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The paper is a broad review of "intelligent rock mechanics" at the intersection of AI and rock engineering. It traces the historical progression from early neural networks and SVMs to deep learning (CNNs, LSTMs, GANs, transformers), discusses emerging physics-informed and graph-based methods, and briefly notes nascent roles for LLMs. The review synthesizes applications in: (i) data-driven estimation of mechanical properties (UCS, elastic moduli, velocities), (ii) image-based microstructure reconstruction and fracture detection (CNNs, VAEs/GANs, point-cloud methods, hybrid deterministic–stochastic DFN modeling), (iii) AI-assisted constitutive modeling and PDE solution (LSTM/TCN-based constitutive surrogates, PINNs and variants, hybrid FEM/DEM integration), and (iv) engineering applications (rock mass classification, rockburst/geohazard prediction, tunneling/boring operations, slope stability, and other emerging tasks). It closes with challenges (data scarcity, interpretability/trust, computational efficiency, workflow integration, model maintenance) and a future outlook toward hybrid physics–data frameworks and digital twins.
Cross‑Modal Consistency: [32]/50
Textual Logical Soundness: [25]/30
Visual Aesthetics & Clarity: [10]/20
Overall Score: [67]/100
Detailed Evaluation (≤500 words):
1. Cross‑Modal Consistency
• Visual ground truth
– Figure 1: Block diagram of an AI framework for rock mechanics (blue/yellow modules; arrows showing data/knowledge flow).
– Figure 2: (a) Longitudinal geologic/elevation profile with tunnel line; (b) Chainage progress schematic (excavated/monitored); (c) Tunnel cross‑section (7.2 m×6.2 m); (d) Face photo with structural planes/rockburst area; (e) LSTM multitask predictor (events/energy/volume); (f) LSTM classifier (five intensity classes); (g) Matrix of blasting cycles vs warning results.
– Figure 3: (a) MLP with physics/data/coordinate loss for parameter inversion; (b) Plaxis 3D model and surface sampling; (c) 3D surface of predicted ground deformation; (d) 2D heatmap of deformation.
• Major 1: Many sub‑figures are presented without an identifying figure number/caption in the main text, hindering reference. Evidence: Only “Figure 1” is cited (“as shown in Figure 1”); later panels (Fig. 2(a–g), Fig. 3(a–d)) appear uncited.
• Major 2: Label discontinuity within Figure 2 (missing explicit (c),(d) labels in text; (e),(f) jump), creating ambiguity. Evidence: Panels show (a),(b),(e),(f) marks while the cross‑section and photo are unlabeled.
• Minor 1: Bibliometric claim lacks a supporting visual/table. Evidence: “the term ‘machine learning’ now surpasses ‘artificial intelligence’ in frequency” in Sec. 1 without a figure.
• Minor 2: Some symbols in panels (e.g., PN, PB, … in Fig. 2f) are not defined in text near first appearance. Evidence: Fig. 2(f) output nodes labeled “None PN … Extremely intense PXi”.
2. Text Logic
• No Major issues found.
• Minor 1: A few long, multi‑clause sentences reduce readability but do not break arguments. Evidence: Sec. 5.3 first paragraph contains multi‑method list in one sentence.
• Minor 2: The bibliometric methodology is described, but numerical outcomes or counts are not reported. Evidence: Sec. 1 “analyzed for publication trends, keyword co‑occurrence…”
3. Figure Quality
• Major 1: Critical text/legends are illegible at print size in most panels. Evidence: Fig. 1 dense small fonts; Fig. 2(a–g) axes/legends; Fig. 3(b–d) color bars/axes unreadable.
• Major 2: Several quantitative plots lack visible units/ticks at readable size (e.g., elevation scale, deformation axes). Evidence: Fig. 2(a), Fig. 3(c–d).
• Minor 1: Colour palettes are acceptable but some heatmaps lack annotated extrema or reference points. Evidence: Fig. 3(d).
Key strengths:
Key weaknesses:
Recommendations:
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This paper presents a comprehensive review of the application of artificial intelligence (AI) and machine learning (ML) techniques in rock mechanics and geotechnical engineering. The authors meticulously trace the evolution of AI methodologies, from early neural networks to modern deep learning architectures, and their increasing integration into various aspects of rock engineering. The paper highlights the transformative potential of AI in addressing long-standing challenges in the field, such as the complex behavior of geological materials, anisotropy, discontinuities, and multiphysics coupling. The authors emphasize the shift towards data-driven modeling paradigms, showcasing how AI is being used for tasks like rock property estimation, image-based modeling, fracture detection, and constitutive modeling. They also discuss the growing adoption of physics-informed neural networks (PINNs) that embed governing physical laws into loss functions, aligning data-driven inference with mechanical consistency. The paper acknowledges the challenges that remain, including data quality, model generalization, and interpretability, and calls for standardized datasets, interdisciplinary collaboration, and transparent AI workflows. The authors conclude with a forward-looking perspective on the development of next-generation intelligent frameworks capable of coupling physical knowledge, spatial reasoning, and adaptive learning, aiming to advance rock mechanics from empirical modeling toward fully intelligent, autonomous systems. The paper's significance lies in its attempt to synthesize a large body of literature on the intersection of AI and rock mechanics, providing a valuable resource for researchers and practitioners in the field. However, the paper's broad scope and lack of critical evaluation of individual studies also present limitations that need to be addressed.
