Response of Thinning to C:N:P Stoichiometric Characteristics and Seasonal Dynamics of Leaf-Litter-Soil System in Cupressus funebris Endl. Artificial Forests in Southwest, China

Jiang, Xue; Yang, Jingtian; Yang, Yulian; Yang, Jiaping; Dong, Qing; Zeng, Houyuan; Zhang, Kaiyou; Xu, Ning; Yuan, Jiayi; Liu, Mei; Li, Dehui; Wu, Qinggui

doi:10.3390/f15081435

Open AccessArticle

Response of Thinning to C:N:P Stoichiometric Characteristics and Seasonal Dynamics of Leaf-Litter-Soil System in Cupressus funebris Endl. Artificial Forests in Southwest, China

by

Xue Jiang

^1,2,†

,

Jingtian Yang

^1,†,

Yulian Yang

¹,

Jiaping Yang

¹,

Qing Dong

¹,

Houyuan Zeng

²,

Kaiyou Zhang

¹,

Ning Xu

¹,

Jiayi Yuan

²,

Mei Liu

¹,

Dehui Li

³ and

Qinggui Wu

^1,*

¹

Ecological and Security Key Laboratory of Sichuan Province, Mianyang Normal University, Mianyang 621000, China

²

Engineering Research Center for Forest and Grassland Disaster Prevention and Reduction, Mianyang Normal University, Mianyang 621000, China

³

School of Urban and Rural Planning and Construction, Mianyang Normal University, Mianyang 621000, China

^*

Author to whom correspondence should be addressed.

^†

These authors contributed equally to this work.

Forests 2024, 15(8), 1435; https://doi.org/10.3390/f15081435

Submission received: 9 June 2024 / Revised: 27 July 2024 / Accepted: 13 August 2024 / Published: 14 August 2024

(This article belongs to the Section Forest Soil)

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Abstract

:

Ecological stoichiometry is essential for investigating biogeochemical cycling in an ecosystem. Thinning, a management practice that closely mimics natural processes, significantly influences stand structure and microclimate, thereby affecting nutrient cycling. Nonetheless, seasonal variations in ecological stoichiometry across the leaf-litter-soil continuum under different thinning regimes remain inadequately understood. In this study, we evaluated three thinning methods (strip filling (SF), ecological thinning (ET), and forest gap (FG)) to investigate the stoichiometric characteristics of Cupressus funebris Endl (C. funebris). within the leaf-litter-soil system in Southwest China. The samples were collected during four distinct seasonal periods: early dry season (January–March, EDS), late dry season (April–June, LDS), early wet season (July–September, EWS), and late wet season (October–December, LWS). The results indicated that the (1) carbon (C), nitrogen (N), and phosphorus (P) contents and C:N:P ratio in leaves, litter, and soils varied widely and were strongly influenced by thinning method and season. (2) In the EDS, the soil TP content significantly decreased by 36.9% (p < 0.05), 41.67% (p < 0.05), and 17.9% (p < 0.05) under ET, FG, and SF treatments compared to the pure C. funebris forest (PC). (3) Compared to the PC, the leaf organic C content under ET significantly increased by 6.6% (EDS, p < 0.05), 8.4% (EWS, p < 0.05), 24.8% (LDS, p < 0.05), and 11.5% (EWS, p < 0.05). (4) Under identical thinning methods, the contents of litter C, litter N, litter P, leaf N, and leaf P (excluding litter C in SF) were found to be highest in the LWS. Conversely, the ratios of litter C:N, litter C:P, litter N:P, leaf C:N, leaf C:P, leaf N:P, soil N:P, and soil C:P (except for the ratios of litter N:P in ET and FG) were observed to be lowest in the LWS. (5) Season and thinning method significantly affected the internal stability of P stoichiometric homeostasis, and litter P under ET (EWS) was categorized as “plastic” (p < 0.1, 0.75 < H). (6) The results of the structural equation model show that the thinning method has a direct positive impact on leaf C, N, and P contents and a direct negative impact on the chemical stoichiometry of leaves and soil. Season has a direct positive impact on soil C, N, and P contents, as well as on the chemical stoichiometry of litter and leaves; however, they have a direct negative impact on leaf C, N, and P contents. This study contributes to C. funebris plantation management and provides basic information for global stoichiometric analysis.

Keywords:

thinning methods; leaf-litter-soil system; stoichiometric homeostasis; seasons; Cupressus funebris Endl.

1. Introduction

Carbon (C), nitrogen (N), and phosphorus (P) are essential elements that play pivotal roles in maintaining and regulating biogeochemical cycles within terrestrial ecosystems [1]. The study of C:N:P ecological stoichiometry offers valuable insights into the biogeochemical dynamics of nutrients and energy flow between plants and soil, thereby elucidating the significant ecological implications of these processes [2]. It is widely recognized that N and P are the most prevalent limiting nutrients in terrestrial ecosystems and are capable of regulating plant productivity and influencing C sequestration [3]. Numerous studies have investigated the stoichiometric properties of plant tissues or soil at regional or global scales to analyze nutrient cycling and elemental limitations in plants [3,4,5,6,7,8]. However, contemporary research on ecological stoichiometry has predominantly concentrated on individual components such as leaves, litter, and soil [3,4,6,7,8]. Comprehensive investigations encompassing the entire leaf-litter-soil continuum are scarce.

Thinning is a primary technique for the near-natural transformation of artificial forests and has been extensively employed in forest management practices. This method is principally categorized into strip thinning, gap creation, and ecological thinning [7,9,10,11,12]. For example, forest gaps can induce resource and environmental heterogeneity by changing environmental factors such as light, temperature, and moisture, thereby directly or indirectly influencing the energy flow within plant and soil systems [9]. Ecological thinning, which is a primary management practice for improving the growth of the remaining trees, can stimulate energy cycling by changing the soil microclimate and nutrient dynamics of the remaining trees [7,12]. Strip filling, a technique widely employed in artificial forest management, has been shown to significantly improve the ecological and economic benefits of these forests [11]. Importantly, thinning practices can inevitably influence C:N:P ecological stoichiometry by altering the environmental conditions within plantation forests [7,9,11,12]. Thinning potentially regulates the cycling of C, N, and P by altering the microclimate as well as the quality and quantity of organic matter and microbial properties [7,12]. For instance, Zhou et al. [7] demonstrated that thinning promotes N and P cycling in forest soils and increases soil fertility. However, Muscolo et al. [13] suggested that thinning may reduce litterfall inputs to the soil. Conversely, Yang et al. [14] suggested that thinning may increase litterfall input. Furthermore, the effects of thinning on N₂O emissions remain ambiguous [10]. Consequently, the effects of thinning on C:N:P ecological stoichiometry are difficult to generalize because of differences in origin, tree species, stand density, site quality, stand age, thinning methods, and climatic conditions [4,7,8].

Plants employ specific strategies to adapt to their surrounding environment, and their physiological metabolism fluctuates across different seasons, thereby affecting the stoichiometric ratios of C, N, and P in plants [15]. For example, Orgeas et al. [16] found that sampling timing significantly affects the stoichiometry of C, N, and P in Quercus variabilis Blume leaves. Townsend et al. [17] revealed that plant growth is constrained by P during the rainy season and N during the dry season. Li and Wang [18] observed that the contents and stoichiometry of C, N, and P in plantations showed pronounced seasonal changes on the Loess Plateau. Consequently, when investigating ecological stoichiometry, it is imperative to account for seasonal dynamics to enhance our understanding of temporal variations in C, N, and P.

Cupressus funebris Endl. (C. funebris) is an important, rapidly growing tree species utilized in afforestation efforts for the Yangtze River Shelter Forest Project, valued for its substantial social, economic, and ecological contributions [19,20,21]. However, a high initial planting density has precipitated a range of issues, including markedly reduced water storage capacity, diminished biodiversity, and soil degradation, which have collectively led to a substantial decline in ecological services [14,21,22]. According to the third-phase project plan for the construction of the protective forest system in the Yangtze River Basin (2011–2020), the Chinese government has implemented a series of thinning methods since 2010 to enhance the ecological functions of C. funebris [14]. These methods, which include strip filling, forest gap, and ecological thinning, have been used to optimize the structure of artificial C. funebris forests [14,19]. Previous research on the effects of various thinning methods on C. funebris has predominantly focused on biomass, root system architecture, stand structure, and plant diversity [14,19,20,21,23]. However, studying the stoichiometric characteristics of C:N:P and their seasonal dynamics within the leaf-litter-soil system in C. funebris plantations can provide valuable insights into the adaptation strategies and nutrient limitations of these ecosystems. Therefore, it is imperative to investigate the processes of material and energy circulation within the leaf-litter-soil system to gain a comprehensive understanding of the ecological characteristics and functions of C. funebris artificial forests under various thinning methods. Such insights are essential for vegetation restoration and forest management strategies in the study area. In this study, we selected three thinning methods (strip filling, forest gap, and ecological thinning) and one natural forest. We sampled plant leaves, leaf litter, and soil samples in four seasons to investigate C, N, and P contents, stoichiometry, and stoichiometric homeostasis in Southwest China.

