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学者姓名:郑玉婴
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A series of boron-doped graphene-supported nanoflower-catalysts (nf-MnOx/BG) were synthesized using an in- situ method to boost intrinsic catalytic performance. The regulation of catalyst structure, morphology, and active sites was systematically researched to explore the promoting factors of catalytic activity. The prepared nf-MnOx/ BG-3 catalyst achieves superior NH3-SCR performance throughout the test process (>= 90% NOx conversion at the temperature ranging from 140 to 280 degrees C), comparable to the current mainstream graphene-based catalyst. The ratios of O alpha/(O alpha + O beta) and Mn4+/Mn3+are effectively increased by boron atom doping, which is strongly associated with excellent catalytic deNOx efficiency. Meanwhile, the boron sites with unpaired electronic structures accelerate the reaction of fast-SCR by promoting oxidation and adsorption of nitrogen oxide species. Interestingly, the boron sites can be used as an additional Lewis acid and adsorbed NO2 site to participate in the low-temperature SCR reaction and effectively improve the low-temperature activity.
Keyword :
Boron-doped Boron-doped deNO x efficiency deNO x efficiency Fast-SCR Fast-SCR In-situ method In-situ method Nanoflower-catalysts Nanoflower-catalysts
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| GB/T 7714 | Zheng, Weijie , Zhang, Zhiwei , Hong, Xiansheng et al. Boron-doped graphene-based nanoflower-catalyst promoting low temperature NH3-SCR performance: An interesting site [J]. | ENVIRONMENTAL RESEARCH , 2025 , 274 . |
| MLA | Zheng, Weijie et al. "Boron-doped graphene-based nanoflower-catalyst promoting low temperature NH3-SCR performance: An interesting site" . | ENVIRONMENTAL RESEARCH 274 (2025) . |
| APA | Zheng, Weijie , Zhang, Zhiwei , Hong, Xiansheng , Zheng, Yuying . Boron-doped graphene-based nanoflower-catalyst promoting low temperature NH3-SCR performance: An interesting site . | ENVIRONMENTAL RESEARCH , 2025 , 274 . |
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Slow rebound polyurethane foam (SPUF) has developed rapidly because of its excellent performance in sound insulation, energy absorption, and tactile sensation. However, the friction-induced electrostatic charge accumulation occurs easily due to its high resistivity. In this paper, dimethyl octadecyl hydroxy ethyl ammonium nitrate (SN) intercalated reduced graphene oxide (SN-RGO) were prepared as the conductive agent. The antistatic slow rebound polyurethane foam (ASR-PUF) was prepared with SN-RGO/carbon black as antistatic system and silicone-modified polyethylene glycol (Si-APEG) as low temperature resistant agent. The structures of SN-RGO were investigated by Fourier transform infrared spectra (FT-IR), wide-angle X-ray diffraction (WAXD), and scanning electron microscope (SEM), respectively. The effects SN-RGO on the structures, mechanical properties, low-temperature resistance, and antistatic property of ASR-PUF were studied. It was found that SN-RGO acts as heterogeneous cell nucleating agent, which slightly increases the apparent core density and slightly decreases the porosity of ASR-PUF. The addition of SN-RGO increases both the tensile strength and elongation at break of ASR-PUF, and has little effect on the temperature sensitive index. The surface resistance of ASR-PUF decreases to 1.1 x 108 Omega with a SN-RGO content of 4 wt%, thereby achieving an antistatic effect.Highlights SN-RGO acts as heterogeneous cell nucleating agent in PU foaming. SN-RGO/carbon black provide good antistatic property and mechanical properties without affecting the low-temperature resistance of ASR-PUF. ASR-PUF with an appropriate content of SN-RGO exhibits excellent comprehensive performance.