I found several strengths in this paper that contribute to its overall value as a review. Firstly, the paper provides a comprehensive overview of the current state of AI applications in rock mechanics and geotechnical engineering. The authors have meticulously traced the evolution of AI methodologies, from early backpropagation and support vector machines to modern deep learning frameworks such as convolutional and transformer architectures. This historical perspective is crucial for understanding the development of the field and the current trends in research. The paper effectively highlights the transformative potential of AI in addressing long-standing challenges in the field, such as the complex behavior of geological materials, anisotropy, discontinuities, and multiphysics coupling. The authors also demonstrate a clear understanding of the shift towards data-driven modeling paradigms, showcasing how AI is being used for tasks like rock property estimation, image-based modeling, fracture detection, and constitutive modeling. Furthermore, the paper acknowledges the growing adoption of physics-informed neural networks (PINNs) that embed governing physical laws into loss functions, aligning data-driven inference with mechanical consistency. This emphasis on the integration of physical principles with data-driven approaches is a significant strength, as it addresses the critical need for interpretability and reliability in engineering applications. The paper also provides a well-structured and clear presentation of the information, making it accessible to a broad audience. The use of examples and case studies, while not exhaustive, helps to illustrate the practical applications of AI in rock mechanics. Finally, the paper's forward-looking perspective on the development of next-generation intelligent frameworks capable of coupling physical knowledge, spatial reasoning, and adaptive learning is inspiring and sets a clear direction for future research. The paper's attempt to synthesize a large body of literature on the intersection of AI and rock mechanics is a valuable contribution to the field, providing a useful resource for researchers and practitioners.
Despite its strengths, the paper has several weaknesses that I have verified through my analysis. Firstly, the paper's scope is too broad, attempting to cover the entirety of AI applications in rock mechanics and geotechnical engineering. This breadth comes at the expense of depth, making it challenging to provide a thorough and critical evaluation of each area. As a result, the paper lacks a clear focus, and the depth of analysis varies across different sections. This is evident in the sheer number of topics covered, from fundamental rock properties to complex geotechnical applications, without sufficient detail on any single topic. Secondly, the paper does not adequately address the limitations of individual studies. While the authors mention general challenges such as data quality and model generalization, they fail to provide a critical assessment of the limitations inherent in the specific studies they reference. This lack of critical evaluation undermines the paper's ability to provide a balanced perspective on the current state of the field. The paper also lacks a dedicated section discussing the limitations of the presented works, which would have provided a more comprehensive and nuanced understanding of the challenges and shortcomings in the field. Furthermore, the paper does not sufficiently address the issue of data scarcity in rock mechanics. While the authors acknowledge data limitations as a general challenge, they do not delve into specific strategies for mitigating this issue, such as data augmentation or transfer learning. The paper also fails to discuss the sensitivity of different machine learning models to data quality and the potential for bias in the datasets used. This is a significant oversight, as data scarcity and quality are major hurdles in the application of AI in rock mechanics. The paper also lacks a detailed discussion on the practical implementation of AI models in real-world engineering scenarios. While the authors touch upon some practical aspects, they do not delve into the specific challenges of deploying these models in the field, such as the need for robust and reliable systems that can operate under varying environmental conditions. The paper also fails to discuss the computational cost associated with training and deploying complex AI models, which is a crucial factor in determining their feasibility for practical applications. Additionally, the paper does not adequately address the issue of uncertainty quantification in AI predictions. While the authors mention Bayesian frameworks for uncertainty quantification in the context of rock property estimation, they do not discuss how uncertainty is handled in other applications, such as rockburst prediction or constitutive modeling. This is a critical omission, as uncertainty quantification is essential for making informed decisions in engineering practice. The paper also does not provide a detailed discussion on the validation of AI models against real-world observations and experiments. While the paper mentions validation in specific examples, it lacks a broader discussion on the challenges of validating AI models in rock mechanics, such as the difficulty of obtaining sufficient and reliable data for model training and testing. The paper also does not adequately address the issue of interpretability of AI models. While the authors mention the use of simpler surrogate models and explainable AI techniques, they do not discuss the trade-offs between model accuracy and interpretability, or the importance of feature importance analysis in understanding the underlying mechanisms of rock behavior. Finally, the paper's title, "A Review of Intelligent Rock Mechanics: From Methods to Applications Conference Submissions," is misleading, as the paper does not review conference submissions but rather the broader literature on AI in rock mechanics. This discrepancy between the title and the content is a significant weakness that needs to be addressed. The paper also lacks a clear articulation of its unique contributions compared to existing review papers, making it difficult to assess its added value. The paper also does not provide a detailed discussion of the limitations of the current AI methods used in rock mechanics, such as the challenges of applying deep learning to limited datasets or the interpretability of complex models. The paper also does not adequately discuss the challenges of integrating AI into existing rock mechanics software and workflows, or the need for user-friendly interfaces and tools that allow engineers to use AI models without requiring extensive AI expertise. The paper also does not provide a detailed discussion of the ethical implications of using AI in rock mechanics, such as the potential for bias in AI models or the impact of AI on job displacement. These weaknesses, which I have verified through my analysis, significantly impact the paper's overall quality and its ability to provide a comprehensive and balanced perspective on the current state of AI in rock mechanics.