2. Materials and Methods

2.1. Study Site and Experimental Design

The study site is situated in Linshan Township (31°15′–31°18′ N, 105°25′–105°29′ E), Yanting County, Sichuan Province, Southwest China. It lies between 400 and 650 m above sea level. In the study area, the climate is subtropical humid monsoon, with an annual mean temperature of 17.3 °C and 826 mm of precipitation. The soil type in the region is Cambisols, as classified in the WRB [14]. The tree layer within the study area predominantly consists of C. funebris, which was planted at a density of 4000–6000 trees/hectare in the 1970s. The understory shrubs mainly included Coriaria nepalensis Wall. and Vitex negundo L. The understory herbaceous plants included Carex stipitinux C. B. Clarke ex Franch., Cyclosorus acuminatus (Houtt.) Nakai, Imperata cylindrica (L.) P. Beauv., and Pogonatherum crinitum (Thunb.) Kunth. Between 2005 and 2008, the Sichuan Academy of Forestry conducted thinning management experiments on monoculture cypress plantations of similar aspects, slopes, and altitudes. The experiments included strip filling (SF), ecological thinning (ET), and forest gap (FG). In this study, we selected C. funebris forests (including SF, ET, and FG) under three thinning management regimes as the treatments, with unmodified pure Cupressus funebris forests (PC) as the control (Table 1). The three thinning modes primarily aimed to reduce forest stand density. Strip filling was conducted through artificial logging to establish strips with widths ranging from 4 m to 10 m. The resultant forest gaps generated by artificial logging encompass areas between 50 and 200 m², as measured by the vertical projection of the canopy space onto the ground. Ecological thinning was implemented by selectively removing a portion of cypress trees, thereby maintaining 10%–25% of the original density.

All the samples were collected between September 2021 and June 2022. Based on the tropical forest division, we collected samples in the early dry season (January–March, EDS), late dry season (April–June, LDS), early wet season (July–September, EWS), and late wet season (October–December, LWS) [14]. Four plots (20 × 20 m in size and 50 m apart) separated by at least 1 km were selected for each thinning type with a similar latitude, longitude, altitude, and coverage; all the selected trees in the plots were approximately 20 years old. In addition, five 5 × 5 m subplots were selected in each plot, for a total of 20 subplots. In each subplot, trees of similar health and age were randomly and evenly selected for the collection of plant samples (leaves and litter). In addition, a litter trap (1 × 1 m in size and 50 cm above the ground) made of nylon with a mesh size of 1 mm was placed randomly under each selected tree to collect litter. For each tree, we collected five branches from the inner, middle, and outer parts of each crown canopy, and mature leaves without plant diseases or insect pests were selected and transported to the laboratory. We then collected the newly fallen and undecomposed leaf litter in litter traps. Finally, soil was collected in layers (0–20 cm) within each subplot using the “S” sampling method. A soil sample composition of 20 points (approximately 2 kg) was randomly collected from each subplot. At different time intervals, 20 plant leaf, litter, and soil samples were collected per treatment, corresponding to 20 replicates. In total, 320 samples of plant leaves, litter, and soil were collected (four treatments × four plots × five subplots × four seasons). Each leaf and litter sample weighed approximately 250 g.

2.2. Laboratory Analysis

After being delivered to the lab, the plant leaf and litter samples were first oven-dried for 30 min at 105 °C and then dried further at 65 °C until they reached a consistent weight. The soil samples were then air-dried. After being ground with a ball mill, all samples were sieved through a 0.15-mm sieve and then stored. The organic C (OC) content of the soil and plants was analyzed using the potassium dichromate volumetric method [24]. Soil and plant total nitrogen (TN) content was determined using the semi-micro Kjeldahl method [24]. The total phosphorus (TP) content of soils and plants was determined using the HClO₄-H₂SO₄ digestion–molybdenum antimony anticolorimetric method [24].

2.3. Data Analysis

To ascertain the extent of stoichiometric homeostasis, we used the methodology described by Persson et al. [25]. This pivotal parameter was derived quantitatively by using the following mathematical equation:

H = \frac{\log_{10} (x)}{\log_{10} (y) - \log_{10} (c)}

(1)

where x is the resource soil stoichiometry, y is the nutrient stoichiometry of the organism (leaves or litter), and c is a constant. Therefore, H is the slope of the regression between log(x) and log(y) and should have values between 0 and 1. As the slope was expected to be equal to or >0, one-tailed tests with α = 0.1 were used. If the regression relationship was non-significant (p > 0.1), H was set to zero and the organism was considered “strictly homeostatic”. Species with H = 1 were considered non-homeostatic. All datasets with significant regressions and 0 < H < 1 were classified as “homeostatic” (0 < H ≤ 0.25), “weakly homeostatic” (0.25 < H ≤ 0.5), “weakly plastic” (0.5 < H ≤ 0.75), or “plastic” (0.75 < H) [25].

All the data were checked for homogeneity of variance and normality. Then, a one-way analysis of variance (ANOVA) with the least significant difference (LSD) test was used to identify differences in the content and stoichiometry of C, N, and P among the four management practices and seasons. It is important to note that a significance level of p < 0.05 was used to determine significant differences in the analysis. Subsequently, the values were summarized by their average and standard deviation (AV ± SD). Principal component analysis (PCA) was performed using the “corrplot” package. We used the “lavaan” package to construct the structural equation model (SEM). And considered to pass the test when the p-value (chi-square) was larger than 0.05. Microsoft Excel 2010, R 4.0.3 (R Development Core Team, 2020), and AI 22.0 software were used for data analysis, tabulation, and graphing.

3. Results

3.1. OC, TN, and TP Contents and Their Seasonal Variation Characteristics in the Leaves, Litter, and Soil of C. funebris Forests

As described in Table 2, the data demonstrated that thinning methods, seasons, and their interactions had a significant impact on the content of soil OC, leaf OC, litter TN, and litter TP (p < 0.001). The thinning method had a significant impact on leaf TN content and litter TN content (p < 0.001) but had no significant impact on soil TN content, soil TP content, or leaf TP content (p > 0.05). Season had a significant impact on soil OC content, leaf OC content, soil TN content, leaf TN content, litter TN content, soil TP content, and litter TP content (p < 0.001), as well as leaf TP content and litter OC content (p < 0.05). The interaction effect between thinning method and season had a significant impact on the TN and TP content of litter (p < 0.001), a significant impact on soil TP content (p < 0.01), and no significant impact on the TN content of soil and leaves (p > 0.05). As shown in Table 3, the OC, TN, and TP contents of leaves, litter, and soil were 378–497 g·kg⁻¹, 10.1–13.7 g·kg⁻¹, and 0.84–1.31 g·kg⁻¹ (leaves); 300–429 g·kg⁻¹, 5.7–12.6 g·kg⁻¹, and 0.31–1.07 g·kg⁻¹ (litter); and 10–32 g·kg⁻¹, 0.9–1.5 g·kg⁻¹, and 0.41–1.04 g·kg⁻¹ (soil), respectively.

3.1.1. OC, TN, and TP Contents under Different Thinning Methods in the Leaves, Litter, and Soil of Cupressus funebris Forests

During the EWS and EDS, there was no significant difference in the OC and TN contents of the leaves among the three thinning methods compared to the PC (p > 0.05). Similarly, during the EWS and LDS, there was no significant difference in the TP content of the leaves among the three thinning methods compared to the PC (p > 0.05). During the LDS, there was no significant difference in the OC and TN contents of leaves under SF (p > 0.05), but it was significantly reduced under the ET treatment (p < 0.05) compared to the PC. During the EDS, there was no significant difference in the TP content of leaves under SF (p > 0.05), but it was significantly reduced under ET and FG treatments (p < 0.05) compared to the PC. In the LWS, the OC content in leaves significantly decreased only under SF (p < 0.05), whereas the TN and TP contents significantly increased under other treatments (p < 0.05) compared to the PC.

Except for litter TP content under SF in the LDS (p < 0.05), there was no significant difference in litter TN and TP contents among the three thinning methods during the EWS, LDS, and LWS compared to the PC (p > 0.05). Notably, compared to the PC, litter OC content under ET significantly increased by 6.56% (EDS, p < 0.05), 8.38% (EWS, p < 0.05), 24.77% (LDS, p < 0.05), and 11.45% (LWS, p < 0.05).

There was no significant difference in the soil TN content between the three thinning methods and PC in the four seasons (p > 0.05). In the EDS, the soil OC content significantly increased by 7.85% (p > 0.05), 51.39% (p < 0.05), and 59.94% (p < 0.05) under ET, FG, and SF treatments, respectively, whereas the soil TP content significantly decreased by 36.90% (p < 0.05), 41.67% (p < 0.05), and 17.86% (p < 0.05), respectively, compared to the PC. In the LDS, the soil OC content was significantly reduced by 28.61% (p > 0.05), 52.37% (p < 0.05), and 32.95% (p < 0.05) under the ET, FG, and SF treatments, respectively. There was no significant difference in the soil TP content (p > 0.05).

3.1.2. OC, TN, and TP Contents in Different Seasons in the Leaves, Litter, and Soil of C. funebris Forests

As shown in Table 3, under the same thinning methods, season had significant effects on the OC, TN, and TP contents in the leaf-litter-soil system (p < 0.05). Overall, the litter OC, litter TN, litter TP, leaf TN, and leaf TP contents (except for litter OC content in SF) were the highest in the LWS. The soil OC, TN, and TP contents (except for the soil OC content in FG) were the highest in the LDS. The leaf OC content (except for SF) was the highest in the EWS.

