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LCA results & interpretation Marble Floor and Pavers

Scope and summary

  • Cradle to gate
  • Cradle to gate with options
  • Cradle to grave

Product description

Marble stone flooring can be applied as interior flooring, exterior flooring, landscaping, and terracing. It tends to be durable and easy to maintain, with an elegant outlook. Marble makes up 100% of the total mass of the flooring and is used in commercial, residential, and public sector buildings.


The results in this study are presented for flooring with a thickness of 0.5 inches.

Functional unit

The functional unit is one square meter of floor covering. The amount of marble needed to meet the functional unit is 34.27 kg.

Manufacturing data

The data for all marble stone products were collected from Polycor's marble quarries and processing facilities covering a period of two years: January 2020 to December 2021. Data for marble quarry operations were collected from two quarry sites across North America and grouped as North American marble quarries.


After marble is extracted from the quarry, it goes to a processing facility. Stone processor operations data were collected from one Polycor marble processing site in North America.

  • American Limestone Plants: one manufacturing facility in Georgia.


Data were collected from quarries and producers mainly operating in North America (mainly the US). As such, the geographical coverage for this study is based on North American conditions.

Default installation, packaging, and disposal scenarios

Flooring is delivered at the job site ready for installation, where minor cuts may be necessary to accommodate design. Ancillary materials used in the installation of the product include mortar, grout, and acrylate. These materials are structural enhancement components used as bonding agents or fillers for joints. Wood and cardboard used as packaging to safely deliver the stone to the site is then transported to be either landfilled or recycled, following US EPA's end of life scenarios for containers and packaging. At the end of its useful life, the flooring is removed and transported to be landfilled.

Other life cycle stages

Use of sealants for periodic resealing of marble flooring and use of mortar during installation also generate significant impacts to the overall life cycle impacts. Under normal operating conditions, marble flooring requires not only monthly cleaning but also resealing every five years. Due to the nature of natural stone, it is anticipated that the marble flooring products will last for the lifetime of the building. The reference service life (RSL) thus meets an ESL of 75 years, and flooring will need no replacements during its service life. End-of-life stages have lower contributions on the total life cycle impacts.

What’s causing the greatest impacts

All life cycle stages

For marble flooring, the cradle-to-gate stage (A1-A3) dominates the results for all impact categories except eutrophication and ozone depletion. This study assessed a multitude of inventory and environmental indicators. In addition to the six major impact categories (global warming potential, ozone depletion, acidification, smog, eutrophication, and fossil fuel depletion), additional impact categories have also been included. These six impact categories are globally deemed mature enough to be included in Type III environmental declarations. Other categories are being developed and defined, and LCA should continue making advances in their development. However, the EPD users shall not use additional measures for comparative purposes. LCIA results are relative expressions and do not predict impacts on category endpoints, the exceeding of thresholds, safety margins or risks.


Overall results are consistent with expectations for stone flooring's life cycles, with most of the impacts being generated during cradle-to-gate stages.


The primary finding, across the environmental indicators, was that cradle-to-gate stage (A1-A3) dominates the impacts due to the energy consumed at the quarries and processing plants. The processor operations (A3) stage is the highest contributor to most of the impact categories, followed by the maintenance stage (B2) and quarry operations (A1). The cradle-to gate-stage (A1-A3) contributes to ~60% of the total impacts in all impact categories except for eutrophication and ozone depletion. The transportation of stone from quarries to processing plants, transportation of flooring from processing plants to the installation sites, and use of mortar during installation also generate significant impacts in the overall life cycle impacts of marble flooring.

Quarry operations and transport to processors

Impacts generated at marble quarries (A1) are mainly due to the use of grid electricity and fuels in the quarries. Other material inputs generate little impact in comparison to the electricity and fuel consumed. The transportation of marble from quarries to processing plants generates considerable impacts in numerous impact categories.

Processor operations and transport to building sites

Manufacturing operations at marble processing plants make up the greatest share of impacts. Electricity consumed at processors is responsible for the majority of impacts, while other fuels and material inputs have little contribution. The transportation of marble flooring manufactured in processor plants to the building sites also has a significant impact on the overall life cycle impacts of marble flooring.

Sensitivity analysis

Based on the recommendation provided by Polycor, impacts for processor operations specific to a square meter of marble flooring was assumed to match the average stone processing for a square meter of marble. A sensitivity analysis was performed to check the robustness of the results when the energy consumed during processing is varied by +/-20% from the estimate used in this study. The resulting variation in the total life cycle impacts is about 12%, implying that the system is not sensitive to this assumed value.


