<p>Escalating global climate change has precipitated a dramatic surge in building cooling/heating energy demands, critically undermining urban sustainability. Although dynamic thermal management technologies show potential for reducing architectural carbon footprints, prevailing active regulation systems remain constrained by energy-intensive mode-switching mechanisms and unsustainable operational costs. Here, we develop a zebra-inspired radiative modulator (ZIRM) that achieves climate-customized building thermal management through spatially partitioned integration of radiative cooling (RC) and heating (RH) functional units. The material breakthrough resides in a hybrid thin-film architecture combining a cellulose acetate/Zeolitic imidazolate framework-L (ZIF-L) porous membrane (solar reflectance ∼95%, thermal emissivity ∼0.88) with an MXene/ZIF-67 derived carbon-based absorption layer (solar absorption ∼93%, thermal emissivity ∼0.37), resolving the opto-thermal coupling limitations inherent to conventional materials. Experimental verification demonstrates that programmable regulation of the RC/RH area ratio enables broad-range temperature differential control from −4.3 to 12.1 °C during daytime operation. Building energy simulations reveal ZIRM’s annual energy consumption of 1.45×10<sup>10</sup> GJ, corresponding to 9.9% and 2.7% reductions compared to pure RC and RH systems, respectively. The established “configuration-environment-performance” predictive model pioneers a paradigm-shifting solution for carbon-neutral architecture, synergizing material innovation with climate-customized engineering strategies.</p>

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Zebra-inspired radiative modulator for climate-customized thermal management enabled by metal-organic framework

  • Hetian Lu,
  • Yuxin Liu,
  • Yanli Qi,
  • Yufan Zhou,
  • Zhangbin Yang,
  • Huan Pang

摘要

Escalating global climate change has precipitated a dramatic surge in building cooling/heating energy demands, critically undermining urban sustainability. Although dynamic thermal management technologies show potential for reducing architectural carbon footprints, prevailing active regulation systems remain constrained by energy-intensive mode-switching mechanisms and unsustainable operational costs. Here, we develop a zebra-inspired radiative modulator (ZIRM) that achieves climate-customized building thermal management through spatially partitioned integration of radiative cooling (RC) and heating (RH) functional units. The material breakthrough resides in a hybrid thin-film architecture combining a cellulose acetate/Zeolitic imidazolate framework-L (ZIF-L) porous membrane (solar reflectance ∼95%, thermal emissivity ∼0.88) with an MXene/ZIF-67 derived carbon-based absorption layer (solar absorption ∼93%, thermal emissivity ∼0.37), resolving the opto-thermal coupling limitations inherent to conventional materials. Experimental verification demonstrates that programmable regulation of the RC/RH area ratio enables broad-range temperature differential control from −4.3 to 12.1 °C during daytime operation. Building energy simulations reveal ZIRM’s annual energy consumption of 1.45×1010 GJ, corresponding to 9.9% and 2.7% reductions compared to pure RC and RH systems, respectively. The established “configuration-environment-performance” predictive model pioneers a paradigm-shifting solution for carbon-neutral architecture, synergizing material innovation with climate-customized engineering strategies.