3.2. C:N:P Stoichiometry and Its Seasonal Variation Characteristics in the Leaves, Litter and Soil of C. funebris Forests

As shown in Table 2, the thinning method had no significant impact on the leaf N:P ratio (p > 0.05). Season had a significant impact on the soil C:N ratio, soil C:P ratio, leaf C:N ratio, leaf C:P ratio, litter C:N ratio, litter N:P ratio, and litter C:P ratio (p < 0.001), as well as the soil N:P ratio (p < 0.01). The interaction effect between thinning method and season had a significant impact on the soil C:N ratio, leaf C:N ratio, litter C:N ratio, soil C:P ratio, leaf C:P ratio, litter C:P ratio, soil N:P ratio, leaf N:P ratio, and litter N:P ratio (p < 0.001). As shown in Table 4, the C:N, C:P, and N:P ratios of leaves, litter, and soil were 28.43–47.89, 310.34–541.30, and 10.28–13.00 (leaves); 30.60–66.27, 343.84–1298.66, and 11.09–24.24 (litter); and 7.61–26.07, 13.12–55.89, and 1.29–2.76 (soil), respectively.

3.2.1. C:N:P Stoichiometry under Different Thinning Methods in the Leaves, Litter, and Soil of C. funebris Forests

As shown in Table 4, the thinning method had no significant impact on the ratios of leaf C:N (in the EDS) and leaf N:P (in the LDS and EWS) (p > 0.05). In the same seasons, the ratios of litter C:N, C:P, and N:P of the PC were significantly lower than those under SF (p < 0.05), and the ratios of leaf N:P under FG were significantly lower than those under the other thinning methods (p < 0.05). Overall, the ratios of soil C:N, soil C:P, soil N:P, leaf C:N, and leaf C:P of the PC (except for the ratios of soil C:N, soil C:P, and soil N:P in the EDS) were significantly higher than those under other thinning methods (p < 0.05) in the same seasons.

3.2.2. C:N:P Stoichiometry in Different Seasons in the Leaves, Litter, and Soil of C. funebris Forests

As shown in Table 4, under the same thinning methods, season had significant effects on the C:N, C:P, and N:P ratios in the plant-litter-soil system (p < 0.05). Overall, the ratios of litter C:N, litter C:P, litter N:P, leaf C:N, leaf C:P, leaf N:P, soil N:P, and soil C:P (except for the ratios of litter N:P under ET and FG) were the lowest in the LWS.

3.3. Stoichiometric Homeostasis

The results of the degree of the stoichiometric homeostasis of C, N, P, C:N, C:P, and N:P in the leaves and litter are shown in Table 5.

The C content in the leaves and litter was not significantly affected by any season or thinning method (p > 0.1). However, the C content in leaves and litter under FG (LWS), SF (LWS), and ET (EWS) was categorized as “homeostatic” (p < 0.1, 0 < H ≤ 0.25).

The N content in leaves and litter was not significantly affected by any season or thinning method (p > 0.1). However, the leaf N content in the PC (LDS) was categorized as “homeostatic” (p < 0.1, 0 < H ≤ 0.25), and the litter N content under FD (LDS) was categorized as “weakly homeostatic” (p < 0.1, 0.25 < H ≤ 0.5).

Season and thinning method significantly affect the internal stability of P stoichiometric homeostasis. The litter P content under SF (EDS) and PC (LDS) was categorized as “weakly homeostatic” (p < 0.1, 0.25 < H ≤ 0.5). The leaf P content under FG (EDS) was categorized as “weakly homeostatic” (p < 0.1, 0.25 < H ≤ 0.5). The leaf P content under SF (EWS) and SF (LDS) was categorized as “homeostatic” (p < 0.1, 0 < H ≤ 0.25). However, the litter P content under ET (EWS) was categorized as “plastic” (p < 0.1, 0.75 < H). All others were “strictly homeostatic” (p > 0.1).

The C:N stoichiometry in leaves and litter was not significantly affected by season or thinning method (p > 0.1). However, the litter C:N stoichiometry under FG (EDS) was categorized as “homeostatic” (p < 0.1, 0 < H ≤ 0.25), and litter C:N stoichiometry in the PC (LDS) was categorized as “weakly homeostatic” (p < 0.1, 0.25 < H ≤ 0.5).

The C:P stoichiometry in leaves and litter was not significantly affected by season or thinning method (p > 0.1). However, the leaf C:P stoichiometry under ET (LDS) was categorized as “plastic” (p < 0.1, 0.75 < H), and the C:P stoichiometry in leaves and litter under FG (EDS) was categorized as “homeostatic” (p < 0.1, 0 < H ≤ 0.25).

The N:P stoichiometry in leaves and litter was not significantly affected by season or thinning method (p > 0.1). However, the leaf N:P stoichiometry under FG (EDS), PC (EWS), and SF (LDS) was categorized as “homeostatic” (p < 0.1, 0 < H ≤ 0.25), and litter N:P stoichiometry under ET (EWS) was categorized as “weakly homeostatic” (p < 0.1, 0.25 < H ≤ 0.5).

3.4. Relationships of C, N, and P Contents and Ecological Stoichiometry in the Plant-Litter-Soil System

Principal component analysis (PCA) showed that in the EDS, there was a significant negative correlation between litter TP and soil TP, litter TN, leaf TP, leaf TN, and leaf OC (Figure 1A). The litter N:P ratio was significantly positively correlated with the litter C:P ratio and significantly negatively correlated with the leaf N:P ratio (Figure 2A).

In the EWS, litter TP was significantly positively correlated with litter TN and litter OC and significantly negatively correlated with leaf OC and soil TP (Figure 1B). The litter N:P ratio was significantly positively correlated with the litter C:P ratio and significantly negatively correlated with the soil N:P ratio and soil C:P ratio (Figure 2B).

In the LDS, litter TP was significantly positively correlated with litter TN and soil TP and significantly negatively correlated with leaf OC, leaf TN, and leaf TP (Figure 1C). The litter N:P ratio was significantly positively correlated with the soil N:P ratio and leaf N:P ratio and significantly negatively correlated with the leaf C:N ratio (Figure 2C).

In the LWS, litter TP was significantly positively correlated with leaf OC and significantly negatively correlated with leaf TN and TP (Figure 1D). The litter N:P ratio was significantly positively correlated with the litter C:P ratio and litter C:N ratio and significantly negatively correlated with the soil N:P ratio, soil C:P ratio, and soil C:N ratio (Figure 2D).

The SEM (Figure 3) indicates that LI-N was indirectly positively affected by the thinning method and indirectly negatively correlated with LI-H. LI-H was indirectly positively affected by season, L-N, and S-H and had indirect negative correlations with L-H. L-H was indirectly positively affected by season, L-N, and S-N and had indirect negative correlations with the thinning method. L-N had indirect negative correlations with season and S-N. S-N was indirectly and positively affected by season and S-H.

4. Discussion

4.1. Differences in C, N, and P Contents and Stoichiometry in Leaves, Litter, and Soil

Previous research has shown that thinning significantly increases soil C, N, and P contents [6]. Some researchers have theorized that thinning can open the upper canopy, leading to warmer and wetter soils, enhanced microbial activity, and, ultimately, faster nitrogen cycling [26,27,28]. On the other hand, other researchers believe that thinning reduces the amount of litter entering the soil, limiting soil N cycling [13]. However, our study showed that soil TN was not affected by intercropping, regardless of season. Zhou et al. [7] conducted a meta-analysis of 1228 observations from 115 studies worldwide and showed that intercropping did not significantly affect soil TN, which corroborated our findings. However, this finding is inconsistent with the results of previous studies [13,26,27,28]. This may be due to the complex mechanism of soil nitrogen cycling, which is influenced by factors such as forest biological communities, climate, and thinning systems (thinning intensity and recovery year after thinning) [7].

Koerselman and Meuleman [29] pointed out that N:P < 14 indicates N limitation. However, our research showed that the soil C:N, C:P, and N:P ratios of the three thinning methods were lower than the global forest soil average C:N (12.4), average C:P (81.9), and average N:P (6.6) (Table 3). Cleveland and Liptzin [30] suggested that soil is restricted by the N supply. Mosca et al. [31] also found that thinning could reduce the input of litter into the soil, thereby limiting soil N cycling. This may be because although thinning did not affect soil TN content, ET can significantly increase soil TP. Zhou et al. [7] also found that thinning resulted in a 6.1% increase in soil TP. Most research results have shown that thinning not only leads to an increase in input soil residues but also stimulates the growth of understory plants, requiring a large amount of P, which can mobilize the redistribution of soil P [7,32,33].

Thinning is a key driving factor affecting soil C cycling as the partial logging of forests can alter forest plant biodiversity and functional trait composition [34]. Some studies have shown that thinning can lead to soil OC loss by reducing the litter input [35]. Other studies suggest that thinning can slow down litter decomposition and increase the accumulation of soil OC [36]. The main reason for the contrasting results is the different climatic conditions and tree species characteristics at the study site [36]. Our results indicate that thinning reduces soil OC accumulation but significantly increases litter OC content. This phenomenon may be attributable to the effects of thinning on the canopy openness and microenvironmental conditions. Thinning disrupts the characteristic buffering and stable microclimate of closed-canopy forests, thereby impairing microbial activity and litter decomposition. Additionally, it influences the activities of soil saprophytic and detrital organisms, which are crucial agents in the decomposition of litter and soil organic matter [37,38,39].

