. Ouimet, R.; Korboulewsky, N.; Bilger, I. Soil Texture Explains Soil Sensitivity to C and N Losses from Whole-Tree Harvesting in the Boreal Forest. Soil Syst. 2023, 7, 39. [Google Scholar] [CrossRef]
  68. Houghton, R.A. Balancing the Global Carbon Budget. Annu. Rev. Earth Planet. Sci. 2007, 35, 313–347. [Google Scholar] [CrossRef]
  69. Ola, A.; Devos, W.; Bouchard, M.; Mazerolle, M.J.; Raymond, P.; Munson, A.D. Above- and belowground carbon stocks under differing silvicultural scenarios. For. Ecol. Manag. 2024, 558, 121785. [Google Scholar] [CrossRef]
  70. Bravo-Oviedo, A.; Ruiz-Peinado, R.; Onrubia, R.; del Río, M. Thinning alters the early-decomposition rate and nutrient immobilization-release pattern of foliar litter in Mediterranean oak-pine mixed stands. For. Ecol. Manag. 2017, 391, 309–320. [Google Scholar] [CrossRef]
  71. Ostertag, R.; Marín-Spiotta, E.; Silver, W.L.; Schulten, J. Litterfall and Decomposition in Relation to Soil Carbon Pools Along a Secondary Forest Chronosequence in Puerto Rico. Ecosystems 2008, 11, 701–714. [Google Scholar] [CrossRef]
  72. Aerts, R. Climate, Leaf Litter Chemistry and Leaf Litter Decomposition in Terrestrial Ecosystems: A Triangular Relationship. Oikos 1997, 79, 439–449. [Google Scholar] [CrossRef]
  73. Garcia-Palacios, P.; Maestre, F.T.; Kattge, J.; Wall, D.H. Climate and litter quality differently modulate the effects of soil fauna on litter decomposition across biomes. Ecol. Lett. 2013, 16, 1045–1053. [Google Scholar] [CrossRef] [PubMed]
  74. Parton, W.; Silver, W.L.; Burke, I.C.; Grassens, L.; Harmon, M.E.; Currie, W.S.; King, J.Y.; Adair, E.C.; Brandt, L.A.; Hart, S.C.; et al. Global-Scale Similarities in Nitrogen Release Patterns During Long-Term Decomposition. Science 2007, 315, 361–364. [Google Scholar] [CrossRef] [PubMed]
  75. Zhang, D.; Hui, D.; Luo, Y.; Zhou, G. Rates of litter decomposition in terrestrial ecosystems: Global patterns and controlling factors. J. Plant Ecol. 2008, 1, 85–93. [Google Scholar] [CrossRef]
  76. Ferrere, P.; Lupi, A.M. How much carbon do Argentine Pampas Pinus radiata plantations store? For. Syst. 2023, 32, e005. [Google Scholar] [CrossRef]
  77. Oliver, G.R.; Beets, P.N.; Pearce, S.H.; Graham, J.D.; Garrett, L.G. Carbon accumulation in two Pinus radiata stands in the North Island of New Zealand. N. Z. J. For. Sci. 2011, 41, 71–86. [Google Scholar]
Forests 16 01137 g002
Figure 2. Biplot (principal components 1 and 2) from principal component analysis (PCA) for all evaluated sites, considering carbon stocks (TBC, FFC, SOC, and TCS) and climate variables, soil properties, and stand and site characteristics. Ellipses denote groups defined by soil type (sand, granitic, recent ash, and metamorphic).
Figure 2. Biplot (principal components 1 and 2) from principal component analysis (PCA) for all evaluated sites, considering carbon stocks (TBC, FFC, SOC, and TCS) and climate variables, soil properties, and stand and site characteristics. Ellipses denote groups defined by soil type (sand, granitic, recent ash, and metamorphic).
Forests 16 01137 g002
Forests 16 01137 g003
Figure 3. Pearson correlation coefficient (r) between all carbon stocks (TBC = total biomass carbon; FFC = forest floor carbon; SOC = soil organic carbon; and TCS = total stock carbon) and predictor variables (VHA = stand volume; Alt = altitude; NDVI = normalized difference vegetation index; Tmean = mean annual temperature; VDPmean = mean annual vapor deficit pressure; Pp = annual precipitation; ETP = potential evapotranspiration; SWDI = soil water deficit index; SWHC = soil water holding capacity at 1 m depth; N20 = soil nitrogen content at 20 cm depth; Sand20 = soil sand content at 20 cm depth. Non-significant variables (p > 0.05) are not shown in the correlation matrix.
Figure 3. Pearson correlation coefficient (r) between all carbon stocks (TBC = total biomass carbon; FFC = forest floor carbon; SOC = soil organic carbon; and TCS = total stock carbon) and predictor variables (VHA = stand volume; Alt = altitude; NDVI = normalized difference vegetation index; Tmean = mean annual temperature; VDPmean = mean annual vapor deficit pressure; Pp = annual precipitation; ETP = potential evapotranspiration; SWDI = soil water deficit index; SWHC = soil water holding capacity at 1 m depth; N20 = soil nitrogen content at 20 cm depth; Sand20 = soil sand content at 20 cm depth. Non-significant variables (p > 0.05) are not shown in the correlation matrix.
Forests 16 01137 g003
Forests 16 01137 g004
