Decoupling clinker technology from cement product emissions: A macroeconomic ML-LCA framework for global embodied carbon policy screening.
クリンカー技術をセメント製品排出量から切り離す:グローバルな組込み炭素政策スクリーニングのためのマクロ経済ML-LCAフレームワーク (AI 翻訳)
Dilba Rayaru Kandiyil, M. Sadique, Denise Lee, J. Amoako-Attah, Rafal Al Mufti
🤖 gxceed AI 要約
日本語
この研究は、セメント産業の組込み炭素を推定するために、マクロ経済データのみを用いた機械学習とLCAを組み合わせたフレームワークを提案する。GDP per capitaなどからクリンカー対セメント比を予測し、技術別LCAモデルでA1-A3段階の排出量を算出する。18カ国での検証により物理的に妥当な結果を得ており、データ不足地域での炭素政策スクリーニングに貢献する。
English
This study proposes a hybrid ML-LCA framework to estimate cement embodied carbon using only publicly available macroeconomic data, predicting clinker-to-cement ratio from GDP per capita and other indicators. The Gradient Boosting model is integrated with a process-based LCA to estimate country-level carbon intensities (0.53-0.97 kg CO2/kg cement), validated across 18 economies. It provides a scalable baseline for embodied carbon policy screening in data-scarce contexts.
Unofficial AI-generated summary based on the public title and abstract. Not an official translation.
📝 gxceed 編集解説 — Why this matters
日本のGX文脈において
日本では、建設分野でのカーボンニュートラル達成に向けて、セメントの組込み炭素算定の重要性が増している。本フレームワークは、マクロ経済データのみで推計可能なため、我が国の建設業界での簡易なベンチマークとして活用できる可能性がある。
In the global GX context
Global carbon regulations (e.g., EU CBAM, Buy Clean policies) increasingly require embodied carbon data. This framework enables screening-level benchmarking for countries lacking plant-level LCA data, supporting policy design and international comparisons.
👥 読者別の含意
🔬研究者:Provides a validated method to estimate national cement embodied carbon using ML and macroeconomic data, useful for carbon accounting and LCA communities.
🏢実務担当者:Cement companies and construction firms can use this screening tool for preliminary benchmarking of their products' carbon footprint without detailed inventory data.
🏛政策担当者:Supports design of embodied carbon regulations by offering a transparent, scalable method to compare carbon intensities across countries for policy setting.
📄 Abstract(原文)
The cement industry contributes approximately 7-8% of global anthropogenic CO2 emissions, yet accurate cradle-to-gate embodied carbon estimation requires plant-level inventory data that are largely unavailable across developing and emerging economies. This data scarcity constrains global benchmarking and the implementation of emerging embodied carbon regulations. This study proposes a STIRPAT-grounded hybrid machine learning-life cycle assessment (ML-LCA) framework for estimating national-scale cement embodied carbon using exclusively publicly available macroeconomic data. GDP per capita, population, and temporal indicators are used to predict the clinker-to-cement ratio (CCR), which is subsequently propagated through a technology-stratified, process-based LCA model enforcing stoichiometric and thermodynamic constraints across A1-A3 stages. Among seven candidate algorithms, Gradient Boosting was selected for its smooth non-linear approximation and LCA integration suitability. SHAP analysis confirms GDP per capita as the dominant CCR driver, with contributions directionally consistent with established technology diffusion theory, ensuring model transparency. Validation across 18 economies through statistical metrics, residual diagnostics, country-level diagnostic benchmarking, Leave-One-Country-Out (LOCO) cross-validation, and three independent literature-benchmarking countries (Pakistan, Mexico, Spain) confirms physically plausible and externally consistent outputs ranging from 0.53 to 0.97 kg CO2/kg cement. A central methodological contribution is the ability to estimate the clinker-substitution decoupling effect at the country scale using only macroeconomic inputs, in contexts where plant-level LCA inventory data are unavailable. Conventional LCA already separates process, energy, and material composition contributions when inventory data are present; the present framework extends this separation to data-scarce national contexts. At the system level, an Environmental Kuznets Curve-type pattern is qualitatively reproduced when model outputs are aggregated across countries, providing a coherence check on the framework as a whole. Out-of-country generalisation is assessed using Leave-One-Country-Out (LOCO) cross-validation as the primary protocol (mean fold RMSE 0.077; 12 of 18 folds below RMSE 0.10), with a forward-chaining temporal split as a complementary diagnostic. The framework is operationalised through an interactive decision-support interface, offering a scalable, transparent baseline for embodied carbon benchmarking, policy screening, and net-zero pathway evaluation in the global cement sector. The framework is positioned as a screening-level reference for data-scarce contexts, complementary to plant-level LCA and Environmental Product Declarations where these are available.
🔗 Provenance — このレコードを発見したソース
- semanticscholar https://www.sciencedirect.com/science/article/pii/S0301479726018621/pdffirst seen 2026-07-13 07:17:47
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