Strain-adjustable reflectivity of polyurethane nanofiber membrane for thermal management applications

Passive radiative cooling technologies are highly attractive in pursuing sustainable development. However, current cooling materials are often static, which makes it difficult to cope with the varying needs of all-weather thermal comfort management. Herein, a strategy is designed to obtain flexible thermoplastic polyurethane nanofiber (Es-TPU) membranes via electrospinning, realizing reversible in-situ solvent-free switching between radiative cooling and solar heating through changes in its optical reflectivity by stretching. In its radiative cooling state (0% strain), the Es-TPU membrane shows a high and angular-independent reflectance of 95.6% in the 0.25-2.5 mu m wavelength range and an infrared emissivity of 93.3% in the atmospheric transparency window (8-13 mu m), reaching a temperature drop of 10 degrees C at midday, with a corresponding cooling power of 118.25 W/ m2. The excellent mechanical properties of the Es-TPU membrane allows the continuous adjustment of reflec-tivity by reversibly stretching it, reaching a reflectivity of 61.1% (Delta R = 34.5%) under an elongation strain of 80%, leading to a net temperature increase of 9.5 degrees C above ambient of an absorbing substrate and an equivalent power of 220.34 W m- 2 in this solar heating mode. The strong haze, hydrophobicity and outstanding aging resistance exhibited by this scalable membrane hold promise for achieving uniform illumination with tunable strength and efficient thermal management in practical applications.

Automated summary

Flexible thermoplastic polyurethane nanofiber membranes were prepared via electrospinning for reversible in-situ switching between radiative cooling and solar heating. The membrane exhibited high reflectance and infrared emissivity in the cooling state, achieving a temperature drop of 10°C at midday. By stretching the membrane, the reflectivity could be adjusted for solar heating, resulting in a temperature increase of 9.5°C above ambient. The membrane also demonstrated strong haze, hydrophobicity, and excellent aging resistance, making it promising for practical applications in uniform illumination and thermal management.