Figure 4. Relationship between observed and predicted carbon stocks using adjusted models for (a) total biomass carbon stock (TBC); (b) forest floor carbon stock (FFC); (c) soil organic carbon stock (SOC); and (d) total carbon stock of site (TCS).
Figure 4. Relationship between observed and predicted carbon stocks using adjusted models for (a) total biomass carbon stock (TBC); (b) forest floor carbon stock (FFC); (c) soil organic carbon stock (SOC); and (d) total carbon stock of site (TCS).
Forests 16 01137 g004
Table 2. Mean physical and chemical soil properties values evaluated at 0–20, 20–40, and 40–100 cm depths from soil pits representing each soil type. Standard deviation for each variable at each depth is indicated in parentheses. Different lowercase letters indicate significant differences among soil type means for each depth (Tukey’s HSD test).
Table 2. Mean physical and chemical soil properties values evaluated at 0–20, 20–40, and 40–100 cm depths from soil pits representing each soil type. Standard deviation for each variable at each depth is indicated in parentheses. Different lowercase letters indicate significant differences among soil type means for each depth (Tukey’s HSD test).
Soil TypeDeep (cm)B.D. (g cm−3)C Total (%)N Total (%)C/NClay (%)Silt (%)Sand (%)
Sandy0–201.13 (0.11) a1.71 (0.81) c0.08 (0.04) c24.8 (10.9) a2.9 (0.7) c26.9 (25.5) b70.2 (26.1) a
20–401.27 (0.16) a1.23 (0.49) c0.06 (0.03) c24.6 (9.7) a2.9 (1.7) c17.7 (15.2) c79.4 (19.6) a
40–1001.34 (0.17) b0.95 (0.54) c0.05 (0.03) b18.1 (4.1) ab3.2 (1.3) b8.1 (4.2) b88.7 (8.6) a
Granitic0–201.20 (0.27) a3.21 (1.68) bc0.14 (0.09) bc25.1 (3.8) a22.7 (5.9) b29.6 (5.6) ab47.7 (5.9) b
20–401.23 (0.20) a2.35 (1.24) bc0.09 (0.06) bc24.9 (4.2) a28.8 (10.1) a27.4 (6.7) bc43.8 (4.7) bc
40–1001.38 (0.09) ab1.11 (0.67) bc0.06 (0.03) b19.1 (3.5) a36.2 (8.6) a27.3 (10.9) a36.5 (15.2) c
Recent Ash0–200.59 (0.07) b7.02 (0.79) a0.41 (0.06) a17.4 (1.7) b8.8 (5.3) c43.0 (10.8) a48.2 (6.5) b
20–400.64 (0.04) b4.89 (0.75) a0.27 (0.04) a18.1 (1.8) b7.4 (6.8) c37.7 (14.5) ab54.9 (14.9) b
40–1000.66 (0.02) c3.42 (0.63) a0.20 (0.03) a17.1 (1.3) ab6.4 (6.9) b35.5 (12.4) a58.1 (11.8) b
Metamorphic 0–201.28 (0.25) a5.07 (3.90) ab0.26 (0.20) b22.2 (7.3) ab36.7 (16.2) a38.5 (14.6) ab24.8 (12.9) c
20–401.36 (0.15) a4.11 (3.47) ab0.21 (0.20) ab21.3 (6.2) ab20.2 (6.8) b43.4 (6.5) a36.4 (13.0) c
40–1001.46 (0.15) a2.08 (1.79) b0.14 (0.12) a15.4 (2.9) b30.9 (13.2) a32.8 (8.9) a36.3 (18.8) c
B.D. = soil bulk density; C total = total carbon content; N = total nitrogen content; C/N = carbon-to-nitrogen ratio.
Table 3. Average stand volume, and aboveground, belowground, total biomass, soil, forest floor, and total site carbon stock for all sites. Different lowercase letters indicate significant differences among soil type means (Tukey’s HSD test), considering an ANOVA analysis within each soil type.
Table 3. Average stand volume, and aboveground, belowground, total biomass, soil, forest floor, and total site carbon stock for all sites. Different lowercase letters indicate significant differences among soil type means (Tukey’s HSD test), considering an ANOVA analysis within each soil type.
Soil TypeStand Volume (m3 ha−1)AGBC (Mg ha−1)BGBC (Mg ha−1)TBC (Mg ha−1)FFC (Mg ha−1)SOC (Mg ha−1)TCS (Mg ha−1)
Sandy soils475.8 ns137.3 ns35.2 ns172.5 ns18.6 ab139.9 c331.0 c
Granitic soils488.5 ns134.2 ns34.4 ns168.6 ns19.8 a217.0 bc405.4 bc
Recent Ash soils505.5 ns142.9 ns35.6 ns178.5 ns13.4 b281.4 ab473.3 ab
Metamorphic soils451.6 ns124.1 ns31.8 ns155.9 ns14.7 ab382.4 a552.9 a
AGBC = carbon stock in the aboveground biomass; BGBC = carbon stock in the belowground biomass; TBC = carbon stock in the total (aboveground + belowground) biomass; SOC = organic carbon stock in the mineral soil (up to 1 m deep); FFC = carbon stock in the forest floor; and TCS = total carbon stock of the stands. ns = not significant.
Table 4. Mean values of carbon stocks and environmental and soil proprieties variables according to site obtained after principal component analysis (PCA).
Table 4. Mean values of carbon stocks and environmental and soil proprieties variables according to site obtained after principal component analysis (PCA).
Soil TypeVHAAltNDVITmeanVPDmeanPpETPSWHCSWDIN20Sand20
(m3 ha−1)(m)(°C)(kPa)(mm yr−1)(mm yr−1)(mm)(mm)(%)(%)
Sandy333.8148.02213.51.111180.71177.119.823.30.0390.1
Sandy431.4125.32113.51.101115.41166.0175.4124.80.1522.4
Sandy470.8114.72213.71.081056.01181.149.7−75.40.1090.3
Sandy517.5166.72313.51.191167.61137.444.374.50.0679.9
Sandy625.4106.02313.61.081089.61166.861.8−15.50.0867.8
Granitic363.084.71913.10.931288.21131.576.4233.20.0849.7
Granitic397.9391.72011.30.831205.21015.479.8269.70.1255.1