Plants primarily obtain N and P from the soil, and the soil nutrient content plays a significant role in regulating the stoichiometry of C, N, and P in plants [40]. Our results showed that the leaves had the highest C, N, and P contents (Table 2). This is because leaves are responsible for photosynthesis and require sufficient C, N, and P to synthesize various enzymes for biochemical reactions [41]. Sterner and Elser [42] suggested that homeostatic organisms can maintain stable levels of various elements and their ratios in fluctuating environments. This ability demonstrates how organisms have adapted to their environment over many generations [43]. In general, the most active organ has the greatest need for essential elements, such as N and P [41]. Based on this, Zhang et al. [41] proposed the hypothesis that highly active organs would exhibit stricter N:P stoichiometry homeostasis to ensure optimal material and energy efficiency. In this study, we found that N, P, and N:P homeostasis was highest in the litter, followed by leaves, supporting the hypothesis that more active organs have a higher capacity to maintain relatively stable element contents and ratios.

4.2. Effects of Season on C, N, and P Contents and Stoichiometry in Leaves, Litter, and Soil

Seasonal fluctuations in C, N, and P contents and stoichiometry in leaves, litter, and soil play a critical role in regulating plant community responses to environmental changes [44]. The prevailing scholarly consensus posits that plants achieve a relative equilibrium with their external environment by regulating their nutritional attributes and physiological processes. Additionally, the stoichiometry of plant ecosystems exhibits seasonal variability [45,46]. Our results showed that seasons have a direct positive impact on soil C, N, and P contents, as well as the chemical stoichiometry of litter and leaves, whereas they have a direct negative impact on leaf C, N, and P contents.

Climate drives plant N-use strategies and plant-soil interactions. Rivas-Ubach et al. [15] argued that plants use specific strategies to adapt to their environment and physiological metabolism changes in different seasons, thereby affecting their C, N, and P stoichiometry. Elser et al. [47] found that species with high relative growth rates tend to have low foliar N:P ratios. Our results showed that litter C, litter N, litter P, leaf N, and leaf P contents for all thinning methods were the highest in the LWS, and among the ecological stoichiometric ratios, the C:N, C:P, and N:P ratios of litter; C:N, C:P, and N:P ratios of leaves; and C:P and N:P ratios of soil were the lowest in the LWS, which is not consistent with some previous research results [18,48]. The reasons for these trends are as follows: (1) In the LWS, the litter mass is constantly rising as microorganisms decompose it to release N. This decomposition also increases the N content of the litter [49]. (2) Plants transport accumulated organic matter from their leaves to other plant parts for storage, which requires a large amount of transport proteins, resulting in a significant increase in the leaf N content [50]. (3) Zhou et al. [7] found that the effect sizes of N cycling processes were significantly correlated with the mean annual precipitation and mean annual temperature, suggesting that these N fluxes are more sensitive to thinning in warm and humid regions. The climatic conditions in the study area were characterized by dryness during the LDS and EWS, with increased rainfall occurring during the LWS.

5. Conclusions

The C, N, and P contents and stoichiometric homeostasis of C. funebris in the plant-litter-soil system have different trends under different thinning methods and seasonal variations. Overall, the C, N, and P contents and C:N:P ratio in leaves, litter, and soils varied widely and were strongly influenced by thinning method and season. Season and thinning method significantly affect the internal stability of P stoichiometric homeostasis, and the litter P content under ET (EWS) was categorized as plastic. The results of the structural equation model show that thinning method has a direct positive impact on the C, N, and P contents of the leaves and a direct negative impact on the chemical stoichiometry of leaves and soil. Season has a direct positive impact on soil C, N, and P contents as well as the chemical stoichiometry of litter and leaves, whereas they have a direct negative impact on leaf C, N, and P contents. Therefore, when artificially managing C. funebris forests, it is necessary to consider a combination of thinning and seasonal dynamics and develop appropriate nurturing management measures. However, studying the stoichiometry of C, N, and P during a single year can lead to uncertain results due to the annual variability. Therefore, in future research, it will be necessary to observe the stoichiometry of C, N, and P over several consecutive years.

Author Contributions

All authors contributed to the study conception and design. Material preparation and data collection and analysis were performed by X.J., J.Y. (Jingtian Yang), Y.Y., J.Y. (Jiaping Yang), Q.D., H.Z., K.Z., N.X., D.L., M.L., J.Y. (Jiayi Yuan) and Q.W. The first draft of the manuscript was written by X.J. and Q.W. All authors commented on the previous versions of the manuscript. All authors have read and agreed to the published version of the manuscript.

Funding

This research was financially supported by the National Natural Science Foundation of China (32071747), the Sichuan Provincial Science and Technology Department Project (2023NSFSC1194, 2022NSFSC1175, and 2023NSFSC0750), the Ecological and Security Key Laboratory of Sichuan Province, China (ESP2204), and the Scientific Research Project of Mianyang Normal University (QD2022A02).

Data Availability Statement

Data and materials can be obtained from the authors upon reasonable request.

Conflicts of Interest

The authors have no relevant financial or non-financial interests to disclose.

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Figure 1. PCA was used to identify the relationships between C, N, and P contents in the plant-litter-soil system: (A) EDS, (B) EWS, (C) LDS, and (D) LWS. In all the diagrams, the percentages on the ordination axes indicate the explained variance. S-TC: soil organic carbon, S-TN: soil total nitrogen, S-TP: soil total phosphorus, L-TC: leaf organic carbon, L-TN: leaf total nitrogen, L-TP: leaf total phosphorus, Li-TC: litter organic carbon, Li-TN: litter total nitrogen, and Li-TP: litter total phosphorus.

Figure 2. PCA was used to identify the relationships between C, N, and P stoichiometry in the plant-litter-soil system: (A) EDS; (B) EWS; (C) LDS; (D) LWS. In all the diagrams, the percentages on the ordination axes indicate the explained variance. S-C:N: soil C:N ratio; S-C:P: soil C:P ratio; S-N:P: soil N:P ratio; L-C:N: leaf C:N ratio; L-C: leaf C:P ratio; L-N:P: leaf N:P ratio; Li-C:N: litter C:N ratio; Li-C:P: litter C:P ratio; and Li-N:P: litter N:P ratio.

Figure 3. Structural equation models representing hypothesized causal relationships among management methods, seasons, nutrients in the soil, litter, and leaves, and C, N, and P stoichiometry in the soil, litter, and leaves. The arrows depict casual relationships: red and full lines indicate positive effects, and blue and dashed lines indicate negative effects. Adjacent to the arrows are standardized path coefficients, which indicate the effect size of the relationship. * p < 0.05, ** p < 0.01, and *** p < 0.001. S-N: soil nutrient; S-H: soil C, N, and P stoichiometry; LI-N: litter nutrient; LI-H: litter C, N, and P stoichiometry; L-N: leaf nutrient; L-H: leaf C, N, and P stoichiometry.

Table 1. Overview of the sample site.

Thinning Method	PC	ET	SF	FG
Gradient	15	17	20	18
Slope aspect	north	north	north	north
Altitude (m)	448	476	463	471
Canopy density	0.9 ± 0.01	0.82 ± 0.03	0.72 ± 0.01	0.59 ± 0.02
Species number	22	32	30	33
Density (trees/hectare)	3800	3200	2250	1975

Note: SF, strip filling; ET, ecological thinning; FG, forest gap; and PC: pure Cupressus funebris forests.

Table 2. The impact of thinning methods, seasons, and their interactive effects on the stoichiometry of C, N, and P in C. funebris forests.

Indices	Factor	P
Indices	Factor	Soil	Leaves	Litter
OC	Thinning method	***	***	***
	Season	***	***	*
	Thinning method × season	***	***	***
TN	Thinning method	-	***	***
	Season	***	***	***
	Thinning method × season	-	-	***
TP	Thinning method	-	-	***
	Season	***	*	***
	Thinning method × season	**	-	***
C:N	Thinning method	**	***	***
	Season	***	***	***
	Thinning method × season	***	***	***
C:P	Thinning method	***	***	***
	Season	***	***	***
	Thinning method × season	***	***	***
N:P	Thinning method	*	-	***
	Season	**	***	***
	Thinning method × season	***	***	***

Note: ***: p < 0.001, **: p < 0.01, *: p < 0.05, and -: p > 0.05. OC: organic carbon; TN: total nitrogen; TP: total phosphorus; C:N: carbon/nitrogen; C:P: carbon/phosphorus; and N:P: nitrogen/phosphorus.

Table 3. C, N, and P contents and seasonal variations in the leaf-litter-soil system under different thinning methods.

