Point Source Capture
AI/ML Approaches for Research and Development Application
Approaches
Use machine learning approaches based on known labels/expectations, usually for
- Classification (e.g., Logistic, Support Vector Machine)
- Regression (e.g., Linear, Kernel Ridge)
Potential Problems
- Collect data on diverse PSC systems
- Explore grid-market interactions using cost models.
- Discovery of materials and predicting properties of solvents & sorbents
- Clarify capture levels & net emissions
- Validate PSC technologies for other applications
- Identify site qualifications to inform screening.
- Predict PSC system applicability based on the nature of an industry operation
- Integrate waste heat to reduce PSC energy use
- Fully integrate industrial PSC processes to effectively use low-carbon fuels and feedstocks
- Predict feedstock impacts on product properties
- Run integrated controls to meet purity requirements
- Mange diverse flows/content from varied sources
- Track the quantity & quality of CO2 and flag any issues
- Predict the water and resource usage to avoid operation disruption
Data/Input Formats
- Structured numeric data, text, image, maps, sequences, time-series data
Applications
- Reduce Capture Costs from dilute streams
- Expand capabilities in process modeling, TEA & LCA
- Reduce and validate PSC performance and cost
- Scale up technology for low-carbon power, materials & supply chain
- Adapt power plant PSC technology for industry
- Reduce process energy intensity and emissions
- Product low-CO2 product/construction materials
- Ensure quality and minimum purity of captured CO2
- Water and resource usage management
Approaches
Use machine learning approaches without known labels/expectations, usually for
- Clustering
- Dimension reduction
Potential Problems
- Collect data on diverse PSC systems
- Optimize emissions in stead and non-steady states
- Increase process intensification to improve carbon capture efficiency
- Identify site qualifications to inform screening.
- Guide operations to cut CO2 and improve the product.
Data/Input Formats
- Structured or unstructured data
Applications
- Reduce Capture Costs from dilute streams
- Expand capabilities in prcoess modeling, TEA & LCA
- Reduce and validate PSC performance and cost
- Scale up technology for low-carbon power, materials & supply chain
- Product low-CO2 product/construction materials
Approaches
Use complex neural network architecture for
- Image and spatial classification
- Time series regression
- Natural language processing
Potential Problems
- Explore grid-market interactions using cost models.
- Discovery of materials and predicting properties of solvents & sorbents
- Mange diverse flows/content from varied sources.
- Predict PSC system applicability based on the nature of an industry operation
- Predict the water and resource usage to avoid operation disruption
Data/Input Formats
- Structured numeric data, text, image, maps, sequences, time-series data
Applications
- Reduce Capture Costs from dilute streams
- Reduce and validate PSC performance and cost
- Adapt power plant PSC technology for industry
- Reduce process energy intensity and emissions
- Water and resource usage management
Approaches
Combine more than one machine learning models to handle the tasks
- Random Forest
- XGBoost
- Committee Machine
Potential Problems
- Collect data on diverse PSC systems
- Fill critical knowledge gaps in the complex interplay among mateirals, processing, properties & performance.
- Conduct technoeconomic Analyses using cost data from FEED studies
- Optimize emissions in steady and non-steady states
- Develop optimization models for PSC control systems.
- Increase process intensification to improve carbon capture efficiency
- Validate PSC technologies for other applications
- Provide a control strategy to optimize overall PSC system operations.
- Assess real-time data on fuels and feedstocks
- Predict the water and resource usage to avoid operation disruption
Data/Input Formats
- Structured numeric data, text, image, maps, sequences, time-series data
Applications
- Reduce Capture Costs from dilute streams
- Expand capabilities in prcoess modeling, TEA & LCA
- Reduce and validate PSC performance and cost
- Reduce process energey intensity and emissions
- Ensure quality and minimum purity of captured CO2
- Water and resource usage management
Approaches
Integrate scientific equations and knowledge into machine learning algorithms (usually using Deep Learning), such as Physics-Informed Machine Learning
Potential Problems
- Discovery of materials and predicting properties of solvents & sorbents.
- Validate PSC technologies for other applications
- Provide a control strategy to optimize overall PSC system operations
- Predict the water and resource usage to avoid operation disruption
Data/Input Formats
- Structured numeric data, text, image, maps, sequences, time-series data
- Scientific equations, field equations, partial differential equations
Applications
- Reduce Capture Costs from dilute streams
- Reduce and validate PSC performance and cost
- Water and resource usage management
| Large Language Models for UNSTRUCTURED DATA MINING | Large Language Models for GENERATIVE DISCOVERY | Transfer Learning | Science-based Learning | Edge Computing | Advance Sensor | Reinforcement Learning | Operator Learning | |
|---|---|---|---|---|---|---|---|---|
| Characterize Materials | ||||||||
| Develop Structural/Functional Materials | ||||||||
| Enable Smart Components w/embedded sensors | ||||||||
| Optimize regional Planning and Operations | ||||||||
| Modeling/Simulation Bridging Scales | ||||||||
| Accelerate Flow Sheet Initialization | ||||||||
| Optimize Turbine Operations | ||||||||
| Assess/Control H2 Combustion Characteristics |