Advanced Fiber Materials, Год журнала: 2024, Номер unknown
Опубликована: Июль 30, 2024
Язык: Английский
Nano Energy, Год журнала: 2025, Номер unknown, С. 110688 - 110688
Опубликована: Янв. 1, 2025
Язык: Английский
Процитировано
5
European Polymer Journal, Год журнала: 2024, Номер 206, С. 112777 - 112777
Опубликована: Янв. 21, 2024
Язык: Английский
Процитировано
16
Micromachines, Год журнала: 2024, Номер 15(10), С. 1226 - 1226
Опубликована: Сен. 30, 2024
Non-invasive medical nanofiber technology, characterized by its high specific surface area, biocompatibility, and porosity, holds significant potential in various domains, including tissue repair biosensing. It is increasingly becoming central to healthcare offering safer more efficient treatment options for contemporary medicine. Numerous studies have explored non-invasive nanofibers recent years, yet a comprehensive overview of the field remains lacking. In this paper, we provide summary applications electrospun fields, considering multiple aspects perspectives. Initially, introduce electrospinning nanofibers. Subsequently, detail their health, health monitoring, personal protection, thermal regulation, wound care, highlighting critical role improving human health. Lastly, paper discusses current challenges associated with offers insights into future development trajectories.
Язык: Английский
Процитировано
14
Advanced Functional Materials, Год журнала: 2024, Номер 34(27)
Опубликована: Фев. 21, 2024
Abstract Maintaining human body temperature under low is crucial to well‐being, thereby urgently requiring for high‐performance warmth retention materials. However, designing such materials with both mechanical robustness and warming up the complex changing outdoor environments remains challenging. Here, a dual‐network structured aerogel micro‐nanofiber/MXene sponge directly synthesized by synchronous occurrence of electrospinning electrospraying. Tailoring phase inversion solution jet creates micro‐nanofibers highly porous structures, which exhibit nanoscale aperture (30–60 nm) high single fiber surface aera (56.5 m 2 g −1 ). Under strong hydrogen bonding interaction, structures are constructed chemical entanglement between self‐assembled MXene networks, achieving robust stretchable compressible property. The nanopores cause Knudsen effect suppress slippage air molecules, enhancing unique capacity block heat energy. Further integrating passive radiative heating active performance as‐designed offers an all‐day personal system rise skin over 3.5 °C. This work may provide new candidates applications within aerospace, energy, transportation, building.
Язык: Английский
Процитировано
13
Advanced Functional Materials, Год журнала: 2024, Номер unknown
Опубликована: Июнь 20, 2024
Abstract Passive radiative cooling is a zero‐energy technology vital for mitigating the energy crisis. However, achieving intelligent thermal management across varying weather conditions (day/night and summer/winter) while maintaining sustainability significant challenge. Here, recyclable biomass film engineered adaptive, year‐round conservation introduced. This utilizes porous acetyl cellulose (AC) as cooling‐side matrix, enabling efficient during hot days (8.5 °C reduction) minimizing overcooling on cold nights (only 2.5 reduction). performance facilitated by high solar reflectance (96.3%) broad‐spectrum infrared emission (95.4%), optimizing atmospheric regulation. The reverse side, coated with carbon black (CB), demonstrates superior heating (20.9 increase), allowing effortless switching between flipping film. Further, employs solvent‐responsive ethyl (EC) adhesion, ensuring durability, complete recycling, reuse. With ultraviolet (UV) resistance, self‐cleaning, coupled management, this work provides new ideas advanced heat materials, adaptive control both daytime/nighttime summer/winter.
Язык: Английский
Процитировано
12
Chemical Engineering Journal, Год журнала: 2024, Номер 488, С. 150873 - 150873
Опубликована: Март 31, 2024
Язык: Английский
Процитировано
11
Journal of Materials Chemistry A, Год журнала: 2024, Номер 12(25), С. 14866 - 14884
Опубликована: Янв. 1, 2024
This review provides a comprehensive overview of radiative cooling textiles from fundamentals, advanced structures and construction strategies to emerging applications.
Язык: Английский
Процитировано
10
Advanced Functional Materials, Год журнала: 2024, Номер unknown
Опубликована: Сен. 16, 2024
Abstract Phase‐change textiles can achieve temperature regulation in variable ambient environments, however, augmenting the amounts of phase‐change materials (PCMs) remains a significant challenge due to occurrence leakage with higher amounts. Herein, novel approach is proposed for fabrication hierarchical nanofiber textile embedded substantial quantity microcapsules (PCMC) using electrospinning. Such composed polyvinylidene fluoride‐hexafluoropropylene fibers (PVDF‐HFP) layer and polyvinyl butyral doped 60 wt% PCMC (PVB/PCMC‐60) layer. Gratifyingly, shows no signs rupture exhibits excellent cycling stability. Furthermore, incorporation does not affect spectral characteristics PVDF‐HFP while providing enthalpy fusion (92.6 J g −1 ) PVB/PCMC‐60 This serves compensate deficiency radiative cooling capacity effectively mitigates fluctuations overheating textile. Outdoor test results indicate that drops 3.7 14.8 °C compared without (namely PVDF‐HFP/PVB) cotton, attains subambient drop 6.5 °C. Additionally, desirable mechanical strength, flexibility, washability, breathability, moisture permeability, sun protection.
Язык: Английский
Процитировано
10
Chemical Engineering Journal, Год журнала: 2025, Номер 506, С. 159916 - 159916
Опубликована: Янв. 1, 2025
Язык: Английский
Процитировано
2
ACS Applied Polymer Materials, Год журнала: 2025, Номер unknown
Опубликована: Фев. 9, 2025
Язык: Английский
Процитировано
2