Changes in soil chemical properties and their spatial distribution after logging and conversion to oil palm plantation in Sabah (Borneo)

Trevan Flynn; Jiri Tuma; Tom M Fayle; Hana Veselá; Jan Frouz

doi:10.1017/S026646742300024X

Changes in soil chemical properties and their spatial distribution after logging and conversion to oil palm plantation in Sabah (Borneo)

Published online by Cambridge University Press: 10 October 2023

and

Trevan Flynn*: Affiliation:
Biology Centre of the Czech Academy of Sciences, Institute of Soil Biology and Biogeochemistry, Na Sádkach 7, 370 05, České Budějovice, Czech Republic Swedish University of Agriculture Sciencies, Uppsala, SE-750 07, Sweden
Jiri Tuma: Affiliation:
Biology Centre of the Czech Academy of Sciences, Institute of Soil Biology and Biogeochemistry, Na Sádkach 7, 370 05, České Budějovice, Czech Republic
Tom M Fayle: Affiliation:
Biology Centre of the Czech Academy of Sciences, Institute of Entomology, Branišovská 1160/31, 370 05, České Budějovice, Czech Republic School of Biological and Behavioural Sciences, Queen Mary University of London, London, UK
Hana Veselá: Affiliation:
Institute for Environmental studies, Charles University, Benátská 2, 12800 Prague, Czech Republic
Jan Frouz: Affiliation:
Biology Centre of the Czech Academy of Sciences, Institute of Soil Biology and Biogeochemistry, Na Sádkach 7, 370 05, České Budějovice, Czech Republic Institute for Environmental studies, Charles University, Benátská 2, 12800 Prague, Czech Republic
*: Corresponding author: Trevan Flynn; Email: trevan.flynn@slu.se

Article contents

Abstract
Introduction
Materials and methods
Results
Discussion
Conclusion
Supplementary material
Financial support
Competing interests
Ethical statement
References

Rights & Permissions

Abstract

Conversion of primary forest into oil palm plantations is common in tropical countries, affecting soil properties, ecosystem services and land-use management. However, little is known about the short-range spatial soil distribution that is important for soil scientists, ecologists, entomologists, mycologists or microbiologists. In this study, seven soil properties (pH, EC (µS/m), P (mg/kg), NO3- (mg/kg), N%, C% and C:N) were measured to quantify the spatial autocorrelation across primary forest, selectively logged forest and oil palm plantation in Sabah, Malaysian Borneo. Local variograms were calculated (range ∼5 m) to determine the short-range variation, and a decision tree as well as principal component analysis were implemented to determine if the overall (global) mean differed between land uses. As hypothesised, oil palm soils deviated the most from primary forest soils, which had more fluctuating variograms and in general, a shorter range. Oil palm plantations also showed a difference in the global mean except for electrical conductivity. Selectively logged forests also differed in their short-range spatial structure; however, the global mean and variance remained similar to primary forest soil with the exception of labile phosphorus and nitrate. These results were attributed to initial plantation development, removal of topsoil, fertiliser application and topography.

Keywords

Borneo land-use change logging oil palm SAFE project soil properties spatial autocorrelation

Type: Research Article
Information: Journal of Tropical Ecology , Volume 39 , 2023 , e36

DOI: https://doi.org/10.1017/S026646742300024X [Opens in a new window]
Creative Commons: This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright: © The Author(s), 2023. Published by Cambridge University Press

Introduction

Anthropogenic land-use change often affects soil properties over a shorter time span than natural factors such as climate, topography, vegetation, age and parent material (Amundson and Jenny Reference Amundson and Jenny1991; Winkler et al. Reference Winkler, Fuchs, Rounsevell and Herold2021; Yaalon and Yaron Reference Yaalon and Yaron1966). In the tropics, logging of primary forests and conversion into agricultural land is widespread (Benhin Reference Benhin2006; Kleinschmit et al. Reference Kleinschmit, Ferraz Ziegert and Walther2021; World Resource Institute 1991), which reduces the quality and quantity of natural resources (Guerrero et al. Reference Guerrero, Gomes and Lollo2020). This topic has been widely studied; however, little is known about the short-range variation of soil chemical properties and hence, biodiversity, ecology, entomology, microbiology, mycology and many other ecosystem services.

