利用機理性模型和機器學習預測陸地生態系土壤有機碳的穩定性

陳品華; Pin-Hua Chen

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/101726

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	郭大孚	zh_TW
dc.contributor.advisor	Ta Fu Dave Kuo	en
dc.contributor.author	陳品華	zh_TW
dc.contributor.author	Pin-Hua Chen	en
dc.date.accessioned	2026-02-26T17:02:43Z	-
dc.date.available	2026-02-27	-
dc.date.copyright	2026-02-26	-
dc.date.issued	2026	-
dc.date.submitted	2026-01-20	-
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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/101726	-
dc.description.abstract	土壤碳封存被認為是實現長期碳儲存與碳中和的潛在重要策略。本研究針對未施行主動減碳管理措施之農地、森林與草地生態系，系統性分析土壤有機碳（SOC）的穩定性與釋放行為，透過整合現地量測之土壤 CO2 通量（F）、由分解速率常數（k）推估之平均停留時間（MRT），並建立 k 與 F 之預測模型。結果顯示，在 0.2 m 表層土壤中（n = 4,963），超過 82% 的觀測值其 MRT 低於 10 年，四分位距（Q1–Q3）集中於 2–8 年，顯示表層 SOC 週轉速率偏快。相關分析與模型結果一致指出，溫度為控制 CO2 排放最關鍵之環境因子，當溫度上升 10 °C 時，F 與 k 分別增加約 1.6–2.3 倍。相較之下，碳氮比（CN）、黏土含量與 pH 雖可能影響 SOC 穩定性，但因資料量有限且時間解析度不足，其效應難以量化。模型選擇結果顯示，CN 與 pH 分別為農地與森林 CO2 排放之重要控制因子。外部驗證顯示，約 80–90% 的預測值落於三倍誤差範圍，顯示機理模型具有良好預測能力；相較之下，機器學習模型雖可提高模型準確度，但伴隨明顯過度參數化。將模型應用於台灣尺度後發現，不同縣市森林（n = 784）與農地（n = 102）之 MRT 介於 2.2–4.1 年，顯示表層 SOC 具有高度快速週轉特性。其空間分布進一步以 ArcGIS 呈現，證實本模型可有效整合於碳管理與策略規劃中。整體而言，本研究指出，在缺乏主動管理措施下，農地、森林與草地之表層 SOC 難以作為有效的長期碳儲存來源；而環境因子對 MRT 的關係分析，仍受限於場址差異性，以及缺乏高品質且具高時間解析度之 CO2 通量與土壤性質資料。	zh_TW
dc.description.abstract	Soil sequestration has been suggested as a potentially important strategy for long-term carbon storage and achieving carbon neutrality. This study investigates the stability and release of soil organic carbon (SOC) cropland, forest, and grassland without active carbon mitigations. This is achieved by examining field collected CO2 flux (F), deriving mean residence time (MRT) from decomposition rate constant (k) and constructing predictive models of k and F. Results show that for SOC within the upper 0.2 m soil layer (n = 4,963), more than 82% of observations exhibit MRT values below 10 years, with interquartile (Q1–Q3) ranges of 2–8 years across croplands, forests, and grasslands. Correlation analysis and models both identify temperature as the most critical factor on CO2 efflux across the ecosystems, with a 10 °C increase resulting in a 1.6–2.3 fold rise in F and k. while carbon to nitrogen ratio (CN), clay content, and pH are potentially important determinants of carbon stability, their effects are less quantifiable as their data are more limited and inadequately resolved temporally. Model selection suggests that CN and pH may be important for surficial CO2 efflux in croplands and forests, respectively. External validation shows that 8090% of in situ prediction fall within a threefold error range, indicating good performance of the mechanistic model. Machine learning based models are found to be statistically inferior to mechanistic models, with better accuracy achieved at the cost of substantial over-parameterization. Application of the developed mechanistic models reveals rapid surface SOC turnover in Taiwan, with MRT ranging from 2.2 to 4.1 years across forest (n=784) and cropland (n=102) soils in different counties. The assessed MRT are spatially mapped using ArcGIS, illustrating the mechanistic models can be readily integrated into carbon management practice or strategic planning. Overall, this study demonstrates that surface SOC in cropland, forest, and grassland is not an effective long-term carbon storage without active mitigative management practices. Further delineation of environmental factors on MRT is constrained by site-specificity and the lack of high-quality and high-resolution temporal data of both CO2 efflux and soil properties.	en