Keyword :
antistatic antistatic intercalated reduced graphene oxide intercalated reduced graphene oxide low-temperature resistance low-temperature resistance polyurethane foam polyurethane foam
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| GB/T 7714 | Cao, Jing , Wang, Li , Zheng, Yuying . Preparation of antistatic slow rebound polyurethane foam based on dimethyl octadecyl hydroxy ethyl ammonium nitrate intercalated reduced graphene oxide/carbon black antistatic system [J]. | POLYMER ENGINEERING AND SCIENCE , 2025 . |
| MLA | Cao, Jing et al. "Preparation of antistatic slow rebound polyurethane foam based on dimethyl octadecyl hydroxy ethyl ammonium nitrate intercalated reduced graphene oxide/carbon black antistatic system" . | POLYMER ENGINEERING AND SCIENCE (2025) . |
| APA | Cao, Jing , Wang, Li , Zheng, Yuying . Preparation of antistatic slow rebound polyurethane foam based on dimethyl octadecyl hydroxy ethyl ammonium nitrate intercalated reduced graphene oxide/carbon black antistatic system . | POLYMER ENGINEERING AND SCIENCE , 2025 . |
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The gradual permeation of corrosive mediums, external mechanical damage, and ultraviolet (UV) radiation-induced aging are critical factors contributing to the rapid deterioration of the anticorrosive functionality of polymer coatings. In this study, a two-dimensional anticorrosive enhancement material, fluorinated graphene loaded with zinc oxide nanoparticles (FG@ZnO), was synthesized via the heterogeneous nucleation growth method. This material was then embedded into a polyurethane coating to modify the coating matrix, and a biomimetic lotus leaf-like fine micro-nanostructure was fabricated on the coating surface employing a templating approach. Through this internal-external dual modification strategy, an FG@ZnO/SPU composite coating with multiple protective functions was constructed to offer enduring corrosion protection to the steel substrate. Experimental findings reveal that the composite coating exhibits excellent superhydrophobicity, with a water contact angle as high as 152°. Even after immersion in a 3.5 % NaCl solution for 80 days, the composite coating maintains an exceptionally high low-frequency impedance modulus of 1.332 × 1010 Ω cm2, demonstrating exceptional long-term anticorrosive performance. In instances of coating damage, FG@ZnO markedly relieves the corrosion reaction between the corrosive medium and the steel substrate while suppressing galvanic corrosion. Furthermore, the composite coating demonstrates effective resistance against UV radiation-induced aging effects. These exceptional multiple protective properties are attributed to the internal-external dual modification effect of embedded FG@ZnO and biomimetic lotus leaf hydrophobic modification. This study provides an attractive strategy for preparing polymer composite coatings with multiple protective functions for enduring corrosion protection of metals. © 2024 Elsevier B.V.
Keyword :
Biomimetics Biomimetics Composite coatings Composite coatings Contact angle Contact angle Corrosion inhibitors Corrosion inhibitors Corrosion resistant coatings Corrosion resistant coatings Deterioration Deterioration Hydrophobicity Hydrophobicity II-VI semiconductors II-VI semiconductors Polyurethanes Polyurethanes Sodium chloride Sodium chloride Steel corrosion Steel corrosion Synthesis (chemical) Synthesis (chemical) Zinc alloys Zinc alloys Zinc coatings Zinc coatings Zinc oxide Zinc oxide
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| GB/T 7714 | Zhang, Jie , Zheng, Yuying . Constructing multi-protective functional polyurethane composite coating via internal-external dual modification: Achieving superhydrophobicity, enhanced barrier, corrosion inhibition, and UV aging resistance properties [J]. | Progress in Organic Coatings , 2024 , 194 . |
| MLA | Zhang, Jie et al. "Constructing multi-protective functional polyurethane composite coating via internal-external dual modification: Achieving superhydrophobicity, enhanced barrier, corrosion inhibition, and UV aging resistance properties" . | Progress in Organic Coatings 194 (2024) . |
| APA | Zhang, Jie , Zheng, Yuying . Constructing multi-protective functional polyurethane composite coating via internal-external dual modification: Achieving superhydrophobicity, enhanced barrier, corrosion inhibition, and UV aging resistance properties . | Progress in Organic Coatings , 2024 , 194 . |