Indices	Season	Thinning Method
		PC			ET			FG			SF
		Litter	Leaves	Soil	Litter	Leaves	Soil	Litter	Leaves	Soil	Litter	Leaves	Soil
OC	EDS	357.69 ± 7.63 Ba	386.79 ± 10.11 Ac	10.06 ± 1.94 Bc	381.15 ± 9.33 Aab	385.94 ± 10.05 Ab	10.85 ± 0.82 Bb	374.33 ± 4.44 ABb	378.13 ± 5.91 Ad	15.23 ± 1.14 Ab	396.14 ± 9.80 Ab	401.06 ± 5.80 Ab	16.09 ± 1.58 Ab
	LDS	300.16 ± 6.65 Cb	470.30 ± 14.03 Aa	32.23 ± 2.09 Aa	374.51 ± 7.23 Bb	386.00 ± 17.61 Bb	23.01 ± 1.23 Ba	417.06 ± 8.53 ABa	467.36 ± 8.73 Ab	15.35 ± 1.16 Cb	428.76 ± 12.20 Aa	443.32 ± 6.21 Aa	21.61 ± 1.58 Ba
	EWS	374.63 ± 7.02 Ba	490.55 ± 16.99 Aa	20.13 ± 2.19 Ab	406.04 ± 10.11 Aa	438.9 ± 13.24 Ba	20.60 ± 1.36 Aa	335.59 ± 6.35 Cc	497.33 ± 6.59 Aa	12.08 ± 0.94 Bb	364.95 ± 7.48 Bc	405.9 ± 10.04 Bb	14.79 ± 1.54 Bbc
	LWS	363.84 ± 6.55 Ba	430.28 ± 10.82 Ab	19.72 ± 1.31 Ab	405.50 ± 10.91 Aa	427.93 ± 11.80 Aa	11.96 ± 1.07 Bb	404.35 ± 14.79 ABa	411.21 ± 8.15 ABc	18.85 ± 1.44 Aa	382.56 ± 10.49 ABbc	386.94 ± 6.91 Bb	11.48 ± 1.23 Bc
TN	EDS	6.72 ± 0.26 Bd	11.24 ± 0.21 ABb	1.13 ± 0.13 Aab	6.60 ± 0.09 Bc	10.77 ± 0.15 Bb	0.89 ± 0.08 Ab	5.69 ± 0.12 Cd	11.17 ± 0.25 ABb	1.04 ± 0.08 Ab	7.30 ± 0.16 Ad	11.41 ± 0.23 Ab	1.00 ± 0.11 Ab
	LDS	9.56 ± 0.24 Ac	10.65 ± 0.19 ABb	1.45 ± 0.13 Aa	9.23 ± 0.46 Ab	10.25 ± 0.19 Bbc	1.22 ± 0.07 Aa	7.66 ± 0.31 Bc	10.19 ± 0.27 Bc	1.34 ± 0.09 Aa	9.09 ± 0.30 Ac	10.96 ± 0.28 Ab	1.44 ± 0.10 Aa
	EWS	10.27 ± 0.28 ABb	10.81 ± 0.39 ABb	0.98 ± 0.10 Ab	9.79 ± 0.27 Bb	10.10 ± 0.19 Bc	1.01 ± 0.06 Ab	9.96 ± 0.20 ABb	10.48 ± 0.24 ABc	1.14 ± 0.07 Aab	10.57 ± 0.29 Ab	11.14 ± 0.23 Ab	0.96 ± 0.10 Ab
	LWS	11.92 ± 0.16 Aa	12.04 ± 0.26 Ca	1.22 ± 0.11 Aab	11.83 ± 0.34 Aa	11.97 ± 0.24 Ca	1.07 ± 0.07 Aab	12.56 ± 0.23 Aa	12.73 ± 0.22 Ba	1.16 ± 0.07 Aab	11.85 ± 0.38 Aa	13.69 ± 0.22 Aa	1.04 ± 0.10 Ab
TP	EDS	0.46 ± 0.02 Bd	1.04 ± 0.03 Aa	0.84 ± 0.07 Aa	0.46 ± 0.01 Bc	0.84 ± 0.01 Ba	0.53 ± 0.02 Cc	0.52 ± 0.01 ABc	0.87 ± 0.03 Bb	0.49 ± 0.03 Cb	0.31 ± 0.01 Cd	1.08 ± 0.02 Ab	0.69 ± 0.04 Bab
	LDS	0.58 ± 0.02 ABc	0.92 ± 0.02 Ac	0.76 ± 0.02 Aa	0.62 ± 0.02 Ab	1.31 ± 0.44 Aa	0.80 ± 0.01 Aa	0.55 ± 0.02 Bc	0.87 ± 0.02 Ab	0.74 ± 0.02 Aa	0.41 ± 0.02 Cc	0.93 ± 0.02 Ac	1.01 ± 0.32 Aa
	EWS	0.89 ± 0.02 Ab	0.93 ± 0.03 Ab	0.41 ± 0.05 Bb	0.82 ± 0.05 Aa	0.90 ± 0.03 Aa	0.67 ± 0.02 Ab	0.64 ± 0.04 Bb	0.92 ± 0.02 Ab	0.73 ± 0.03 Aa	0.79 ± 0.04 Ab	0.93 ± 0.02 Ac	0.46 ± 0.03 Bb
	LWS	1.07 ± 0.02 Aa	1.08 ± 0.03 Ba	0.73 ± 0.03 Ba	0.91 ± 0.04 Ba	1.04 ± 0.02 Ba	0.79 ± 0.02 ABa	0.84 ± 0.02 Ba	1.25 ± 0.03 Aa	0.74 ± 0.03 Ba	0.89 ± 0.04 Ba	1.26 ± 0.03 Aa	0.83 ± 0.02 Aab

Note: Different capital letters indicate significant differences at the 0.05 level among different thinning methods in the same season (p < 0.05). Different lowercase letters indicate significant differences at the 0.05 level among different seasons for the same thinning methods (p < 0.05).

Table 4. Ecological stoichiometry and seasonal variations in the leaf-litter-soil system under different thinning methods.

Indices	Season	Thinning Method
		PC			ET			FG			SF
		Litter	Leaves	Soil	Litter	Leaves	Soil	Litter	Leaves	Soil	Litter	Leaves	Soil
C:N	EDS	55.25 ± 2.94 Ba	34.61 ± 1.09 Ab	7.61 ± 0.81 Cb	58.16 ± 1.54 Ba	36.00 ± 1.15 Ab	13.12 ± 1.06 Bb	66.27 ± 1.39 Aa	34.16 ± 0.91 Ab	14.89 ± 0.47 ABa	54.72 ± 1.79 Ba	35.40 ± 0.78 Ab	17.32 ± 1.86 Aab
	LDS	31.84 ± 1.15 Dc	44.30 ± 1.44 ABa	26.07 ± 3.71 Aa	42.17 ± 1.84 Cb	37.82 ± 1.79 Cb	19.37 ± 1.02 Ba	55.98 ± 2.31 Ab	46.51 ± 1.65 Aa	11.89 ± 0.94 Cb	47.55 ± 0.99 Bb	40.92 ± 1.15 BCa	15.22 ± 0.59 BCab
	EWS	36.92 ± 1.06 Bb	46.84 ± 2.70 Aa	22.42 ± 2.49 Aa	41.86 ± 1.28 Ab	44.00 ± 1.95 Aa	20.61 ± 1.07 Aa	33.95 ± 0.90 Cc	47.89 ± 1.16 Aa	11.01 ± 1.02 Bb	34.86 ± 0.90 BCc	36.81 ± 1.28 Bb	20.61 ± 5.04 Aa
	LWS	30.60 ± 0.60 Bc	36.22 ± 1.43 Ab	19.17 ± 3.24 Aa	34.57 ± 0.99 Ac	35.94 ± 1.07 Ab	11.17 ± 0.51 Cb	32.06 ± 0.79 Bc	32.50 ± 0.90 Bb	16.52 ± 0.87 ABa	32.59 ± 0.89 ABc	28.43 ± 0.74 Cc	12.03 ± 1.63 BCb
C:P	EDS	798.32 ± 33.10 Ba	376.65 ± 14.36 Bb	13.12 ± 2.54 Cd	833.15 ± 27.72 Ba	461.53 ± 13.64 Aab	21.29 ± 1.92 Bb	730.21 ± 18.77 Ba	445.12 ± 15.96 Ab	34.99 ± 4.15 Aa	1298.66 ± 57.79 Aa	375.05 ± 9.87 Bc	24.15 ± 2.47 Bb
	LDS	527.98 ± 20.87 Cb	517.30 ± 19.42 ABa	42.45 ± 2.71 Ab	607.95 ± 12.22 Cb	421.92 ± 27.79 Cb	20.08 ± 1.73 Ba	778.13 ± 30.78 Ba	541.30 ± 15.67 Aa	21.19 ± 1.72 Cbc	1083.60 ± 47.78 Ab	483.84 ± 13.73 Ba	31.00 ± 3.30 Bab
	EWS	423.29 ± 11.32 Bc	539.97 ± 24.47 Aa	55.89 ± 6.25 Aa	536.12 ± 38.17 Abc	494.70 ± 18.71 Aa	31.58 ± 2.54 Ba	552.47 ± 30.50 Ab	543.46 ± 14.40 Aa	16.96 ± 1.44 Cc	483.02 ± 23.91 ABc	436.78 ± 10.76 Bb	32.96 ± 3.33 Ba
	LWS	343.84 ± 8.90 Bd	404.13 ± 17.22 Ab	28.64 ± 2.88 Ac	465.53 ± 24.48 Ac	415.99 ± 12.51 Ab	15.51 ± 1.60 Bc	483.50 ± 19.27 Ab	333.09 ± 11.10 Bc	26.22 ± 2.30 Ab	445.02 ± 22.44 Ac	310.34 ± 9.38 Bd	14.33 ± 1.74 Bc
N:P	EDS	14.98 ± 0.75 Bb	10.88 ± 0.20 Bb	1.46 ± 0.18 Bb	14.42 ± 0.50 Ba	12.86 ± 0.17 Aa	1.80 ± 0.21 ABa	11.09 ± 0.34 Cc	13.00 ± 0.23 Aa	2.38 ± 0.27 Aa	24.24 ± 1.41 Aa	10.62 ± 0.22 Bb	1.50 ± 0.16 Bb
	LDS	16.76 ± 0.61 Ba	11.67 ± 0.22 Aa	1.91 ± 0.17 ABb	14.82 ± 0.56 BCa	11.34 ± 0.59 Ab	1.55 ± 0.09 Bab	14.24 ± 0.70 Cb	11.73 ± 0.26 Ab	1.83 ± 0.12 ABb	22.85 ± 0.97 Aa	11.89 ± 0.27 Aa	2.09 ± 0.03 Aa
	EWS	11.53 ± 0.25 Cc	11.79 ± 0.40 Aa	2.76 ± 0.31 Aa	12.62 ± 0.68 BCb	11.37 ± 0.32 Ab	1.55 ± 0.12 Cab	16.74 ± 1.27 Aa	11.39 ± 0.24 Ab	1.62 ± 0.13 BCb	13.79 ± 0.50 Bb	11.98 ± 0.00 Aa	2.20 ± 0.26 ABa
	LWS	11.24 ± 0.23 Cc	11.16 ± 0.20 ABab	1.74 ± 0.19 Ab	13.48 ± 0.60 Bab	11.60 ± 0.17 Ab	1.39 ± 0.12 ABb	15.03 ± 0.37 Aab	10.28 ± 0.24 Cc	1.61 ± 0.11 ABb	13.62 ± 0.52 Bb	10.92 ± 0.19 Bb	1.29 ± 0.14 Bb

