Understanding Life cycle assessment and sustainability criteria terminology

This is a standardised framework (set out in ISO 14040/44) that allows compilation and evaluation of the inputs, outputs, and the potential environmental impacts of a product system throughout its lifecycle. There are four steps:

1. Definition of goal and scope
2. Inventory analysis
3. Impact assessment
4. Interpretation

The system boundary determines which entities (unit processes) are inside the system and which are outside. It essentially determines which lifecycle/supply chain stages and processes are included in the assessment and need to be in accordance with the goal and scope of the study.

Ideally, the boundary should be as broad as possible, thereby including all the processes that directly and indirectly contribute to the system under consideration, from the extraction of all the raw resources to the intended point of use of the delivered product.

The functional unit represents the reference product or service to which the input and output flows from the lifecycle inventory (LCI) are related.

For example, the functional unit for fuels could be e.g. ‘MJ of delivered energy’, and hence the output flow for emissions could be expressed with the unit: gCO₂e/MJ.

This is a phase of the lifecycle assessment which involves the compilation and quantification of inputs and outputs for a product throughout its lifecycle.

This is the evaluation phase of the lifecycle assessment which aims to assess the magnitude and significance of the potential environmental impacts for a product system throughout the lifecycle of the product.

Sustainability criteria are parameters for the production process and quality of a process that must be met to obtain a sustainability status or certification. Often sustainability criteria will consist of multiple impact categories against which a product lifecycle impacts will be assessed.

An established methodology to assess impacts e.g.

• EU Renewable Energy Directive (RED II)
• JEC (JRC-EUCAR-Concawe) Well to Wheels study
• GREET Model
• ICAO CORSIA carbon certification

An impact category combines multiple factors that cause the same impact on the environment into a single environmental effect.

For example, carbon dioxide (CO₂) and methane (CH₄) both lead to the greenhouse effect and can be converted into a single unit (e.g. kg CO₂e) that translates into one impact category (e.g., climate change). In LCA, impact categories represent the environmental issue of concern to which a lifecycle inventory analysis (LCIA) may be assigned.

An impact indicator may also be known as an “impact metric”. This provides a quantifiable representation of an impact category, which can result in numerical values, expressed in category-specific units.

For example, for climate change (an impact category), the related impact indicator (global warming potential) is expressed in kg CO₂e.

Co-product allocation is a method to distribute environmental impacts (e.g. emissions) between two or more products resulting from a process or product system.

Allocation can be done by mass, energy, and economic value of the resulting products. Essentially, this method focuses on the individual product unit, which is assigned a share of the overall environmental impact, rather than considering the system as a whole.

System expansion is a method to distribute environmental impacts (e.g. emissions) between two or more products resulting from a process or product system.

Let’s consider this with the figure below. In the system expansion approach, the entire impact of the system (Plant AB) is first calculated, and then the boundary of the multioutput system is expanded to include a set of alternative independent production pathways (Plant B) which are capable of producing outputs that are deemed to be “functionally equivalent” to the various co-products of interest (Product B’ being functionally equivalent to Product B). The impact assigned to one co-product (Product A) is finally calculated as the difference between the entire impact of the original multi-output process (Impact AB), and the sum of the impacts of the alternative independent pathways that produce functional equivalents of all the other co-products (Impact B’).

This approach is part of the consequential lifecycle assessment method that seeks to capture change in environmental impact as a consequence of a certain activity.

ISO 14040 recommends the use of system expansion whenever possible.