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Cleanup of oil spills has become one of the most challenging tasks in recent years, as marine oil spills have had a great negative impact on human health and the ecological environment. This also urgently requires the development of new materials and methods with superhydrophobic properties for oil–water separation. As new porous materials, metal–organic frameworks (MOFs) have attracted much attention due to their unique structures and fascinating properties. However, powdered MOF materials are difficult to recycle, and therefore, suitable substrates need to be selected to construct superhydrophobic composites. The surface hydroxyl groups of cellulose fibers offer great possibilities for their superhydrophobic preparation. In this paper, HDTMS‐UiO‐66@CFs composites with superhydrophobicity were strategically synthesized by in‐situ growth of Zr(IV)‐based MOFs linked to hexadecyltrimethoxysilane (HDTMS) on cellulosic fibers (cotton fabric) by using a hydrothermal synthesis method. The HDTMS‐UiO‐66@CFs composites have a water contact angle of 172° and the absorption capacity of light oil and heavy oil is more than 1100%, and the oil–water separation efficiency is as high as 96%. Due to the in‐situ growth of the HDTMS‐UiO‐66 material on cotton fibers, which makes the material more resistant and stable, the material can still maintain its superhydrophobic properties in various harsh environments and after repeated use. Therefore, the newly developed HDTMS‐UiO‐66@CFs composites have a high potential as novel adsorbent materials for cleaning up offshore oil spills and other applications.HighlightsIn‐situ growth of superhydrophobic metal‐organic frameworks (MOF) particles on cellulose fibers.The porous structure of hexadecyltrimethoxysilane (HDTMS)‐UiO66 plays a key role in hydrophobicity.HDTMS‐UiO66@CFs are chemically stable and have long‐term durability.
Keyword :
cotton fabrics cotton fabrics hydrophobicity hydrophobicity oil—water separation oil—water separation zirconium-based metal-organic framework zirconium-based metal-organic framework
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| GB/T 7714 | Hanwen Hu , Yu Li , Xiansheng Hong et al. A superhydrophobic zirconium‐based metal‐organic framework/cellulose fiber composite material [J]. | Polymer Engineering & Science , 2024 , 64 (5) : 1981-1992 . |
| MLA | Hanwen Hu et al. "A superhydrophobic zirconium‐based metal‐organic framework/cellulose fiber composite material" . | Polymer Engineering & Science 64 . 5 (2024) : 1981-1992 . |
| APA | Hanwen Hu , Yu Li , Xiansheng Hong , Qian Li , Ranyi Rao , Ziyu Gong et al. A superhydrophobic zirconium‐based metal‐organic framework/cellulose fiber composite material . | Polymer Engineering & Science , 2024 , 64 (5) , 1981-1992 . |
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Slow rebound polyurethane foam (SPUF) has been widely used due to its advantages such as sound insulation, energy absorption, and good tactile sensation. However, SPUF is prone to harden at low temperature, and its application in medical equipment and households requires significant antibacterial properties. In this paper, self‐made silicone modified polyethylene glycol (Si‐APEG) and graphene oxide supported allicin (Alc@GO) were prepared and used as low‐temperature resistant agent and antibacterial agent, respectively. Low‐temperature resistant polyurethane foam (LSPUF) and antibacterial LSPUF (ALSPUF) were prepared respectively with water as foaming agent. The morphology of ALSPUF was observed by scanning electron microscope. Properties studied include apparent core density and porosity, mechanical properties including tensile strength, 40% compressive hardness, and rebound resilience, as well as low‐temperature resistance. Effects of Si‐APEG content on the structures and properties were analyzed and the LSPUF with an Si‐APEG content of 10 wt.% showed the best comprehensive performance. Therefore, ALSPUFs with Si‐APEG content of 10 wt.% and Alc@GO content of 0–3 wt.% were prepared. The addition of Alc@GO increased the antibacterial ratio significantly without obvious effect on the structure and mechanical properties of LSPUF. The antibacterial ratio of ALSPUF reached 99.07% at a Alc@GO content of 2.5 wt.% and testing time of 60 min. This work provides an effective and feasible method for the preparation of ALSPUF which can be widely used in medical devices and households.HighlightsSilicone modified polyether is a suitable low‐temperature resistant agent for PU foam.Allicin supported on GO provides good antibacterial property for PU foam.ALSPUF has better mechanical properties than SPU.
