Carbon dioxide removal (CDR) options - WITNESS: Difference between revisions
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All these models implement directly the chemical reaction equation (consuming proportionate inputs and generating proportionate outputs to the chemical equation coefficients) | |||
All these models implement directly the chemical reaction equation (consuming proportionate inputs and generating proportionate outputs to the chemical equation coefficients), computing the heat/energy/resources needed for the reaction to happen, as well as the byproducts generated. They all have defined capex/opex/efficiency costing defined to handle how investment convert into actual CCUS capability. | |||
{{ModelDocumentationTemplate | {{ModelDocumentationTemplate |
Latest revision as of 17:02, 19 September 2024
Carbon capture
Carbon capture models include
- Direct air capture
- Flue gas capture
Carbon storage
Carbon storage models include
- Biomass burying and fossilization
- Deep ocean injection
- Deep saline formation
- Depleted oil or gas refill
- Enhanced oil recovery
- Geologic mineralization
- Pure carbon solid storage
- Reforestation
All these models implement directly the chemical reaction equation (consuming proportionate inputs and generating proportionate outputs to the chemical equation coefficients), computing the heat/energy/resources needed for the reaction to happen, as well as the byproducts generated. They all have defined capex/opex/efficiency costing defined to handle how investment convert into actual CCUS capability.
Corresponding documentation | |
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Previous versions | |
No previous version available | |
Model information | |
Model link | |
Institution | Open-Source for Climate (OS-C), N/A, https://os-climate.org/transition-analysis/., Linux Foundation (LF), N/A, https://www.linuxfoundation.org/. |
Solution concept | Systems dynamics based approach |
Solution method | OptimizationSimulation-based optimization |
Anticipation |