It is known that the conversion to oil palm plantation reduces numerous ecosystem services provided by soil. For example, after logging, areas that are leveled (along with roads) increase run-off causing erosion (Van Wambeke Reference Van Wambeke1992; Hartanto et al. 2003), and with the removal of topsoil and drainage, the soil organic matter (SOM) content is reduced (Krejčová et al. Reference Krejčová, Vicentini, Flynn, Mudrák and Frouz2021; Andriesse and Schelhaas Reference Andriesse and Schelhaas1987). This causes loss of fertility (Dressen et al. Reference Dressen, Buurman and Permadhy1976) and an increase in soil compaction (Lal Reference Lal2021; Lyczak et al. Reference Lyczak, Kabrick and Knapp2021). These losses further cause a reduction in biodiversity (World Resource Institute 1991), can affect soil processes such as bioturbation (Tuma et al. Reference Tuma, Fleiss, Eggleton, Frouz, Klimes, Lewis, Yusah and Fayle2019), increase evapotranspiration (Uhl et al. Reference Uhl, Clark, Clark and Murphy1981) and cause pollution (Henderson and Osbourne Reference Henderson and Osbourne2000; Koh and Wilcove Reference Koh and Wilcove2007). This reduces the provisioning of ecosystem services such as water purification, food production, livelihood, climate regulation and biodiversity (FAO and UNEP 2020).

The soil properties that provide these functions and services are correlated in geographic space. This spatial autocorrelation reflects processes that help form soils and informs proper land-use management. The most common geostatistical technique to model the spatial structure of soil properties is known as a variogram. A variogram generalises a random process over the distance between point pairs (Matheron Reference Matheron1963). A variogram shows the short-range variance or measurement errors (nugget), the total semivariance (sill) and the distance over which the property is no longer correlated in geographic space and/or time (range).

Oil palm plantations need the least area per litre of any vegetable oil (Basiron Reference Basiron2007; Poore and Nemecek 2018), provide a low financial cost to the consumer and high profitability for the producer, and are a driver of economic development (Qaim et al. Reference Qaim, Sibhatu, Siregar and Grass2020). Consequently, oil palm expansion is driving deforestation in Southeast Asia (Henderson and Osborne Reference Henderson and Osbourne2000; Koh and Wilcove Reference Koh and Wilcove2007; Palm Reference Palm2005). For example, in Malaysian Borneo, from 1990 to 2018, oil palm was responsible for decreasing the area of primary forest by 13% in Sarawk and 16% in Sabah and decreasing the area of peat forests from by 21% in Sarawak and 19% in Sabah (Jaafar et al. Reference Jaafar, Said, Maulud, Uning, Latif, Kamarulzaman, Mohan, Pradhan, Saad, Broadbent, Cardil, Silva and Takriff2020).

In the state of Sabah, Malaysian Borneo, oil palm plantations are generally established from areas that were originally selectively logged forests (Osman et al. Reference Osman, Phua, Ling and Kamlun2012), where trees with the highest economic value were harvested first and then fast-growing trees in the following round of harvest. Once logged, the areas were left to naturally regenerate, often for multiple decades. However, even with regulations, logged forest mainly consists of pioneering trees and the forests were left degraded (Reynolds et al. Reference Reynolds, Payne, Sinun, Mosigil and Walsh2011). These areas were converted to oil palm by mechanically levelling, draining and/or removing the topsoil as well as adding infrastructure, fertiliser, herbicides and pesticides.

The aim of this study was to determine if land use alters soil chemical properties. It is hypothesised that the largest change will be seen in the short-range spatial autocorrelation in oil palm and logged forest relative to primary forest soils. Additionally, it is believed that the global mean will be significantly different for oil palm but similar for logged forest and primary forest soils.

Materials and methods

Study sites

The research site (Figure 1a, b) forms part of the Stability of Altered Forest Ecosystems (SAFE) project in the state of Sabah, Borneo Malaysia (Ewers et al. Reference Ewers, Didham, Fahrig, Hector, Holt, Kapos, Reynolds, Sinun, Snaddon and Turner2011; Tuma et al. Reference Tuma, Fleiss, Eggleton, Frouz, Klimes, Lewis, Yusah and Fayle2019) approximately 4 $^\circ $ 40’ 27” N and 117 $^\circ $ 31’ 40” E with an elevation ranging from 370 to 500 m. The climate is characterised by an isohyperthermic soil temperature and an udic soil moisture regime with a mean annual temperature of 26.7 and mean annual precipitation of ∼2,650 mm (Kumagai and Porporato Reference Kumagai and Porporato2012; Kuntashula et al. Reference Kuntashula, Chabala and Mulenga2014; Walsh and Newbery Reference Walsh and Newbery1999). The dominant soil types in the region are Typic/Humic Hapludults and Kandiudults on hilly positions with various types of Histosols, Inceptisols and Entisols in lower regions (Sakurai Reference Sakurai1999). The geology is characterised by a metamorphic complex of amphibolites, and gneiss intruded by granite, gabbro, and ultramafic rock (Haile and Lee Reference Haile and Lee1997).

