Ambient Pressure Drying of Freeze-Cast Ceramics from Aqueous Suspension

Gao, Yu-Cheng; Qin, Bing; Wen, Shao-Meng; You, Yang; Xue, JingZhe; Yin, Yi-Chen; Ma, Zhi-Yuan; Dong, Kang; Meng, Yu-Feng; Manke, Ingo; Zhang, Si-Chao; Yu, Zhi-Long; Yu, Shu-Hong

doi:10.1021/acs.nanolett.3c02654

Cited by 3 publications

(2 citation statements)

References 44 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…A great interface between organic/inorganic parts is critical and has a direct influence on materials’ mechanical properties and construction performance. , Introducing inorganic materials with functional groups such as hydroxyl into organic substances can effectively improve the interface and enhance the mechanical properties of the composite materials. − However, the extremely high interface can lead to the interlocking of inorganic components, forming thermal bridges and thus leading to an increase in the thermal conductivity. − Therefore, preparing porous materials with high mechanical performance, high fire resistance, and high thermal insulation performance is of great significance but faces significant challenges. Constructing anisotropic porous organic/inorganic composites with oriented hierarchical porous structures could be an approach to address the aforementioned issues. − The organic component forms the material framework, while the inorganic component imparts excellent fire resistance to the composite material. , The anisotropic porous structure could be obtained by freeze orientation processes. , An excellent dispersion of solutes in low-temperature aqueous solvents is critical for the freeze orientation processes to obtain oriented hierarchical porous structures in anisotropic materials. − …”

Section: Introductionmentioning

confidence: 99%

An Anisotropic Noncombustible Nanocomposite Based on a Fiberglass–Chitosan 3D Network for Building Insulation

Feng,

Yuan,

Wan

et al. 2024

ACS Appl. Nano Mater.

View full text Add to dashboard Cite

Insulation materials can effectively reduce heat loss by conduction, thereby conserving energy in buildings. Traditional insulation materials usually consist of organic compounds, which are flammable. Despite the application of inorganic materials, such as fiberglass (GF), for their flame-retardant properties, their poor insulating performance and difficulties in dispersion and molding limit their use in construction. Therefore, creating a composite that effectively combines the high thermal insulation properties of organic materials with the high flame resistance of inorganic materials holds significant importance, yet poses substantial challenges. Herein, an Anisotropic Noncombustible Nanocomposite based on Fiberglass-Chitosan (ANNFC) has been prepared. GF was uniformly dispersed into the chitosan (CS) solution though hydrogen bonding. The ANNFC with anisotropic layered structures was prepared through a freeze-orientation process. The as-prepared ANNFC reached a high limiting oxygen index (LOI) of 99.48%, exhibited a low heat release rate (peak at 26 kW m −2 ), a low smoke production rate (peak at 0.00143 m 2 s −1 ), and a high compressive modulus (3.65 MPa). As a conceptual demonstration, a mini house was constructed using ANNFC. After being baked at a high temperature of 50 °C for 1 h, the interior of the ANNFC house maintained a relatively steady temperature of 37 °C. Therefore, the successfully constructed ANNFC provided a feasible path for fabricating thermal insulation materials for construction.

show abstract

Section: Introductionmentioning

confidence: 99%

An Anisotropic Noncombustible Nanocomposite Based on a Fiberglass–Chitosan 3D Network for Building Insulation

Feng,

Yuan,

Wan

et al. 2024

ACS Appl. Nano Mater.

View full text Add to dashboard Cite

show abstract

“…In fact, the drying step significantly affects the crystallinity and porosity of regenerated cellulose materials (e.g., cellulose aerogel). Various drying methods have been attempted, including freeze drying, supercritical fluid drying, ambient pressure drying, vacuum drying, and microwave drying . Among these, freeze drying and supercritical fluid drying are popular.…”

Section: Introductionmentioning

confidence: 99%

Engineering High-Performance Composite Cellulose Materials for Fast Hemostasis

Wang,

Li,

Wei

et al. 2024

ACS Biomater. Sci. Eng.

View full text Add to dashboard Cite

The development of an effective hemostatic agents is of vital importance for saving wounded individuals from uncontrolled hemorrhage, which is the main reason for preventable death after accidental injury. However, current high-performance hemostatic agents suffer from a cumbersome preparation procedures and poor biocompatibility. Here, we engineered a cellulosic-derived aerogel material by simply controlling the drying process of cellulose regeneration for fast hemostasis. Four different freeze-drying pretreatments were investigated. As compared with the other three, the cellulosic aerogel material prepared without freezing pretreatment exhibited the lowest crystallinity (21.3%) and the highest body fluid absorption capacity (20.3 times that of its own weight) due to its super hierarchical porous structure, which led to an excellent hemostatic performance in vitro blood coagulation (≈100 s). Moreover, the addition of gelatin and diatomite in the material could tune the functional groups and electrostatic properties of the aerogel and further enhance its hemostatic performance. Various characterizations, including X-ray diffraction (XRD), fourier transform infrared spectroscopy (FTIR), X-ray nanocomputed tomography (CT), scanning electron microscopy (SEM), and zeta potential analysis, were carried out to probe the structure−function relationship of the prepared material, and its mechanism of fast hemostasis was thereafter revealed. The results indicate that the developed aerogel is a cost-effective and feasibly scalable hemostatic material suitable for practical use in industry.

show abstract