Note: Different capital letters indicate significant differences at the 0.05 level among different thinning methods in the same season (p < 0.05). Different lowercase letters indicate significant differences at the 0.05 level among different seasons on the same thinning methods (p < 0.05).

Table 5. Relationships between log10-transformed C, N, and P contents and C:N, C:P, and N:P in leaves, litter, and soil for PC, SF, ET, and FG in different seasons.

	Thinning Method	Organ	Variable (X)	Variable (Y)	H	R²	p	Constant	Grade
EDS	PC	leaves	Log(soil C content)	Log(leaf C content)	0.006	0.002	0.86	2.579	strictly homeostatic
			Log(soil N content)	Log(leaf N content)	0.049	0.085	0.213	1.049	strictly homeostatic
			Log(soil P content)	Log(leaf P content)	0	0.107	0.159	0.001	strictly homeostatic
			Log(soil C:N content)	Log(leaf C:N content)	0	0.062	0.29	1.581	strictly homeostatic
			Log(soil C:P content)	Log(leaf C:P content)	0	0.121	0.133	2.618	strictly homeostatic
			Log(soil N:P content)	Log(leaf N:P content)	0	0.072	0.252	1.039	strictly homeostatic
		litter	Log(soil C content)	Log(litter C content)	0.001	0	0.969	2.551	strictly homeostatic
			Log(soil N content)	Log(litter N content)	0	0.054	0.324	0.82	strictly homeostatic
			Log(soil P content)	Log(litter P content)	0	0	0.999	−0.344	strictly homeostatic
			Log(soil C:N content)	Log(litter C:N content)	0.117	0.131	0.117	1.637	strictly homeostatic
			Log(soil C:P content)	Log(litter C:P content)	0	0	0.997	2.896	strictly homeostatic
			Log(soil N:P content)	Log(litter N:P content)	0	0.018	0.570	1.17	strictly homeostatic
	SF	leaves	Log(soil C content)	Log(leaf C content)	0.004	0.001	0.887	2.598	strictly homeostatic
			Log(soil N content)	Log(leaf N content)	0.02	0.012	0.645	1.056	strictly homeostatic
			Log(soil P content)	Log(leaf P content)	0.082	0.044	0.372	0.046	strictly homeostatic
			Log(soil C:N content)	Log(leaf C:N content)	0.039	0.028	0.478	1.5	strictly homeostatic
			Log(soil C:P content)	Log(leaf C:P content)	0.009	0.002	0.859	2.559	strictly homeostatic
			Log(soil N:P content)	Log(leaf N:P content)	0.055	0.075	0.243	1.017	strictly homeostatic
		litter	Log(soil C content)	Log(litter C content)	0.028	0.02	0.556	2.564	strictly homeostatic
			Log(soil N content)	Log(litter N content)	0.026	0.019	0.559	0.863	strictly homeostatic
			Log(soil P content)	Log(litter P content)	0.307	0.18	0.062	−0.565	weakly homeostatic
			Log(soil C:N content)	Log(litter C:N content)	0.053	0.024	0.515	1.671	strictly homeostatic
			Log(soil C:P content)	Log(litter C:P content)	0	0.049	0.348	3.212	strictly homeostatic
			Log(soil N:P content)	Log(litter N:P content)	0	0.076	0.239	1.390	strictly homeostatic
	ET	leaves	Log(soil C content)	Log(leaf C content)	0.07	0.044	0.373	2.513	strictly homeostatic
			Log(soil N content)	Log(leaf N content)	0	0.025	0.505	1.03	strictly homeostatic
			Log(soil P content)	Log(leaf P content)	0	0.003	0.829	−0.082	strictly homeostatic
			Log(soil C:N content)	Log(leaf C:N content)	0	0.028	0.479	1.627	strictly homeostatic
			Log(soil C:P content)	Log(leaf C:P content)	0	0.002	0.835	2.682	strictly homeostatic
			Log(soil N:P content)	Log(leaf N:P content)	0	0.057	0.31	1.114	strictly homeostatic
		litter	Log(soil C content)	Log(litter C content)	0.019	0.004	0.731	2.559	strictly homeostatic
			Log(soil N content)	Log(litter N content)	0.018	0.014	0.625	0.818	strictly homeostatic
			Log(soil P content)	Log(litter P content)	0	0.008	0.707	−0.356	strictly homeostatic
			Log(soil C:N content)	Log(litter C:N content)	0.014	0.002	0.862	1.747	strictly homeostatic
			Log(soil C:P content)	Log(litter C:P content)	0.058	0.024	0.518	2.841	strictly homeostatic
			Log(soil N:P content)	Log(litter N:P content)	0	0	0.971	1.155	strictly homeostatic
	FG	leaves	Log(soil C content)	Log(leaf C content)	0.043	0.052	0.335	2.526	strictly homeostatic
			Log(soil N content)	Log(leaf N content)	0	0.01	0.675	1.046	strictly homeostatic
			Log(soil P content)	Log(leaf P content)	0.279	0.315	0.01	0.024	weakly homeostatic
			Log(soil C:N content)	Log(leaf C:N content)	0.087	0.01	0.67	1.429	strictly homeostatic
			Log(soil C:P content)	Log(leaf C:P content)	0.152	0.283	0.016	2.418	homeostatic
			Log(soil N:P content)	Log(leaf N:P content)	0.078	0.337	0.007	1.088	homeostatic
		litter	Log(soil C content)	Log(litter C content)	0.079	0.264	0.021	2.481	weakly homeostatic
			Log(soil N content)	Log(litter N content)	0	0.014	0.625	0.753	strictly homeostatic
			Log(soil P content)	Log(litter P content)	0.077	0.033	0.447	−0.263	strictly homeostatic
			Log(soil C:N content)	Log(litter C:N content)	0.347	0.251	0.024	2.225	weakly homeostatic
			Log(soil C:P content)	Log(litter C:P content)	0.063	0.089	0.201	2.768	strictly homeostatic
			Log(soil N:P content)	Log(litter N:P content)	0	0.01	0.670	1.049	strictly homeostatic
LDS	PC	leaves	Log(soil C content)	Log(leaf C content)	0.046	0.009	0.698	2.6	strictly homeostatic
			Log(soil N content)	Log(leaf N content)	0.061	0.147	0.096	1.019	homeostatic
			Log(soil P content)	Log(leaf P content)	0.341	0.157	0.083	0.002	weakly homeostatic
			Log(soil C:N content)	Log(leaf C:N content)	0.111	0.087	0.208	1.49	homeostatic
			Log(soil C:P content)	Log(leaf C:P content)	0	0.069	0.264	2.974	strictly homeostatic
			Log(soil N:P content)	Log(leaf N:P content)	0	0.027	0.492	1.072	strictly homeostatic
		litter	Log(soil C content)	Log(litter C content)	0.044	0.018	0.576	2.409	strictly homeostatic
			Log(soil N content)	Log(litter N content)	0	0.009	0.691	0.98	strictly homeostatic
			Log(soil P content)	Log(litter P content)	0	0.025	0.504	−0.261	strictly homeostatic
			Log(soil C:N content)	Log(litter C:N content)	0.231	0.297	0.013	1.814	homeostatic
			Log(soil C:P content)	Log(litter C:P content)	0.001	0.000	0.996	2.715	strictly homeostatic
			Log(soil N:P content)	Log(litter N:P content)	0.023	0.005	0.776	1.213	strictly homeostatic
	SF	leaves	Log(soil C content)	Log(leaf C content)	0	0.059	0.303	2.702	strictly homeostatic
			Log(soil N content)	Log(leaf N content)	0.077	0.054	0.325	1.027	strictly homeostatic
			Log(soil P content)	Log(leaf P content)	0.029	0.025	0.502	−0.032	strictly homeostatic
			Log(soil C:N content)	Log(leaf C:N content)	0.051	0.006	0.74	1.548	strictly homeostatic
			Log(soil C:P content)	Log(leaf C:P content)	0.023	0.015	0.612	2.649	strictly homeostatic
			Log(soil N:P content)	Log(leaf N:P content)	0.098	0.333	0.008	1.048	homeostatic
		litter	Log(soil C content)	Log(litter C content)	0.002	0	0.92	2.626	strictly homeostatic
			Log(soil N content)	Log(litter N content)	0	0.017	0.585	0.962	strictly homeostatic
			Log(soil P content)	Log(litter P content)	0.182	0.234	0.031	−0.376	homeostatic
			Log(soil C:N content)	Log(litter C:N content)	0.03	0.004	0.794	1.64	strictly homeostatic
			Log(soil C:P content)	Log(litter C:P content)	0.071	0.049	0.349	2.925	strictly homeostatic
			Log(soil N:P content)	Log(litter N:P content)	0.046	0.024	0.517	1.339	strictly homeostatic
	ET	leaves	Log(soil C content)	Log(leaf C content)	0	0.03	0.464	2.815	strictly homeostatic
			Log(soil N content)	Log(leaf N content)	0.048	0.018	0.57	1.006	strictly homeostatic
			Log(soil P content)	Log(leaf P content)	0	0.018	0.576	−0.155	strictly homeostatic
			Log(soil C:N content)	Log(leaf C:N content)	0	0.023	0.519	1.751	strictly homeostatic
			Log(soil C:P content)	Log(leaf C:P content)	0.881	0.207	0.044	1.31	plastic
			Log(soil N:P content)	Log(leaf N:P content)	0.014	0.000	0.977	1.019	strictly homeostatic
		litter	Log(soil C content)	Log(litter C content)	0.114	0.124	0.127	2.418	strictly homeostatic
			Log(soil N content)	Log(litter N content)	0	0.044	0.377	0.971	strictly homeostatic
			Log(soil P content)	Log(litter P content)	0.28	0.014	0.619	−0.182	strictly homeostatic
			Log(soil C:N content)	Log(litter C:N content)	0	0.032	0.448	1.767	strictly homeostatic
			Log(soil C:P content)	Log(litter C:P content)	0	0.001	0.895	2.796	strictly homeostatic
			Log(soil N:P content)	Log(litter N:P content)	0	0.067	0.27	1.196	strictly homeostatic
	FG	leaves	Log(soil C content)	Log(leaf C content)	0.041	0.028	0.477	2.62	strictly homeostatic
			Log(soil N content)	Log(leaf N content)	0.007	0.000	0.938	1.004	strictly homeostatic
			Log(soil P content)	Log(leaf P content)	0.471	0.241	0.028	0.001	weakly homeostatic
			Log(soil C:N content)	Log(leaf C:N content)	0.125	0.075	0.244	1.531	strictly homeostatic
			Log(soil C:P content)	Log(leaf C:P content)	0.09	0.084	0.214	2.613	strictly homeostatic
			Log(soil N:P content)	Log(leaf N:P content)	0	0.029	0.473	1.08	strictly homeostatic
		litter	Log(soil C content)	Log(litter C content)	0.021	0.007	0.725	2.594	strictly homeostatic
			Log(soil N content)	Log(litter N content)	0.251	0.186	0.058	0.85	weakly homeostatic
			Log(soil P content)	Log(litter P content)	0.15	0.012	0.641	−0.246	strictly homeostatic