Keyword :
antibacterial properties antibacterial properties graphene oxide supported allicin graphene oxide supported allicin low-temperature resistance low-temperature resistance silicone modified polyethylene silicone modified polyethylene slow rebound polyurethane foam slow rebound polyurethane foam
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| GB/T 7714 | Jing Cao , Li Wang , Yuying Zheng . Synthesis and characterization of antibacterial and low‐temperature resistant slow rebound polyurethane foams [J]. | Polymer Engineering & Science , 2024 , 64 (10) : 4709-4719 . |
| MLA | Jing Cao et al. "Synthesis and characterization of antibacterial and low‐temperature resistant slow rebound polyurethane foams" . | Polymer Engineering & Science 64 . 10 (2024) : 4709-4719 . |
| APA | Jing Cao , Li Wang , Yuying Zheng . Synthesis and characterization of antibacterial and low‐temperature resistant slow rebound polyurethane foams . | Polymer Engineering & Science , 2024 , 64 (10) , 4709-4719 . |
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In recent years, thermoplastic polyurethane elastomer has shown great application prospects in the fields of polymer film due to its outstanding tensile properties, high elasticity, wear resistance, oil resistance, low temperature resistance, wide range of hardness, and other properties. However, its flammable properties greatly limit its application in the field of polymer film. The self-made GO was used as a carbon source, phenylboronic acid as an acid source, ammonium polyphosphate (APP) as an acid and gas source, and intumescent flame retardant (IFR) was compounded. The IFR was introduced into thermoplastic polyurethane (TPU) to prepare a series of IFR/TPU composite films with different formulations. The results show that PA and GO can make up for the loss of mechanical properties caused by the addition of APP and improve the thermal stability of the composite film, and the IFR flame retardant composed of the two and APP can effectively improve the flame retardancy of the composite film. When the additions of APP, PA, and GO were 10, 3, and 0.75%, respectively, the LOI value of the IFR/TPU composite material reached 29.5, the flame-retardant grade reached V-0, and its peak heat release rate, total heat release, peak smoke production rate, and total smoke release were 86.0, 64.9, 70.5, and 21.7%, greatly lower than pure TPU, respectively. The flame retardancy of the spacer composite membrane constructed from Ti-7 was significantly improved, and the burn-through time of the single-layer film sample was increased by 2.22 times, and the double-layer film sample was increased by 2.63 times.