Figure 1. Site within the surrounding area (a), sampling clusters (b) and sampling orientation in each cluster extending from the GPS placed at the black dot (c). Numbers represent how the coordinates were manually entered for each observation. PF: Primary Forest; LF: Logged Forest; OP: Oil Palm.

Three land uses were sampled before any SAFE project-related experimental fragmentation. The primary forest has been under conservation since 1976 and has experienced little to no human disturbances. This area lies on both eastern and western hill slopes and has a mean elevation of 431 m, and Shorea and Diospyros tree genera predominate. The logged forest areas were on western sloping positions, has a mean elevation of 450 m, had been selectively logged at least twice (between 1970–1990 and 1999–2010) and was previously logged for Dryobalanops, Dipterocarpus, Shorea and Parashorea tree genera. Only past signs of logging have been observed and secondary forest now predominates. Oil palm plantations were found almost continuously in slightly lower elevation areas (mean elevation of 385 m) such as foot slopes and valleys, planted in 2006 and are fertilised twice a year with diammonium phosphate ((NH₄)₂HPO₄)), potassium chloride (KCl), ammonium sulphate ((NH₄)₂,SO₄), magnesium sulphate (MgSO₄) and disodium tetraborate octahydrate (Na₂[B₄O₅(OH)₄]·8H₂O) (Elias et al. Reference Elias, Robinson, Both, Goodall, Majalap-lee, Ostle and Mcnamara2020). However, the amount of fertiliser applied was not known. The oil palm site is managed by the company Benta Wawasan Sdn. Bhd. (Ewers et al. Reference Ewers, Didham, Fahrig, Hector, Holt, Kapos, Reynolds, Sinun, Snaddon and Turner2011) and consist of Elaeis guineensis monocultures with a low, open canopy and sparse under vegetation.

Twenty-two sampling clusters (Figure 1b) were dug on the three land-use areas (8 in primary forest, 6 in logged forest and 8 in oil palm). Each sampling cluster comprised 10 samples (n = 220), 1 m apart, taken in the shape of a right triangle as shown in Figure 1c. Since the sample locations within each cluster were inside the precision of the GPS (5 m), the coordinates were manually entered.

Composite soil samples (average of total depth) down to 20 cm in depth were taken, were homogenised by hand (in the field by mixing the soil by hand), then sieved (2 mm), and oven-dried at 70–80â„ƒ for 3–5 days. Seven soil chemical properties were measured: pH, EC (µS/m), P (mg/kg), NO₃ ^- (mg/kg), N%, C% and C:N. The pH and EC were measured in a 1:2.5 soil to water solution after mechanically shaking for an hour and filtered. A 1:100 soil to Mechlich-3 solution was shaken for 30 min and filtered to measure labile P with a UV Genesys 10 Thermo spectrometer at an 889 nm wavelength as described by Watanabe and Olsen (Reference Watanabe and Olsen1965). To determine NO₃ ^-, samples were extracted in deionised water (1:5 soil:water ratio) and filtered, and the NO₃ ^- was determined using a colorimetric method (Zbíral et al. Reference Zbíral, Honsa and Malý1997). The same filtrate was used to determine pH and conductivity using a glass and potentiometric electrode. Total organic C and N percent were measured through a Flash 2000 Thermo Scientific elemental analyser.

Data analysis

A flow chart of the process used to determine the variability of the soil properties on the site is shown in Figure 2. From the observations, variograms were created for each soil property and the model fit was estimated through ordinary kriging. The difference in mean soil properties between land uses was then calculated through a conditional inference tree (ctree). Then, principal component analysis (PCA) was conducted to determine the variance. To determine the correlations between soil properties, a correlation matrix was constructed for all soil properties within a land use. All statistical analysis was conducted in R software (R Core Team 2017).

Figure 2. Flow chart of the process used to capture the variation of measured soil properties.