			Log(soil C:N content)	Log(litter C:N content)	0	0.036	0.426	1.855	strictly homeostatic
			Log(soil C:P content)	Log(litter C:P content)	0	0.000	0.926	2.897	strictly homeostatic
			Log(soil N:P content)	Log(litter N:P content)	0.002	0.000	0.990	1.143	strictly homeostatic
EWS	PC	leaves	Log(soil C content)	Log(leaf C content)	0.02	0.002	0.839	2.660	strictly homeostatic
			Log(soil N content)	Log(leaf N content)	0	0.012	0.648	1.026	strictly homeostatic
			Log(soil P content)	Log(leaf P content)	0	0.018	0.569	−0.063	strictly homeostatic
			Log(soil C:N content)	Log(leaf C:N content)	0	0.011	0.654	1.754	strictly homeostatic
			Log(soil C:P content)	Log(leaf C:P content)	0	0.023	0.525	2.813	strictly homeostatic
			Log(soil N:P content)	Log(leaf N:P content)	0.1	0.147	0.095	1.104	homeostatic
		litter	Log(soil C content)	Log(litter C content)	0	0.027	0.492	2.618	strictly homeostatic
			Log(soil N content)	Log(litter N content)	0	0.005	0.759	1.007	strictly homeostatic
			Log(soil P content)	Log(litter P content)	0.011	0.002	0.864	−0.047	strictly homeostatic
			Log(soil C:N content)	Log(litter C:N content)	0	0.019	0.566	1.625	strictly homeostatic
			Log(soil C:P content)	Log(litter C:P content)	0	0.062	0.290	2.705	strictly homeostatic
			Log(soil N:P content)	Log(litter N:P content)	0	0.026	0.495	1.069	strictly homeostatic
	SF	leaves	Log(soil C content)	Log(leaf C content)	0.002	0.000	0.968	2.603	strictly homeostatic
			Log(soil N content)	Log(leaf N content)	0.024	0.034	0.437	1.047	strictly homeostatic
			Log(soil P content)	Log(leaf P content)	0.114	0.185	0.058	0.008	homeostatic
			Log(soil C:N content)	Log(leaf C:N content)	0.013	0.002	0.840	1.545	strictly homeostatic
			Log(soil C:P content)	Log(leaf C:P content)	0	0.018	0.572	2.681	strictly homeostatic
			Log(soil N:P content)	Log(leaf N:P content)	0.001	0.000	0.974	1.077	strictly homeostatic
		litter	Log(soil C content)	Log(litter C content)	0.031	0.032	0.447	2.525	strictly homeostatic
			Log(soil N content)	Log(litter N content)	0.037	0.037	0.418	1.024	strictly homeostatic
			Log(soil P content)	Log(litter P content)	0.12	0.02	0.548	−0.071	strictly homeostatic
			Log(soil C:N content)	Log(litter C:N content)	0.048	0.072	0.253	1.482	strictly homeostatic
			Log(soil C:P content)	Log(litter C:P content)	0	0.018	0.568	2.76	strictly homeostatic
			Log(soil N:P content)	Log(litter N:P content)	0.063	0.072	0.252	1.117	strictly homeostatic
	ET	leaves	Log(soil C content)	Log(leaf C content)	0.143	0.173	0.068	2.824	homeostatic
			Log(soil N content)	Log(leaf N content)	0	0.001	0.888	1.002	strictly homeostatic
			Log(soil P content)	Log(leaf P content)	0	0.015	0.608	−0.07	strictly homeostatic
			Log(soil C:N content)	Log(leaf C:N content)	0	0.114	0.146	1.904	strictly homeostatic
			Log(soil C:P content)	Log(leaf C:P content)	0	0.101	0.172	2.863	strictly homeostatic
			Log(soil N:P content)	Log(leaf N:P content)	0	0.003	0.827	1.056	strictly homeostatic
		litter	Log(soil C content)	Log(litter C content)	0.025	0.005	0.765	2.574	strictly homeostatic
			Log(soil N content)	Log(litter N content)	0.048	0.011	0.664	0.988	strictly homeostatic
			Log(soil P content)	Log(litter P content)	0.94	0.167	0.073	0.063	plastic
			Log(soil C:N content)	Log(litter C:N content)	0.018	0.001	0.876	1.595	strictly homeostatic
			Log(soil C:P content)	Log(litter C:P content)	0.158	0.043	0.378	2.475	strictly homeostatic
			Log(soil N:P content)	Log(litter N:P content)	0.309	0.186	0.057	1.038	weakly homeostatic
	FG	leaves	Log(soil C content)	Log(leaf C content)	0.027	0.032	0.447	2.668	strictly homeostatic
			Log(soil N content)	Log(leaf N content)	0.032	0.014	0.617	1.017	strictly homeostatic
			Log(soil P content)	Log(leaf P content)	0.13	0.059	0.301	−0.018	strictly homeostatic
			Log(soil C:N content)	Log(leaf C:N content)	0	0.027	0.491	1.741	strictly homeostatic
			Log(soil C:P content)	Log(leaf C:P content)	0	0.111	0.151	2.847	strictly homeostatic
			Log(soil N:P content)	Log(leaf N:P content)	0	0.076	0.238	1.066	strictly homeostatic
		litter	Log(soil C content)	Log(litter C content)	0.079	0.139	0.106	2.441	strictly homeostatic
			Log(soil N content)	Log(litter N content)	0	0.004	0.782	0.997	strictly homeostatic
			Log(soil P content)	Log(litter P content)	0.044	0.001	0.893	−0.2	strictly homeostatic
			Log(soil C:N content)	Log(litter C:N content)	0.103	0.064	0.282	1.423	strictly homeostatic
			Log(soil C:P content)	Log(litter C:P content)	0.225	0.159	0.082	2.999	homeostatic
			Log(soil N:P content)	Log(litter N:P content)	0	0.016	0.592	1.219	strictly homeostatic
LWS	PC	leaves	Log(soil C content)	Log(leaf C content)	0.026	0.005	0.777	2.598	strictly homeostatic
			Log(soil N content)	Log(leaf N content)	0.034	0.025	0.503	1.077	strictly homeostatic
			Log(soil P content)	Log(leaf P content)	0.107	0.034	0.439	0.047	strictly homeostatic
			Log(soil C:N content)	Log(leaf C:N content)	0.096	0.059	0.302	1.434	strictly homeostatic
			Log(soil C:P content)	Log(leaf C:P content)	0.049	0.013	0.651	2.53	strictly homeostatic
			Log(soil N:P content)	Log(leaf N:P content)	0.008	0.002	0.837	1.045	strictly homeostatic
		litter	Log(soil C content)	Log(litter C content)	0	0.03	0.463	2.62	strictly homeostatic
			Log(soil N content)	Log(litter N content)	0.011	0.006	0.738	1.075	strictly homeostatic
			Log(soil P content)	Log(litter P content)	0.049	0.011	0.656	0.033	strictly homeostatic
			Log(soil C:N content)	Log(litter C:N content)	0.013	0.004	0.782	1.468	strictly homeostatic
			Log(soil C:P content)	Log(litter C:P content)	0.001	0	0.983	2.531	strictly homeostatic
			Log(soil N:P content)	Log(litter N:P content)	0.064	0.131	0.116	1.037	strictly homeostatic
	SF	leaves	Log(soil C content)	Log(leaf C content)	0.01	0.004	0.782	2.576	strictly homeostatic
			Log(soil N content)	Log(leaf N content)	0	0.001	0.898	1.135	strictly homeostatic
			Log(soil P content)	Log(leaf P content)	0	0.055	0.32	0.08	strictly homeostatic
			Log(soil C:N content)	Log(leaf C:N content)	0.016	0.003	0.834	1.434	strictly homeostatic
			Log(soil C:P content)	Log(leaf C:P content)	0	0.008	0.701	2.513	strictly homeostatic
			Log(soil N:P content)	Log(leaf N:P content)	0	0.025	0.508	1.038	strictly homeostatic
		litter	Log(soil C content)	Log(litter C content)	0.12	0.23	0.032	2.458	homeostatic
			Log(soil N content)	Log(litter N content)	0	0	0.945	1.069	strictly homeostatic
			Log(soil P content)	Log(litter P content)	0	0.013	0.629	−0.077	strictly homeostatic
			Log(soil C:N content)	Log(litter C:N content)	0	0.002	0.837	1.527	strictly homeostatic
			Log(soil C:P content)	Log(litter C:P content)	0.049	0.013	0.63	2.584	strictly homeostatic
			Log(soil N:P content)	Log(litter N:P content)	0	0	0.974	1.127	strictly homeostatic
	ET	leaves	Log(soil C content)	Log(leaf C content)	0.059	0.032	0.449	2.566	strictly homeostatic
			Log(soil N content)	Log(leaf N content)	0	0	0.952	1.076	strictly homeostatic
			Log(soil P content)	Log(leaf P content)	0	0.005	0.769	0.006	strictly homeostatic
			Log(soil C:N content)	Log(leaf C:N content)	0.007	0	0.96	1.544	strictly homeostatic
			Log(soil C:P content)	Log(leaf C:P content)	0.1	0.094	0.19	2.501	strictly homeostatic
			Log(soil N:P content)	Log(leaf N:P content)	0.01	0.003	0.82	1.062	strictly homeostatic
		litter	Log(soil C content)	Log(litter C content)	0.098	0.095	0.185	2.502	strictly homeostatic
			Log(soil N content)	Log(litter N content)	0.155	0.197	0.109	1.068	strictly homeostatic
			Log(soil P content)	Log(litter P content)	0.199	0.012	0.65	−0.03	strictly homeostatic
			Log(soil C:N content)	Log(litter C:N content)	0.156	0.08	0.228	1.374	strictly homeostatic
			Log(soil C:P content)	Log(litter C:P content)	0.032	0.003	0.818	2.619	strictly homeostatic
			Log(soil N:P content)	Log(litter N:P content)	0.045	0.006	0.751	1.115	strictly homeostatic
	FG	leaves	Log(soil C content)	Log(leaf C content)	0.118	0.194	0.052	2.465	homeostatic
			Log(soil N content)	Log(leaf N content)	0	0.069	0.262	1.107	strictly homeostatic
			Log(soil P content)	Log(leaf P content)	0.047	0.006	0.753	0.101	strictly homeostatic
			Log(soil C:N content)	Log(leaf C:N content)	0.035	0.007	0.735	1.467	strictly homeostatic
			Log(soil C:P content)	Log(leaf C:P content)	0	0.000	0.973	2.523	strictly homeostatic
			Log(soil N:P content)	Log(leaf N:P content)	0	0.104	0.165	1.033	strictly homeostatic
		litter	Log(soil C content)	Log(litter C content)	0.078	0.026	0.495	2.503	strictly homeostatic
			Log(soil N content)	Log(litter N content)	0.057	0.041	0.39	1.095	strictly homeostatic
			Log(soil P content)	Log(litter P content)	0.028	0.002	0.853	−0.073	strictly homeostatic
			Log(soil C:N content)	Log(litter C:N content)	0	0.003	0.822	1.529	strictly homeostatic
			Log(soil C:P content)	Log(litter C:P content)	0.026	0.003	0.823	2.642	strictly homeostatic
			Log(soil N:P content)	Log(litter N:P content)	0.075	0.039	0.404	1.16	strictly homeostatic