Keyword :
Expansion flame retardant Expansion flame retardant Flame-retardant Flame-retardant Mechanical properties Mechanical properties Space composite film Space composite film Thermoplastic polyurethane elastomer Thermoplastic polyurethane elastomer
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| GB/T 7714 | Zheng, Weijie , Cai, Qingshu , Xiong, Lei et al. Highly efficient GO-based synergistic intumescent flame retardant/thermoplastic polyurethane for spatial composite film: insight into flame retardancy and mechanism [J]. | JOURNAL OF THERMAL ANALYSIS AND CALORIMETRY , 2024 , 149 (14) : 7289-7300 . |
| MLA | Zheng, Weijie et al. "Highly efficient GO-based synergistic intumescent flame retardant/thermoplastic polyurethane for spatial composite film: insight into flame retardancy and mechanism" . | JOURNAL OF THERMAL ANALYSIS AND CALORIMETRY 149 . 14 (2024) : 7289-7300 . |
| APA | Zheng, Weijie , Cai, Qingshu , Xiong, Lei , Zheng, Yuying . Highly efficient GO-based synergistic intumescent flame retardant/thermoplastic polyurethane for spatial composite film: insight into flame retardancy and mechanism . | JOURNAL OF THERMAL ANALYSIS AND CALORIMETRY , 2024 , 149 (14) , 7289-7300 . |
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Cleanup of oil spills has become one of the most challenging tasks in recent years, as marine oil spills have had a great negative impact on human health and the ecological environment. This also urgently requires the development of new materials and methods with superhydrophobic properties for oil-water separation. As new porous materials, metal-organic frameworks (MOFs) have attracted much attention due to their unique structures and fascinating properties. However, powdered MOF materials are difficult to recycle, and therefore, suitable substrates need to be selected to construct superhydrophobic composites. The surface hydroxyl groups of cellulose fibers offer great possibilities for their superhydrophobic preparation. In this paper, HDTMS-UiO-66@CFs composites with superhydrophobicity were strategically synthesized by in-situ growth of Zr(IV)-based MOFs linked to hexadecyltrimethoxysilane (HDTMS) on cellulosic fibers (cotton fabric) by using a hydrothermal synthesis method. The HDTMS-UiO-66@CFs composites have a water contact angle of 172 degrees and the absorption capacity of light oil and heavy oil is more than 1100%, and the oil-water separation efficiency is as high as 96%. Due to the in-situ growth of the HDTMS-UiO-66 material on cotton fibers, which makes the material more resistant and stable, the material can still maintain its superhydrophobic properties in various harsh environments and after repeated use. Therefore, the newly developed HDTMS-UiO-66@CFs composites have a high potential as novel adsorbent materials for cleaning up offshore oil spills and other applications.Highlights In-situ growth of superhydrophobic metal-organic frameworks (MOF) particles on cellulose fibers. The porous structure of hexadecyltrimethoxysilane (HDTMS)-UiO66 plays a key role in hydrophobicity. HDTMS-UiO66@CFs are chemically stable and have long-term durability. Schematic diagram of the preparation process and properties of superhydrophobic zirconium-based metal-organic framework/cellulose fiber composites. image
Keyword :
cotton fabrics cotton fabrics hydrophobicity hydrophobicity oil-water separation oil-water separation zirconium-based metal-organic framework zirconium-based metal-organic framework
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| GB/T 7714 | Hu, Hanwen , Li, Yu , Hong, Xiansheng et al. A superhydrophobic zirconium-based metal-organic framework/cellulose fiber composite material [J]. | POLYMER ENGINEERING AND SCIENCE , 2024 , 64 (5) : 1981-1992 . |
| MLA | Hu, Hanwen et al. "A superhydrophobic zirconium-based metal-organic framework/cellulose fiber composite material" . | POLYMER ENGINEERING AND SCIENCE 64 . 5 (2024) : 1981-1992 . |
| APA | Hu, Hanwen , Li, Yu , Hong, Xiansheng , Li, Qian , Rao, Ranyi , Gong, Ziyu et al. A superhydrophobic zirconium-based metal-organic framework/cellulose fiber composite material . | POLYMER ENGINEERING AND SCIENCE , 2024 , 64 (5) , 1981-1992 . |
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P-N-B organic flame retardant was synthesized using 4-formylphenylboronic acid, 4-aminophenylthiophenol, 9,10-dihydro-9-oxa-10-phos-phaphenanthrene-10-oxide (DOPO), and then introduced into the hydroxyl-terminated polybutadiene acrylonitrile (HTBN) molecular chain to successfully prepare a macromolecular flame retardant, which was used to prepare flame retardant waterborne polyurethane. The mechanical properties, thermal properties, and flame retardancy of waterborne polyurethane (FR-WPU) were studied using thermogravimetic analysis (TGA), limiting oxygen index (LOI), scanning electron microscope (SEM), cone calorimeter, and universal testing machine, respectively, and the flame retardant mechanism of macromolecular flame retardants was explored. An LOI value of 29.76% and a UL-94 V-0 rating could be realized when the APFBH conjugation is 7.5 wt%, showing a significant improvement of melt dripping behavior and flame retardancy. It indicated that the fire resistance of FR-WPU remarkably improved and displayed both gas and condensed phase mechanism. As the content of APBDH increased, the tensile strength and the elongation at break of FR-WPU increased firstly and then decreased.
