Feedstock characterization

The following measurements shall be taken of feedstock before spreading for the purpose of estimating the maximum potential CDR for a given feedstock, and for modeling the potential CDR and weathering rate over the project lifetime (both detailed in the CDR Estimates section below).

Characteristics with two asterisks (**) do not need to be measured for every feedstock batch, if Project Developers measure them at least once and justify that they are not expected to vary across batches from the same feedstock source.

Table 1 List of measurements to perform on feedstock to determine CDR potential, via calculations and models described below. Provide average and distribution of results.

*to be measured from samples taken immediately prior to spreading feedstock

The following measurements shall be taken before feedstock spreading for the purpose of demonstrating that the project meets Environmental and Social Do No Harm requirements. Project Developers shall compare all measurement results to the thresholds set in the relevant jurisdictional regulations. It shall be transparently stated when no regulation covers the given measurement, and which thresholds are used instead.

Characteristics with two asterisks (**) do not need to be measured for every feedstock batch, if Project Developers measure them at least once and justify that they are not expected to vary across batches from the same feedstock source.

Table 2 List of measurements to perform on feedstock to determine ESDNH compliance.

*optional measurement. If not measured, safety precautions must be implemented and described to protect workers from RCS

Maximum potential CDR of applied feedstock shall be calculated based on the modified Steinor equation, shown below (Renforth, 2019). Project Developers should use the average, minimum and maximum results from feedstock measurements and report the range of results.

$\textbf{(Eq.1)}\ E_{pot} = \frac{M_{CO_2}}{100} \times \left( \alpha \frac{CaO}{M_{CaO}} + \beta \frac{MgO}{M_{MgO}} + \varepsilon \frac{Na_2O}{M_{Na_2O}} + \theta \frac{K_2O}{M_{K_2O}} + \gamma \frac{SO_3}{M_{SO_3}} + \delta \frac{P_2O_5}{M_{P_2O_5}} \right) \times 10^3 \times \eta$

• $E_{pot}$ represents the maximum CDR potential of a feedstock

• $CaO, MgO, SO_3, P_2O_5, Na_2O$ and $K_2O$ represent the elemental concentrations in the form of oxides

• $M_x$ denotes the molecular mass of each respective oxide $x$

• $\alpha, \beta, \gamma, \delta, \varepsilon, \text{ and } \theta$ represent the relative contributions of each oxide. According to Renforth, 2019, $\alpha, \beta, \varepsilon, \text{ and } \theta$ are equal to -1; $\gamma$ equals -1; and $\delta$ equals -2.

• $\eta$ represents the molar ratio of CO$_2$ sequestered per divalent cation present in the feedstock. As a default, this may be assumed to be 0.85. See the Measurements section for more details.

Potential CDR over the project lifetime should be modeled, specifying CDR across any expected crediting period renewals.

The model should include a curve of expected weathering completion (e.g. 10 years after application, it is estimated that 70% of the material has weathered). The results of this modeling are used for informing allocation of upstream impacts in the GHG quantification. The models used shall:

• include at least a consideration of moisture, temperature, and pH in the project region.

• link biogeochemical and hydrological processes.

• have already been calibrated and validated with appropriate independent datasets of CDR measurements.

• transparently assess initialization assumptions and model uncertainty, and the resulting effect on CDR estimates.

• include an estimate of CDR loss in the FFZ (i.e. in rivers, surface water, and the ocean).

• use direct measurements of multiple variables to ground-truth models wherever possible.

• provide all technical details needed to assess the validity of the approach to the VVB and/or peer reviewers

Alternatively, Project Developers may opt to count all upstream impacts in the first reporting period and credit issuance.