Thermal Energy Storage integration with Nuclear Power: Material challenges and Innovation pathways towards Flexible Low-Carbon Systems

Yelaman Maksum; Siyuan Dai; R. Deepak Selvakumar; Tongtong Zhang; Ahmed K. Alkaabi; Yulong Ding

doi:10.1016/j.cnt.2026.100016

Thermal Energy Storage integration with Nuclear Power: Material challenges and Innovation pathways towards Flexible Low-Carbon Systems

Yelaman Maksum
, Siyuan Dai
, R. Deepak Selvakumar
, Tongtong Zhang^*
, Ahmed K. Alkaabi^*
, Yulong Ding

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

Recent accelerated shift towards deep decarbonisation demands nuclear power to evolve from baseload generation into flexible one with multi services. The integration of thermal energy storage (TES) with nuclear reactors provides a promising pathway to decouple heat and power functions, enabling steady-state reactor operation while allowing the delivery of dispatchable electricity and industrial process heat. This perspective paper outlines the material, component, and system-level challenges constraining TES deployment under the nuclear contexts - particularly corrosion, thermal fatigue, and irradiation effects under high-temperature molten salt and phase-change environments. Advances in alloy design, redox-controlled salt chemistry, modular TES architectures, and predictive control strategies are identified as critical innovation levers. Drawing on lessons from concentrated solar power and small modular reactor development, the paper proposes a roadmap for cross-sector collaboration and standardised materials qualification. Overcoming these barriers could reposition nuclear power plants as flexible, carbon-neutral energy hubs, bridging clean energy generation with heat and power applications across future integrated energy systems.

Original language	English
Article number	100016
Journal	Carbon Neutral Technologies
Early online date	5 Mar 2026
DOIs	https://doi.org/10.1016/j.cnt.2026.100016
Publication status	E-pub ahead of print - 5 Mar 2026

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 9 Industry, Innovation, and Infrastructure

Keywords

Thermal energy storage
Nuclear power
Small modular reactors
Molten salts
Corrosion and irradiation
Flexible low-carbon systems

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10.1016/j.cnt.2026.100016Licence: Creative Commons: Attribution-NonCommercial-NoDerivs (CC BY-NC-ND)

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title = "Thermal Energy Storage integration with Nuclear Power: Material challenges and Innovation pathways towards Flexible Low-Carbon Systems",

abstract = "Recent accelerated shift towards deep decarbonisation demands nuclear power to evolve from baseload generation into flexible one with multi services. The integration of thermal energy storage (TES) with nuclear reactors provides a promising pathway to decouple heat and power functions, enabling steady-state reactor operation while allowing the delivery of dispatchable electricity and industrial process heat. This perspective paper outlines the material, component, and system-level challenges constraining TES deployment under the nuclear contexts - particularly corrosion, thermal fatigue, and irradiation effects under high-temperature molten salt and phase-change environments. Advances in alloy design, redox-controlled salt chemistry, modular TES architectures, and predictive control strategies are identified as critical innovation levers. Drawing on lessons from concentrated solar power and small modular reactor development, the paper proposes a roadmap for cross-sector collaboration and standardised materials qualification. Overcoming these barriers could reposition nuclear power plants as flexible, carbon-neutral energy hubs, bridging clean energy generation with heat and power applications across future integrated energy systems.",

keywords = "Thermal energy storage, Nuclear power, Small modular reactors, Molten salts, Corrosion and irradiation, Flexible low-carbon systems",

author = "Yelaman Maksum and Siyuan Dai and Selvakumar, \{R. Deepak\} and Tongtong Zhang and Alkaabi, \{Ahmed K.\} and Yulong Ding",

year = "2026",

month = mar,

day = "5",

doi = "10.1016/j.cnt.2026.100016",

language = "English",

journal = "Carbon Neutral Technologies",

issn = "3050-6603",

publisher = "Elsevier Korea",

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T1 - Thermal Energy Storage integration with Nuclear Power

T2 - Material challenges and Innovation pathways towards Flexible Low-Carbon Systems

AU - Maksum, Yelaman

AU - Dai, Siyuan

AU - Selvakumar, R. Deepak

AU - Zhang, Tongtong

AU - Alkaabi, Ahmed K.

AU - Ding, Yulong

PY - 2026/3/5

Y1 - 2026/3/5

N2 - Recent accelerated shift towards deep decarbonisation demands nuclear power to evolve from baseload generation into flexible one with multi services. The integration of thermal energy storage (TES) with nuclear reactors provides a promising pathway to decouple heat and power functions, enabling steady-state reactor operation while allowing the delivery of dispatchable electricity and industrial process heat. This perspective paper outlines the material, component, and system-level challenges constraining TES deployment under the nuclear contexts - particularly corrosion, thermal fatigue, and irradiation effects under high-temperature molten salt and phase-change environments. Advances in alloy design, redox-controlled salt chemistry, modular TES architectures, and predictive control strategies are identified as critical innovation levers. Drawing on lessons from concentrated solar power and small modular reactor development, the paper proposes a roadmap for cross-sector collaboration and standardised materials qualification. Overcoming these barriers could reposition nuclear power plants as flexible, carbon-neutral energy hubs, bridging clean energy generation with heat and power applications across future integrated energy systems.

AB - Recent accelerated shift towards deep decarbonisation demands nuclear power to evolve from baseload generation into flexible one with multi services. The integration of thermal energy storage (TES) with nuclear reactors provides a promising pathway to decouple heat and power functions, enabling steady-state reactor operation while allowing the delivery of dispatchable electricity and industrial process heat. This perspective paper outlines the material, component, and system-level challenges constraining TES deployment under the nuclear contexts - particularly corrosion, thermal fatigue, and irradiation effects under high-temperature molten salt and phase-change environments. Advances in alloy design, redox-controlled salt chemistry, modular TES architectures, and predictive control strategies are identified as critical innovation levers. Drawing on lessons from concentrated solar power and small modular reactor development, the paper proposes a roadmap for cross-sector collaboration and standardised materials qualification. Overcoming these barriers could reposition nuclear power plants as flexible, carbon-neutral energy hubs, bridging clean energy generation with heat and power applications across future integrated energy systems.

KW - Thermal energy storage

KW - Nuclear power

KW - Small modular reactors

KW - Molten salts

KW - Corrosion and irradiation

KW - Flexible low-carbon systems

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DO - 10.1016/j.cnt.2026.100016

M3 - Article

SN - 3050-6603

JO - Carbon Neutral Technologies

JF - Carbon Neutral Technologies

M1 - 100016

ER -

Thermal Energy Storage integration with Nuclear Power: Material challenges and Innovation pathways towards Flexible Low-Carbon Systems

Abstract

UN SDGs

Keywords

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