Versions Compared

Key

  • This line was added.
  • This line was removed.
  • Formatting was changed.

Requirements of the finance community

A. Identify the goal for climate finance:

  1. Green finance: practices aligned with climate change mitigation and co-benefits

Key points of convergence amongst Day 1 groups: 

  1. Hybrid approaches (e.g. , activity-based and modeling) that are optimally cost-effective and accurate.
    1. Hybrid approaches should also help reduce uncertainty.
    2. Low- and middle-income countries are far behind on data, models, and measurement capacity and present more challenges related to smallholdings, farmer-based monitoring etc.
  2. For the finance community, the level of uncertainty is not always as important as identifying what the uncertainties are.  Methods should be good enough to provide evidence that greenwashing is not occurring. Precision can be improved over time.

  3. Using land use activity data as a proxy for SOC should help reduce cost (the major barrier). Improve how to put together robust data on land use history to define what is eligible for SOC stock measurements. 
  4. Observing co-benefits in tandem with soil C increases the value of the C credit. 
  5. As relationships improve with the farmers in certain projects, the synergy in data collection improves. 
    1. Must engage farmers across scales. 
    2. Companies can help engage farmers by encouraging them to collect data and, in turn, begin to promote behavior changes. However, data collection by farmers can impose an additional cost and be inaccurate. 

Requirements of the finance community

How to design MRV:

  1. Finance community wants to make payments based on results. 
  2. Receive payments upfront to support baseline measurements. 
  3. Identify uncertainties. 

How to deal with risk: 

  1. water and biodiversity conservation), where the certainty of directional change is likely, but the impact level is not measured. For example, companies or loans using "green lists" of eligible practices; "good enough" methods (lowest requirements)
  2. Results-based payments: payments based on defined climate mitigation result supported by an accounting system that fosters confidence in impacts, although medium/high quantification uncertainty applies (intermediary requirements)
  3. Carbon-credit markets: quantification of climate mitigation results following rules and procedures determined by protocols and standards under third-party verification (e.g. CDM, Verra and Gold Standard standards), which lowers uncertainties and increases credibility of results (highest requirements)

B. Plan for improving accuracy and uncertainty over time toward carbon market-grade credits.

Practice lists and criteria → Indicators and proxies → Modeling → Measurement

from (lowest accuracy and highest uncertainty) to (highest accuracy and lowest uncertainty)

C. MRV design considerations:

  1. What needs to be estimated?  Carbon sinks, avoided carbon loss, GHGs emissions, and mitigation co-benefits, e.g. water and biodiversity conservation, to ensure benefits to farmers
  2. How well? Accuracy and uncertainty
  3. How to reduce risks of impermanence or non-performance  
  4. How to minimize costs (e.g. acceptable % of the total project budget spent on MRV, sufficient benefit to farmers) 
  5. Other considerations: Scalability needs, verification needs (e.g. first, second and third-party), frequency of estimations, reporting requirements, timing needed to detect changes (e.g. usually > 5 years) and make payments

D. Improving accuracy and uncertainty 

  1. Move to hybrid approaches: direct measurements with modeling and remote sensing 
    1. Measurement, based on project/region characteristics and resources available
      1. activity data collection (e.g. use of smartphone, interviews)
      2. focus on few high-quality measurements (e.g. what to measure and how - sampling design; soil C and soil bulk density; frequency)
      3. prioritization (e.g. sampling design; soil C or bulk density; soil C determination method; use of pedo-transfer functions)
      4. data gaps: filling out gaps (e.g. scientific literature, experts consultation, global databases) 
    2. Modeling: choosing a model, model calibration, technical requirements and acceptable uncertainties
    3. Remote sensing: application and requirements 
    4. Co-benefits: assessment (e.g. generating water/biodiversity indicators from/in tandem? with soil C measurements)
  2. Aggregation across larger scales to reduce project-level variation effects (landscapes)

E. Reducing risk of impermanence or non-performance: 

...

  1. Discounted carbon credits to account for impermanence and accuracy risks
  2. Buffers in carbon credits allocated
  3. Accounting performed at the landscape scale to spread risk over large areas. 
  4. Reducing uncertainty: 
    1. Direct measurements (e.g., soil sampling). 
    2. Model outputs. 
    3. More measurements at deeper depths (> 30 cm). 
  5. Reducing cost of data collection:
  6. Hybrid approach: complement direct measurements with modeling/remote sensing. Detect the optimal measurement strategy based on region and resources available. 
  7. Detect C stock changes by measuring bulk density, in addition to SOC. Verification type and frequency (credibility highest with third-party)