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dc.description.tableofcontents	口試委員會審定書 I 誌謝 II 摘要 III Abstract V Contents VII List of Figures XII List of Tables XXI Chapter 1 Introduction 1 1.1 Background 1 1.2 Research Objectives 3 Chapter 2 Literature Review 5 2.1 The Importance of Soil Carbon Stability 5 2.2 Environmental Factors Potentially Affecting Soil Organic Carbon Stability 6 2.2.1 Soil Temperature 6 2.2.2 Soil Moisture 8 2.2.3 Soil Carbon-to-Nitrogen Ratio 9 2.2.4 Clay 10 2.2.5 SOC Concentration 11 2.2.6 Soil Porosity 12 2.2.7 pH 12 2.2.8 Priming effect 13 2.2.9 Effects of Tillage and Crop Rotation 14 2.3 Differences in the Stability of C3- and C4-Derived SOC 15 2.4 Determination of Calculating Soil Organic Carbon Stock and Mean Residence Time 17 2.4.1 Determination of Calculating SOC Stock: Equivalent Soil Mass vs. Fixed Depth 17 2.4.2 Determination of Calculating Mean Residence Time 18 2.5 Soil Organic Carbon Modeling Pathways: Mechanistic vs. Machine Learning 20 2.5.1 Mechanistic Models 20 2.5.2 Machine Learning 22 2.6 Potential Sources of Uncertainty in Modeling Soil Carbon Stability 24 Chapter 3 Materials and Methods 26 3.1 Data Collection 26 3.2 Data Processing 29 3.2.1 Unit Conversion 29 3.2.2 Linear Interpolation of Soil Temperature and Soil Moisture 30 3.2.3 Estimating Soil Porosity and Bulk Density 31 3.3 Software and Programming Environment 32 3.4 Calculation of In-situ Soil Organic Carbon Decomposition Rate Constant 32 3.5 Calculation of Labtory Soil Organic Carbon Decomposition Rate Constant 34 3.6 Classification by C3 and C4 Types 37 3.7 Model Description 38 3.7.1 Model Building Framework 38 3.7.2 Fixed Ratio of Training and Total Dataset in the Modeling Process 40 3.7.3 Mechanistic Nonlinear Models 41 3.7.4 Linear Models 45 3.7.5 Machine Learning 46 3.8 Model Error Evaluation and Selection Criteria 50 3.9 Correlation and Multicollinearity 51 3.10 Validation of the logk and logF Model under In-situ and Laboratory Data 52 3.11 Application of the logF and logk Model to Regional Soil Data in Hillside of Taiwan 53 3.12 Model Assumption 54 3.13 Radar Chart Construction 55 Chapter 4 Results and Discussion 57 4.1 Data Overview 57 4.1.1 Dataset Description and Basic Statistics 57 4.1.2 Evaluation of the Representativeness of Soil CO2 Flux Based on Literature-Reported Ranges 59 4.1.3 Distribution Characteristics and Data Continuity of Environmental Factors 61 4.1.4 Sensitivity of MRT to Different Soil Depth Assumptions 62 4.1.5 MRT Distribution Across Different Ecosystems 64 4.1.6 Ecosystem Differences in the Median of logF, logk, and M0.2m 66 4.1.7 Comparison of Environmental Factor Distributions Across Different MRT Groups 70 4.1.8 Correlation and Collinearity Among Environmental Factors 73 4.1.9 Assessing Environmental Factors of MRT with Linear Regression 75 4.2 Training-Testing Ratio for logF and logk Modeling 78 4.3 Evaluation of Cross-ecosystem Model Performance 80 4.4 Model Selection and Compare Mechanistic and Machine Learning with AIC 82 