Another parameter that affects the overall life cycle impacts is the thickness of marble flooring. The thickness of stone flooring studied varied up to 2 inches. Results have been presented for a typical interior thickness of 0.5 inches, but as the functional mass of varies with the thickness, the impacts also vary. A sensitivity analysis has thus been conducted for various thicknesses of marble flooring used for different flooring applications. For the thickness of 1.25 inches and larger, the variation in overall life cycle impacts is greater than 20%, implying that the system is sensitive to thickness value.

Other life cycle stages

Use of sealants for periodic resealing of marble flooring and use of mortar during installation also generate significant impacts to the overall life cycle impacts. Under normal operating conditions, marble flooring requires not only monthly cleaning but also resealing every five years. Due to the nature of natural stone, it is anticipated that the marble flooring products will last for the lifetime of the building. The reference service life (RSL) thus meets an ESL of 75 years, and flooring will need no replacements during its service life. End-of-life stages have lower contributions on the total life cycle impacts.

How we're making it greener

Natural stone is one of the lowest embodied carbon construction materials. Although we are proud of this intrinsic quality, we want to make sure that we'll never stop improving it. Our main driver is our ambitious 2025 carbon neutrality pledge. By increasing the use of renewable energy, reducing our dependency on fossil fuels, electrifying our car fleet and increasing the energy efficiency throughout our value chain, we aim to reduce our embodied carbon by 40% by the end of 2025!

Beyond embodied carbon, Polycor only uses rainwater for stone extraction, recycles it, and also uses dry sawing technology in a growing number of quarry operations. In quarrying, production, installation and maintenance, natural stone lowers water use throughout its life cycle.

Polycor is the leader within the Natural Stone Sustainability Standard (ANSI 373) with 25% of our sites certified. This standard examines and verifies numerous areas of natural stone production, effectively improving the baseline for the environmental and social performance of natural stone in alignment with green building practices.

See how we make it greener

LCA results

Life cycle stage A1-A3
Production (quarry and processor operations)
A4
Stone transport to building sites
A5
Installation
B1-B7
Use
C1-C2
Deconstruction and waste transport
C3-C4
Waste processing and end-of-life disposal

Information modules: Included (X) | Excluded* (MND)


Stages B1, B3-B7, C1, and C3 though included, have no associated activities.


*Module D is excluded.

A1 Quarry operations A4 Transport to building sites A5 Installation B1 Use C1 Deconstruction C3 Waste Processing
A2 Transport to processors     B2 Maintenance C2 Waste transport C4 End of life disposal
A3 Processor operations     B3 Repair    
      B4 Replacement    
      B5 Refurbishment    
      B6 Operational energy use    
      B6 Operational water use    
Impacts of 1 square meter of floor covering 1.78E+00 mPts 1.74E-01 mPts 1.22E-01 mPts 8.10E-01 mPts 3.28E-02 mPts 4.67E-03 mPts
Materials or processes contributing >20% to total impacts in each life cycle stage Energy consumed during stone quarrying and processing (electricity and fuels). Truck transportation used to transport product to building site. Use of ancillary materials (mainly mortar) for installation. Sealants used for periodic resealing. Waste transport to the landfill centers. Landfilling after the end of life.

TRACI v2.1 results per functional unit

Life cycle stage A1-A3
Production (Quarry and Processor operations)
A4
Stone transport to building sites
A5
Installation
B2
Maintenance
C2
Waste transport
C4
End-of-life disposal