Note: One-tailed tests with α = 0.1 were used. If the regression was non-significant (p > 0.1), H was set to zero, and the organism was considered “strictly homeostatic”. Species with H = 1 were considered non-homeostatic. All datasets with significant regressions and 0 < H < 1 were categorized as follows: 0 < H ≤ 0.25: “homeostatic”; 0.25 < H ≤ 0.5: “weakly homeostatic”; 0.5 < H ≤ 0.75: “weakly plastic”; and 0.75 < H: “plastic”. For H > 1, an H value close to 1 indicates weak or no stoichiometric homeostasis and an H value much larger than 1 indicates homeostasis.

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Jiang, X.; Yang, J.; Yang, Y.; Yang, J.; Dong, Q.; Zeng, H.; Zhang, K.; Xu, N.; Yuan, J.; Liu, M.; et al. Response of Thinning to C:N:P Stoichiometric Characteristics and Seasonal Dynamics of Leaf-Litter-Soil System in Cupressus funebris Endl. Artificial Forests in Southwest, China. Forests 2024, 15, 1435. https://doi.org/10.3390/f15081435

AMA Style

Jiang X, Yang J, Yang Y, Yang J, Dong Q, Zeng H, Zhang K, Xu N, Yuan J, Liu M, et al. Response of Thinning to C:N:P Stoichiometric Characteristics and Seasonal Dynamics of Leaf-Litter-Soil System in Cupressus funebris Endl. Artificial Forests in Southwest, China. Forests. 2024; 15(8):1435. https://doi.org/10.3390/f15081435

Chicago/Turabian Style

Jiang, Xue, Jingtian Yang, Yulian Yang, Jiaping Yang, Qing Dong, Houyuan Zeng, Kaiyou Zhang, Ning Xu, Jiayi Yuan, Mei Liu, and et al. 2024. "Response of Thinning to C:N:P Stoichiometric Characteristics and Seasonal Dynamics of Leaf-Litter-Soil System in Cupressus funebris Endl. Artificial Forests in Southwest, China" Forests 15, no. 8: 1435. https://doi.org/10.3390/f15081435

APA Style

Jiang, X., Yang, J., Yang, Y., Yang, J., Dong, Q., Zeng, H., Zhang, K., Xu, N., Yuan, J., Liu, M., Li, D., & Wu, Q. (2024). Response of Thinning to C:N:P Stoichiometric Characteristics and Seasonal Dynamics of Leaf-Litter-Soil System in Cupressus funebris Endl. Artificial Forests in Southwest, China. Forests, 15(8), 1435. https://doi.org/10.3390/f15081435

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Response of Thinning to C:N:P Stoichiometric Characteristics and Seasonal Dynamics of Leaf-Litter-Soil System in Cupressus funebris Endl. Artificial Forests in Southwest, China

Abstract

1. Introduction

2. Materials and Methods

2.1. Study Site and Experimental Design

2.2. Laboratory Analysis

2.3. Data Analysis

3. Results

3.1. OC, TN, and TP Contents and Their Seasonal Variation Characteristics in the Leaves, Litter, and Soil of C. funebris Forests

3.1.1. OC, TN, and TP Contents under Different Thinning Methods in the Leaves, Litter, and Soil of Cupressus funebris Forests

3.1.2. OC, TN, and TP Contents in Different Seasons in the Leaves, Litter, and Soil of C. funebris Forests

3.2. C:N:P Stoichiometry and Its Seasonal Variation Characteristics in the Leaves, Litter and Soil of C. funebris Forests

3.2.1. C:N:P Stoichiometry under Different Thinning Methods in the Leaves, Litter, and Soil of C. funebris Forests

3.2.2. C:N:P Stoichiometry in Different Seasons in the Leaves, Litter, and Soil of C. funebris Forests

3.3. Stoichiometric Homeostasis

3.4. Relationships of C, N, and P Contents and Ecological Stoichiometry in the Plant-Litter-Soil System

4. Discussion

4.1. Differences in C, N, and P Contents and Stoichiometry in Leaves, Litter, and Soil

4.2. Effects of Season on C, N, and P Contents and Stoichiometry in Leaves, Litter, and Soil

5. Conclusions

Author Contributions

Funding

Data Availability Statement

Conflicts of Interest

References

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