Granitic437.4368.72211.50.841240.6985.077.2332.80.0946.6
Granitic574.6716.3219.50.671327.11015.4138.4450.10.3049.6
Granitic669.8594.02510.40.681344.51086.6105.2363.00.0937.6
Recent Ash387.6405.72111.91.111549.61025.5199.9724.00.3452.2
Recent Ash432.2341.32112.31.061219.81163.3232.6289.20.4837.5
Recent Ash512.6475.72011.41.011489.01032.2179.0635.80.4353.8
Recent Ash549.1849.0229.80.891575.1925.2198.1848.00.452.6
Recent Ash646.3380.02311.91.021400.71066.3298.1632.50.3944.6
Metamorphic252.7124.72014.31.16812.9936.090.0−33.10.0530.3
Metamorphic381.5154.02113.51.111090.2974.0100.4216.60.1444.6
Metamorphic402.8400.72012.10.83838.4736.2143.1245.30.2016.3
Metamorphic530.1297.32112.50.81792.7747.1169.6215.20.1624.9
Metamorphic690.4366.32510.60.641730.5954.2262.91039.20.737.7
VHA = stand volume; Alt = altitude; NDVI = normalized difference vegetation index; Tmean = mean annual temperature; VDPmean = mean annual vapor deficit pressure; Pp = annual precipitation; ETP = potential evapotranspiration; SWDI = soil water deficit index; SWHC = soil water holding capacity at 1 m depth; N20 = soil nitrogen content at 20 cm depth; Sand20 = soil sand content at 20 cm depth.
Table 5. Adjusted coefficients and statistical criterion values for total biomass carbon stock (TBC, Mg ha−1) considering the reduced model.
Table 5. Adjusted coefficients and statistical criterion values for total biomass carbon stock (TBC, Mg ha−1) considering the reduced model.
VariableParameterEstimateS.E.pAdj-R2RMSE
Intercepta162.62846.332<0.0010.29933.950
VPDmeanb−146.71436.952<0.001
Ppc−0.3930.122<0.001
ETPd0.4470.118<0.001
SWDIe0.3530.099<0.001
Sand20f1.0310.379<0.001
VPDmean = mean vapor pressure deficit (kPa); Pp = precipitation (mm year−1); ETP = potential evapotranspiration (mm year−1); SWDI = soil water deficit index (mm); Sand20 = sand content at 20 cm depth; S.E. = standard error; p = p-values of regression coefficients; Adj-R2: adjusted coefficient of determination; RMSE: root mean square error. According to the multiple linear model, a, b, c, d, e, and f are the estimated parameters for the intercept and VPDmean, Pp, ETP, SWDI, and Sand20, respectively.
Table 6. Adjusted coefficients and statistical criterion values for forest floor carbon stock (FFC, Mg ha−1) considering the reduced model.
Table 6. Adjusted coefficients and statistical criterion values for forest floor carbon stock (FFC, Mg ha−1) considering the reduced model.
VariableParameterEstimateS.E.pAdj-R2RMSE
Intercepta−7.9116.2950.2140.3945.196
VHAb0.0270.006<0.001
ETPc0.0150.006<0.001
SWHCd−0.0320.011<0.001
VHA = stand volume (m3 ha−1); ETP = evapotranspiration (mm year−1); SWHC = soil water holding capacity (mm); S.E. = standard error; p = p-values of regression coefficients; Adj-R2: adjusted coefficient of determination; RMSE: root mean square error. According to the multiple linear model, a, b, c and d are the estimated parameters for the intercept and VHA, ETP and SWHC, respectively.
Table 7. Adjusted coefficients and statistical criterion values for soil organic carbon stock (SOC, Mg ha−1) considering the reduced model.
Table 7. Adjusted coefficients and statistical criterion values for soil organic carbon stock (SOC, Mg ha−1) considering the reduced model.
VariableParameterEstimateS.E.pAdj-R2RMSE
Intercepta470.30850.639<0.0010.77943.512
VHAb0.2080.050<0.001
N20c319.16641.382<0.001
ETPd−0.3910.045<0.001
VHA = stand volume (m3 ha−1); N = nitrogen content at 20 cm depth (%); ETP = evapotranspiration (mm year−1); S.E. = standard error; p = p-values of regression coefficients; Adj-R2: adjusted coefficient of determination; RMSE: root mean square error. According to the multiple linear model, a, b, c and d are the estimated parameters for the intercept and VHA, N20 and ETP, respectively.
Table 8. Adjusted coefficients and statistical criterion values for total carbon stock (TCS, Mg ha−1) considering the reduced model.
Table 8. Adjusted coefficients and statistical criterion values for total carbon stock (TCS, Mg ha−1) considering the reduced model.
VariableParameterEstimateS.E.pAdj-R2RMSE
Intercepta449.00549.959<0.0010.84742.928
VHAb0.5650.049<0.001
ETPc−0.3540.044<0.001
N20d304.90440.827<0.001
VHA = stand volume (m3 ha−1); ETP = evapotranspiration (mm year−1); N = nitrogen content at 20 cm depth (%); S.E. = standard error; p = p-values of regression coefficients; Adj-R2: adjusted coefficient of determination; RMSE: root mean square error. According to the multiple linear model, a, b, c and d are the estimated parameters for the intercept and VHA, ETP and N20, respectively.
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Share and Cite