4.4.1 Model Selection of Linear Models 82 4.4.2 Model Selection of Mechanistic Nonlinear Models 89 4.4.3 Model Selection of Machine Learning and AIC Penalty for Over-Parameterization 96 4.4.4 Integrated Comparison of Mechanistic and Machine Learning 101 4.5 Mechanistic Interpretation of Environmental Factors 106 4.5.1 Interpretive Limitations of Mechanistic Linear Models 106 4.5.2 Mechanistic Interpretation of Correction Functions in Mechanistic Models for logF and logk 109 4.6 Validation and Application of the Mechanistic Model 123 4.6.1 Validation of the Minimum-AIC Model Using In-situ and Laboratory Datasets 123 4.6.2 Validation of Ecosystem-Specific Models Using Taiwan and South China Datasets 127 4.6.3 Model Application to Hillside Data in Taiwan 130 4.7 Limitations of Model 133 Chapter 5 Conclusions and Suggestions 134 5.1 Conclusions 134 5.2 Future Works 136 Chapter 6 References 137 Chapter 7 Appendix 167 7.1 Estimation of Bulk Density Using Empirical Equation 167 7.2 Variance Inflation Factor for Environmental Factors 169 7.3 Training and Testing Results of Linear Models for logF and logk Across Different Ecosystems 171 7.4 Training and Testing Results of Mechanistic Nonlinear Models for logF and logk Across Different Ecosystems 173 7.5 Training and Testing Results of logF and logk Models Across Ecosystems Using SVR, RF, and XGBoost 176 7.6 Variation of AIC and RMSE with the Number of Fitting Parameters for the ML logF and logk models. 180 7.7 Evaluation of the Relative Importance of Environmental Factors Across Machine Learning Algorithms Using Permutation Importance for the logF and logk Models 186 7.8 Radar Plots of logF and logk Models in Different Ecosystems 188 7.9 Soil Temperature Monitoring Sites in Taiwan 190 7.10 Predicted Annual Soil Carbon emissions, Shallow Soil Decomposition rate constants, and SOC contents in Hillside of Taiwan 191 7.11 Temperature correction functions for logF and logk under different ecosystems 193 7.12 Spatial Distribution of the Validation Data and Training Data 194 7.13 Number of Imputed Values Required for Model Application to Taiwan and Taiwan-Like Datasets 196 7.14 Model Application to Cropland Data in Taiwan 198	-
dc.language.iso	en	-
dc.subject	土壤有機碳	-
dc.subject	降解速率常數	-
dc.subject	CO2 通量	-
dc.subject	機理性模型	-
dc.subject	機器學習	-
dc.subject	陸域生態系	-
dc.subject	SOC	-
dc.subject	Decomposition Rate Constant	-
dc.subject	CO2 flux	-
dc.subject	Mechanistic Model	-
dc.subject	Machine Learning	-
dc.subject	Terrestrial Ecosystem	-
dc.title	利用機理性模型和機器學習預測陸地生態系土壤有機碳的穩定性	zh_TW
dc.title	Predicting Stability of Soil Organic Carbon in Terrestrial Ecosystems with Mechanistic Models and Machine Learning	en
dc.type	Thesis	-
dc.date.schoolyear	114-1	-
dc.description.degree	碩士	-
dc.contributor.oralexamcommittee	鄭智馨;童心欣	zh_TW
dc.contributor.oralexamcommittee	Chih-Hsin Cheng;Hsin-hsin Tung	en
dc.subject.keyword	土壤有機碳,降解速率常數CO2 通量機理性模型機器學習陸域生態系	zh_TW
dc.subject.keyword	SOC,Decomposition Rate ConstantCO2 fluxMechanistic ModelMachine LearningTerrestrial Ecosystem	en
dc.relation.page	200	-
dc.identifier.doi	10.6342/NTU202600024	-
dc.rights.note	同意授權(全球公開)	-
dc.date.accepted	2026-01-20	-
dc.contributor.author-college	工學院	-
dc.contributor.author-dept	環境工程學研究所	-
dc.date.embargo-lift	2028-02-16	-
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