Spatial autocorrelation

Before developing the variograms, data for each soil property were checked for normality and heterogeneity through a Shapiro–Wilk test (Shapiro and Wilk Reference Shapiro and Wilk1965) and Levene’s test (Levenes Reference Levenes1960), respectively. Variograms were then constructed to determine the spatial structure of individual soil properties within each land use. Variograms are derived from the semivariance between point pairs with distance. Mathematically, this is described as follows (Matheron Reference Matheron1963):

$$\gamma \left( h \right) = {1 \over {2\left| {N\left( h \right)} \right|}}\sum\limits_{N\left( h \right)} {{{({z_i} - {z_j})}^2}}, $$

where $\gamma \left( h \right)$ is the semivariance at distance $h$ , $N\left( h \right)$ is the set of all point pairs with distance, and ${z_i}$ and ${z_j}$ are values of the soil property at distance i and j, Therefore, $h$ is the product of i and j. This is known as an empirical variogram from which theoretical variograms are computed from.

Theoretical variograms were then fit using residual maximum likelihood (REML; Bartlett Reference Bartlett1937) to automatically fit the nugget ( $h = 0$ ), the sill ( $h = \;\mathop {\lim }\limits_{h\; \to \infty } \gamma \left( h \right))$ and the range. This method was used because it is an unbiased estimate of variance, it does not need homogenous variance, its residuals can be correlated and it is computationally efficient (Johnston Reference Johnston1972). Four theoretical variogram models were tried for each property including spherical (Sph), exponential (Exp), gaussian (Gau) and wave (Wav) models. A more detailed explanation of these variogram models can be found in the supplementary material A1. The final models were selected through ordinary kriging (Matheron Reference Matheron1963) with leave-one-out cross-validation. The model with the lowest root mean squared error (RMSE) for each land use was selected as the final model.

To compare soil properties on different land uses, the spatial autocorrelation of each variogram was evaluated on their spatial dependence, which involved the ratio of the nugget, sill and range (NSR). In this paper, the NSR is as follows:

$${\rm{NSR}} = {{{\rm{Nugget}}} \over {\left( {{\rm{Sill}} + {\rm{Range}}} \right)}},$$

The nugget, sill and range were scaled from 0.1 to 0.9, so each variable had equal weight (e.g., no large range or sill). The smaller the NSR is, the greater the spatial autocorrelation. This spatial dependency measure was used because it incorporates the three common aspects of a variogram into one simple equation (x and y axis), where the commonly used nugget:sill ratio to compare variograms leaves out the range.

Mean soil properties

The means of the soil properties were evaluated between each land use through a type of decision tree known as a ctree (Hothorn et al. Reference Hothorn, Hornik and Zeileis2006; Zeileis and Hothorn Reference Zeileis and Hothorn2015). A ctree recursively splits the data on the independent variable to make the dependent variable more homogenous. It does so until no more splits are possible in the ctree, or a user-defined significance value (p-value) has been reached (Hastie et al. Reference Hastie, Tibshirani and Friedman2009). The ctree was developed with a Bonferroni test at each split with a p-value of 0.01 as the stopping criteria. A ctree was used because they are easy to interpret, do not need linear data, perform well with small sample sizes and are non-parametric (Hothorn et al. Reference Hothorn, Hornik and Zeileis2006; Zeileis and Hothorn Reference Zeileis and Hothorn2015).

After the ctree was grown, the residuals for each model were checked for normality, heterogeneity and spatial autocorrelation. If there was spatial autocorrelation, the residuals were kriged and added back to the model, and the distributions were checked again. It should be noted that the models were only used to see the statistically significant differences and not to predict the soil properties.

Soil property correlations

Before PCA analysis (Pearson Reference Pearson1901), the soil properties were normalised $\left( {\mathop \to \limits_{0,1} } \right)$ so that all properties had an equal weight in the covariance matrix. The soil properties were evaluated on how much each contributed to the variability and how well the soils represent the principal components (PCs), also known as Cos². The contribution is the percentage a soil property contributes to the total variance in a PC and ranges from 0 to 100%. The further away the soil property is from the origin (coordinates = 0,0), the more that property contributes to the variance explained. A larger Cos² implies a better representation within a PC and, hence, the more important the property is. Cos² is simply the sum of the squared coordinates of a soil property on a biplot.

A correlation matrix was created to determine how the soil properties correlate with each other within a land use. Correlations were determined using the REML model as described in Sec 2.2.1. p-Values and Pearson’s correlation coefficient (R²) were used to interpret the correlations.