MDPI and ACS Style

Bozo, D.; Rubilar, R.; Jara, Ó.; Asmussen, M.V.; Alzamora, R.M.; Elissetche, J.P.; Campoe, O.C.; Pincheira, M. Modeling the Effects of Climate and Site on Soil and Forest Floor Carbon Stocks in Radiata Pine Stands at Harvesting Age. Forests 2025, 16, 1137. https://doi.org/10.3390/f16071137

AMA Style

Bozo D, Rubilar R, Jara Ó, Asmussen MV, Alzamora RM, Elissetche JP, Campoe OC, Pincheira M. Modeling the Effects of Climate and Site on Soil and Forest Floor Carbon Stocks in Radiata Pine Stands at Harvesting Age. Forests. 2025; 16(7):1137. https://doi.org/10.3390/f16071137

Chicago/Turabian Style

Bozo, Daniel, Rafael Rubilar, Óscar Jara, Marianne V. Asmussen, Rosa M. Alzamora, Juan Pedro Elissetche, Otávio C. Campoe, and Matías Pincheira. 2025. "Modeling the Effects of Climate and Site on Soil and Forest Floor Carbon Stocks in Radiata Pine Stands at Harvesting Age" Forests 16, no. 7: 1137. https://doi.org/10.3390/f16071137

APA Style

Bozo, D., Rubilar, R., Jara, Ó., Asmussen, M. V., Alzamora, R. M., Elissetche, J. P., Campoe, O. C., & Pincheira, M. (2025). Modeling the Effects of Climate and Site on Soil and Forest Floor Carbon Stocks in Radiata Pine Stands at Harvesting Age. Forests, 16(7), 1137. https://doi.org/10.3390/f16071137

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop