Carbon Footprint & LCA — Industry Case Study

What the LCA Actually Showed When We Ran the Numbers #

The brief came in as a cost reduction project. A mid-size personal care brand in the EU was paying a premium for rigid two-piece setup boxes for a skincare gift set range and wanted to know if there was a cheaper alternative. We ran the LCA alongside the structural redesign, and cost turned out to be the secondary story.

The original rigid box specification used 2.0mm greyboard wrapped in 128 gsm coated art paper, with a separate lid and base, EVA foam insert, and a PE-laminated inner liner. Total board weight per unit: approximately 340g. We modeled this against a proposed collapsible rigid box structure using 1.5mm greyboard with a one-piece auto-bottom configuration, eliminating the liner and replacing the foam insert with a die-cut honeycomb pulp tray.

The LCA followed ISO 14040:2006 and ISO 14044:2006 procedures. Scope covered cradle-to-gate, meaning raw material extraction through to finished goods at our factory gate — we excluded downstream logistics because the brand’s distribution network was outside our data boundary. The functional unit was one complete gift set packaged and ready for shipment, producing output comparable under ISO 14044 clause 4.2.3 on functional unit definition.

Carbon coefficients for virgin GC2 greyboard came from the European Reference Life Cycle Database (ELCD), supplemented by mill-specific EPD data from our primary greyboard supplier. For the honeycomb pulp tray, we used Ecoinvent 3.9 background data, adjusted for the supplier’s 74% recycled fibre input.

The result: the original rigid box configuration generated 1.84 kg CO₂e per functional unit at cradle-to-gate. The redesigned collapsible structure with pulp insert came in at 1.14 kg CO₂e — a 38% reduction. Board weight dropped from 340g to 198g per unit. That single material reduction drove roughly 61% of the total carbon saving; the remainder came from eliminating the PE liner and switching from EVA foam to pulp.

What to Request From a Packaging Supplier Before You Commit to Any LCA-Based Claim #

Before any LCA-linked carbon claim can be published — whether on-pack, in a sustainability report, or in a retail buyer submission — you need specific documentation from your packaging supplier. Requesting “an LCA” is not enough. Here is what to ask for, and what the response tells you.

Ask for the system boundary declaration in writing, per ISO 14044 clause 4.3. If a supplier hands you a carbon figure without specifying whether it is cradle-to-gate, cradle-to-grave, or gate-to-gate, that number is not usable for any formal claim under PAS 2060:2014. A well-prepared supplier will state the boundary, the functional unit, and the primary data sources in the first page of their LCA summary. Response time matters: if this takes more than five working days, the data probably does not exist yet and is being assembled retrospectively.

Ask for the GWP characterisation factor set used. There is ongoing industry debate between using IPCC AR5 GWP100 factors (used in most existing packaging LCAs) versus the newer AR6 factors, which are approximately 4–5% higher for methane-intensive materials. For paper and board-based packaging, the difference is modest. For packaging that uses significant polyolefin content, it is not trivial. Our practice is to run primary calculations under AR5 and flag the AR6 delta in a supplementary note, because most brand sustainability teams are still submitting to frameworks that require AR5 comparability.

Ask whether the carbon data is primary (mill-measured, EPD-verified) or secondary (from background databases like Ecoinvent or ELCD). Primary data for a specific material from a specific mill can differ from Ecoinvent background data by 15–30% in either direction, depending on the mill’s energy mix and recovery rate. Secondary data is acceptable for screening-level LCAs, but for any third-party verified claim, at least the dominant material in your packaging system should carry primary data.

We log all incoming LCA documentation under our internal GS-04 sustainability data review protocol, which tracks data source, vintage year, and whether the figure has been independently verified. Any submission more than three years old is flagged for revalidation before we incorporate it into a brand partner’s carbon calculation.

Cost-Performance Trade-offs When Redesigning for Carbon #

The collapsible rigid box structure in this project cost approximately 18% less per unit at 5,000 units MOQ, which was the original goal. The carbon reduction was a parallel benefit, not a cost premium.

That is not always how it works. Switching from a virgin-fibre coated board to a 100% PCW recycled board with comparable print performance typically adds 8–12% to material cost at equivalent grammage, based on our purchasing data across 14 board grades reviewed in 2024. The carbon saving for that switch is real — roughly 0.3–0.5 kg CO₂e per kg of board, depending on mill energy source — but the brand absorbs the cost delta unless they can use the sustainability story to justify a retail price premium or access a retailer’s preferential shelf programme.

The counterargument worth making: for brands selling into UK or EU retail channels where the EU Packaging and Packaging Waste Regulation (PPWR) recycled content targets apply, paying the premium for certified PCW content now avoids a more disruptive and expensive reformulation in 2028–2030 when thresholds become mandatory. The cost-of-change curve is steeper later.

One trade-off that often goes unexamined is transportation density. A flat-pack collapsible rigid box ships at roughly 4× the unit density of a pre-assembled rigid box. For a brand receiving goods at a US fulfilment centre from China, the freight carbon per unit drops significantly — but this only shows up in the LCA if the scope includes Scope 3 upstream logistics. Many brands leave this out and undercount their packaging’s total carbon contribution.

Greyboard Substrate Selection: Where the Carbon Numbers Actually Come From #

This section is worth going deeper on because it is where most packaging LCAs produce their largest variance, and where we see the most inconsistent data in client briefs.

Greyboard — the core structural material in rigid boxes and some folding carton applications — is typically produced from 100% recycled fibre in standard commercial grades. The carbon intensity of greyboard production varies primarily by two factors: the energy source of the mill (coal, gas, or renewable), and the proportion of post-consumer versus post-industrial recovered fibre. Post-industrial fibre (trim waste, converter off-cuts) has a lower collection energy burden than post-consumer fibre, but post-consumer fibre generally carries a higher recycled content certification value under FSC Recycled and equivalent chain-of-custody schemes.

Carbon intensity figures above are sourced from Ecoinvent 3.9 and cross-checked against available EPDs from three European and two Chinese board mills in our approved vendor list. The SBS figure reflects a European mill average; Chinese SBS production using coal-heavy grid electricity can reach 1.40–1.60 kg CO₂e/kg — a relevant gap if you are comparing packaging produced in different regions.

For the personal care project referenced earlier, the greyboard shift from 2.0mm standard grey to 1.5mm standard grey (both 100% recycled, same mill) saved 0.31 kg CO₂e per unit on board alone, before any other change. Caliper reduction is a lower-risk carbon lever than substrate substitution because it does not alter print or finishing compatibility.

One open question we are tracking: stone paper performs well on carbon intensity at gate, but its end-of-life behaviour in mixed recycling streams is still poorly characterised. Our dataset only covers gate-to-gate LCA for stone paper applications — we will have better end-of-life data after our 2025 pilot with a FMCG client concludes.

Specification Notes for Brand Partners #

When you brief us on a carbon reduction or LCA project, the information that moves things forward fastest is: current substrate specification (greyboard grade, caliper, and GSM), current unit weight as packed, annual volume, and your target scope boundary (cradle-to-gate is what we can fully support with primary data; cradle-to-grave requires your downstream logistics data).

The most common gap in incoming briefs is the absence of a confirmed functional unit. Without it, we cannot produce a carbon figure that is comparable to your existing baseline or reportable under PAS 2060. A functional unit should describe what the packaging does, not just what it is — “one complete unit of product packaged and ready for retail display” is usable; “one box” is not.

Our standard LCA screening process takes 10–15 working days from receipt of a complete brief, including a written system boundary declaration and a preliminary CO₂e figure by material category. A full verification-ready LCA report, suitable for third-party review under ISO 14044, adds 20–25 working days and requires confirmed EPD data from your material suppliers. Sampling for any structural redesign runs in parallel, with first physical samples typically at 15–20 working days from brief sign-off.

What is the actual carbon saving if I switch from a rigid box to a folding carton for a gift set?

Based on the project documented in this article, the cradle-to-gate reduction was 38% — from 1.84 kg CO₂e to 1.14 kg CO₂e per unit. The exact figure for your project depends on your current substrate spec, the unit weight, and whether you are eliminating an insert or liner. A screening LCA on your specific brief will give you a defensible number before you commit to any claim.

Does switching to recycled-content board always reduce carbon?

Yes, compared to virgin SBS, a 100% recycled greyboard grade will show lower carbon intensity — typically 0.45–0.65 kg CO₂e/kg versus 0.90–1.20 kg CO₂e/kg. The caveat is mill energy source: a recycled-fibre mill running on coal-heavy grid power can close the gap significantly compared to a virgin-fibre mill with on-site biomass energy. Ask your supplier for mill-specific EPD data, not just a recycled content percentage.

Can I use your LCA data for an on-pack carbon claim or a retail sustainability submission?

Our LCA screening output gives you a documented baseline and a directional carbon figure. For a formal on-pack claim or a submission requiring third-party verification, the LCA needs to meet ISO 14044 verification standards and, if you are pursuing a carbon neutral claim, PAS 2060:2014 compliance. Our screening report is designed to feed directly into that process, but the verification step itself is conducted by an accredited third party.

What is the minimum order quantity at which an LCA-driven redesign makes commercial sense?

There is no fixed MOQ for running the LCA — it costs the same to model 1,000 units as 100,000. The commercial case for acting on the LCA output depends on volume. At 5,000 units per year, a 18% unit cost reduction from structural redesign pays back tooling and sample costs within two production runs. At 1,000 units per year, the payback period stretches, but if the redesign is driven by retailer sustainability requirements rather than cost, the threshold is different.

How do you handle carbon data confidentiality when running an LCA for our packaging?

All material-level carbon data we generate during a client LCA review is treated as project-specific and not shared across client accounts. Supplier EPD data we hold on file is used in aggregate for our own carbon intensity benchmarking, which feeds our GS-04 protocol, but individual client packaging configurations and carbon figures are kept under NDA by default.

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