Ecological damage

Impact category Unit
Acidification kg SO2 eq Kilograms of Sulfur Dioxide equivalent
Acidification processes increase the acidity of water and soil systems and causes damage to lakes, streams, rivers and various plants and animals as well as building materials, paints and other human-built structures.
1.11E-01 1.29E-02 1.20E-02 6.58E-02 2.44E-03 8.39E-04
Eutrophication kg N eqKilograms of Nitrogen equivalent
Eutrophication is the enrichment of an aquatic ecosystem with nutrients (nitrates and phosphates) that accelerate biological productivity (growth of algae and weeds) and an undesirable accumulation of algal biomass which impacts industry, agriculture, drinking, fishing and recreation and causes death of fish and shellfish, toxicity to humans, marine mammals and livestock, and reduces biodiversity.
1.91E-02 1.74E-03 7.13E-04 2.82E-02 3.28E-04 8.20E-05
Global warming kg CO2 eqKilograms of Carbon Dioxide equivalent
Global warming is an average increase in the temperature of the atmosphere near the Earth’s surface and in the troposphere, which can contribute to change in global climate patterns and is caused by the increase of the sources of greenhouse gases and decrease of the sinks due to deforestation and land use. GW leads to problems in human health, agriculture, forest, water source and damage to species and biodiversity as well as coastal areas.
3.27E+01 4.13E+00 2.61E+00 7.28E+00 7.79E-01 8.68E-02
Ozone depletion kg CFC-11 eq Kilograms of Trichlorofluoromethane equivalent
Ozone depletion is the reduction of ozone in the stratosphere caused by the release of ozone depleting chemicals. Ozone depletion can increases ultraviolet B radiation to the earth which can adversely affect human health (skin cancer and cataracts and immune-system suppression) and other system (marine life, agricultural crops, and other vegetation) and causes damage to human-built materials.
2.45E-06 8.24E-07 1.34E-07 4.80E-06 1.55E-07 1.48E-08

References

LCA Background Report

Polycor Natural Stone Flooring LCA Background Report (public version), Polycor 2023. SimaPro Analyst 9.4, ecoinvent 3.4 database.

ISO 21930:2017 serves as the core PCR along with EN 15804 and SM Part A.

SM Part A: Life Cycle Assessment Calculation Rules and Report Requirements, v2018

March, 2018. Document created by Joep Meijer, Naji Kasem, and Kim Lewis and is managed and maintained by the Sustainable Minds Technical Advisory Board (TAB) as outlined in ISO 14025:2006.

SM Part B: Product group definition for Interior and exterior stone flooring, 2022

April, 2022. Part B review conducted by the Sustainable Minds TAB, [email protected]

ISO 14025, “Sustainability in buildings and civil engineering works -- Core rules for environmental product declarations of construction products and services”


Download PDF SM Transparency Report, which includes the additional EPD content required by the SM Part B.

SM Transparency Reports (TR) are ISO 14025 Type III environmental declarations (EPD) that enable purchasers and users to compare the potential environmental performance of products on a life cycle basis. They are designed to present information transparently to make the limitations of comparability more understandable. A limitation to this study is that not all manufacturers in North America participated. TRs/EPDs of products that conform to the same PCR and include the same life cycle stages, but are made by different manufacturers, may not sufficiently align to support direct comparisons. They therefore, cannot be used as comparative assertions unless the conditions defined in ISO 14025 Section 6.7.2. ‘Requirements for Comparability’ are satisfied. Comparison of the environmental performance of building envelope thermal insulation using EPD information shall be based on the product’s use and impacts at the building level, and therefore EPDs may not be used for comparability purposes when not considering the building energy use phase as instructed under the PCR. Full conformance with the PCR for stone flooring allows EPD comparability only when all stages of a life cycle have been considered, when they comply with all referenced standards, use the same sub-category PCR, and use equivalent scenarios with respect to construction works. However, variations and deviations are possible. Example of variations: Different LCA software and background LCI data sets may lead to different results upstream or downstream of the life cycle stages declared.

Rating systems

The intent is to reward project teams for selecting products from manufacturers who have verified life-cycle environmental performance.

LEED BD+C: New Construction | v4 - LEED v4

Building product disclosure and optimization

Environmental product declarations

  • Industry-wide (generic) EPD ½product

  • Product-specific Type III EPD 1 product

LEED BD+C: New Construction | v4.1 - LEED v4.1

Building product disclosure and optimization

Environmental product declarations

  • Industry-wide (generic) EPD 1 product

  • Product-specific Type III EPD 1.5 product

Collaborative for High Performance Schools National Criteria

MW C5.1 – Environmental Product Declarations

  • Third-party certified type III EPD 2 points

Green Globes for New Construction and Sustainable Interiors

Materials and resources

  • NC 3.5.1.2 Path B: Prescriptive Path for Building Core and Shell

  • NC 3.5.1.2 Path B: Prescriptive Path for Building Core and Shell

BREEAM New Construction 2018

Mat 02 - Environmental impacts from construction products

Environmental Product Declarations (EPD)

  • Industry-average EPD .5 point

  • Multi-product specific EPD .75 point

  • Product-specific EPD 1 point