To address the identified weaknesses, I recommend several concrete and actionable improvements. Firstly, the authors should narrow the scope of the paper to allow for a more in-depth analysis of specific areas within AI applications in rock mechanics. Instead of attempting to cover the entire field, they could focus on a particular theme, such as the use of physics-informed neural networks for constitutive modeling, or the application of machine learning for rock mass classification. This would allow for a more detailed discussion of the state-of-the-art methods, their limitations, and future research directions within that specific area. Secondly, the authors should include a dedicated section that explicitly discusses the limitations of the presented works. This section should provide a critical assessment of the shortcomings of individual studies, including issues related to data quality, model generalization, and interpretability. This would provide a more balanced perspective on the current state of the field and help readers understand the challenges that need to be addressed. Thirdly, the authors should provide a more detailed discussion on the issue of data scarcity in rock mechanics. This discussion should include specific strategies for mitigating this issue, such as data augmentation techniques, transfer learning, and the use of synthetic data generation. The authors should also discuss the sensitivity of different machine learning models to data quality and the potential for bias in the datasets used. Fourthly, the authors should include a more detailed discussion on the practical implementation of AI models in real-world engineering scenarios. This discussion should address the specific challenges of deploying these models in the field, such as the need for robust and reliable systems that can operate under varying environmental conditions. The authors should also discuss the computational cost associated with training and deploying complex AI models and explore strategies for reducing this cost. Fifthly, the authors should provide a more detailed discussion on the issue of uncertainty quantification in AI predictions. This discussion should include specific methods for quantifying uncertainty, such as Bayesian neural networks or ensemble methods, and how these methods can be used to provide more reliable predictions. The authors should also discuss the importance of uncertainty quantification in decision-making and risk assessment. Sixthly, the authors should provide a more detailed discussion on the validation of AI models against real-world observations and experiments. This discussion should address the challenges of obtaining sufficient and reliable data for model training and testing, and the importance of using appropriate validation metrics. Seventhly, the authors should provide a more detailed discussion on the issue of interpretability of AI models. This discussion should include specific techniques for improving interpretability, such as feature importance analysis, saliency maps, or rule extraction, and the trade-offs between model accuracy and interpretability. Eighthly, the authors should revise the title of the paper to accurately reflect its content. The current title is misleading, as the paper does not review conference submissions but rather the broader literature on AI in rock mechanics. The authors should also clearly articulate the unique contributions of their review compared to existing review papers. Finally, the authors should include a more detailed discussion of the limitations of the current AI methods used in rock mechanics, the challenges of integrating AI into existing rock mechanics software and workflows, and the ethical implications of using AI in rock mechanics. These recommendations, which are directly linked to the identified weaknesses, would significantly improve the paper's overall quality and its value to the research community.
Based on my analysis, I have several questions that I believe are crucial for further clarification and understanding of the paper's content. Firstly, given the broad scope of the paper, what specific criteria did the authors use to select the studies included in the review, and how did they ensure that the selected studies are representative of the entire field of AI in rock mechanics? Secondly, considering the limitations of individual studies, what specific examples can the authors provide of studies that have not adequately addressed data quality issues or model generalization, and what are the implications of these limitations for the validity of their findings? Thirdly, regarding data scarcity, what specific data augmentation techniques or transfer learning strategies do the authors recommend for rock mechanics, and what are the potential limitations of these approaches? Fourthly, concerning the practical implementation of AI models, what specific steps do the authors suggest for bridging the gap between academic research and real-world engineering practice, and what are the key challenges that need to be overcome to achieve this? Fifthly, regarding uncertainty quantification, what specific methods do the authors recommend for quantifying uncertainty in AI predictions, and how can these methods be used to inform decision-making and risk assessment in rock mechanics? Sixthly, concerning model validation, what specific metrics do the authors recommend for evaluating the performance of AI models in rock mechanics, and what are the challenges of obtaining sufficient and reliable data for model validation? Seventhly, regarding model interpretability, what specific techniques do the authors recommend for improving the interpretability of complex AI models, and what are the trade-offs between model accuracy and interpretability? Finally, given the paper's title, what specific aspects of conference submissions, if any, did the authors consider in their review, and how does the paper's content relate to the broader literature on AI in rock mechanics? These questions, which target core methodological choices and critical assumptions, seek to clarify key uncertainties and provide a more comprehensive understanding of the paper's contributions and limitations.