Hybrid Nanofluids for Low-Carbon Chemical Processes
低炭素化学プロセスのためのハイブリッドナノ流体 (AI 翻訳)
J. Singh
🤖 gxceed AI 要約
日本語
本レビューは、低炭素化学プロセスにおける熱効率向上のためのハイブリッドナノ流体の可能性を探る。2種類以上のナノ粒子を組み合わせることで、熱伝導率や安定性が向上し、CO₂回収やグリーン合成などの用途に有望である。しかし、コストや長期的安定性などの課題が産業導入の障壁となっている。
English
This review examines hybrid nanofluids as advanced heat-transfer media to enhance energy efficiency in low-carbon chemical processes. By combining two or more nanoparticles, they offer synergistic improvements in thermal conductivity and stability, with applications in CO₂ capture, green synthesis, and renewable thermal systems. However, industrial adoption faces challenges including cost, long-term stability, and material compatibility.
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
本論文は、低炭素化学プロセスにおけるエネルギー効率向上に焦点を当てており、日本のGX政策における産業部門の排出削減目標に間接的に関連する。ただし、GX開示や規制との直接的な接点はない。
In the global GX context
This paper contributes to the global GX context by highlighting energy efficiency improvements in chemical processes, which are critical for reducing industrial emissions. It supports the energy transition by improving thermal systems for carbon capture and renewable energy applications, though it does not directly address disclosure frameworks.
👥 読者別の含意
🔬研究者:Researchers in nanofluids and heat transfer will find a comprehensive summary of recent advances and research gaps in hybrid nanofluids for sustainable chemical engineering.
🏢実務担当者:Chemical engineers seeking to improve process efficiency may gain insights into the potential and limitations of hybrid nanofluids for heat exchange and green synthesis.
📄 Abstract(原文)
Hybrid nanofluids have emerged as advanced heat-transfer media with the potential to significantly enhance the energy efficiency of thermal systems used in low-carbon chemical processes. By combining two or more distinct nanoparticles within a base fluid, these engineered suspensions demonstrate synergistic improvements in thermal conductivity, viscosity control, and stability compared to conventional nanofluids. This review synthesizes recent progress in hybrid nanofluid formulation strategies, stabilization techniques, and the underlying thermophysical mechanisms governing heat transfer. Their growing relevance is highlighted across applications such as compact heat exchangers, CO₂ capture and conversion, green chemical synthesis, and renewableenergy-based thermal systems. Although hybrid nanofluids offer substantial opportunities for process intensification and emission reduction, industrial integration remains limited by issues related to cost, long-term stability, pumping requirements, and material compatibility. The paper identifies critical research gaps and outlines future directions necessary for enabling the large-scale deployment of hybrid nanofluids in sustainable chemical engineering.
🔗 Provenance — このレコードを発見したソース
- semanticscholar https://doi.org/10.47363/jeast/2026(8)343first seen 2026-05-05 23:47:04
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