Keyword :
boron boron flame retardancy flame retardancy functionalization of polymers functionalization of polymers waterborne polyurethane waterborne polyurethane
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| GB/T 7714 | Luo, Yaofa , Jiang, Ronghua , Xu, Yihao et al. Preparation and performance of waterborne polyurethane coatings based on the intumescent flame retardant of boron, phosphorus, and nitrogen [J]. | JOURNAL OF APPLIED POLYMER SCIENCE , 2024 , 142 (7) . |
| MLA | Luo, Yaofa et al. "Preparation and performance of waterborne polyurethane coatings based on the intumescent flame retardant of boron, phosphorus, and nitrogen" . | JOURNAL OF APPLIED POLYMER SCIENCE 142 . 7 (2024) . |
| APA | Luo, Yaofa , Jiang, Ronghua , Xu, Yihao , Wang, Hui , Qiu, Zeping , Huang, Jin et al. Preparation and performance of waterborne polyurethane coatings based on the intumescent flame retardant of boron, phosphorus, and nitrogen . | JOURNAL OF APPLIED POLYMER SCIENCE , 2024 , 142 (7) . |
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Polymer matrix composites with excellent thermal management performance have emerged as remarkable materials in the realms of microelectronic devices and wireless communication technologies. However, achieving high thermal conductivity in most composites often requires a high filling load, which will compromise other desirable properties. Herein, utilizing physical foaming and vacuum infiltration methods, we introduce a 3D honeycomb composite consisting of surface-hydroxylated hexagonal boron nitride (OH-BN) and epoxy. The 3D OH-BN honeycomb foam in the composite features a lightweight design (0.33 g/cm3), high strength (7178 times its own weight) and prominent heat transfer performance. Significantly, these composites achieve notable thermal properties, including high through-plane thermal conductivity (2.073 W m- 1 K-1) and relatively low thermal resistance (0.995 degrees C/W) at a reduced filling load (17.2 vol%). In comparison with pure epoxy, the through-plane thermal conductivity is enhanced by an impressive 894 %, while the thermal resistance is reduced to 1/9.4 of that observed in pure epoxy. Besides, the 3D honeycomb composites combine outstanding mechanical performance, low dielectric properties and excellent insulation, underscoring their potential in the field of thermal management applications in microelectronic devices, wireless communication systems and integrated circuits.
Keyword :
3D thermal conduction networks 3D thermal conduction networks Boron nitride Boron nitride Epoxy composites Epoxy composites Thermal management Thermal management Thermal resistance Thermal resistance
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| GB/T 7714 | Liu, Guang , Ding, Ao , Xu, Pingfan et al. Thermal conductivity of epoxy composites containing 3D honeycomb boron nitride filler [J]. | CHEMICAL ENGINEERING JOURNAL , 2024 , 489 . |
| MLA | Liu, Guang et al. "Thermal conductivity of epoxy composites containing 3D honeycomb boron nitride filler" . | CHEMICAL ENGINEERING JOURNAL 489 (2024) . |
| APA | Liu, Guang , Ding, Ao , Xu, Pingfan , Zhu, Minmin , Zhang, Haizhong , Zheng, Yuying et al. Thermal conductivity of epoxy composites containing 3D honeycomb boron nitride filler . | CHEMICAL ENGINEERING JOURNAL , 2024 , 489 . |
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In recent years, loading antioxidants onto inorganic nanoparticles has attracted increasing interest. However, the existing studies not only have low antioxidant loading efficiency, but also ignore the relationship between structural changes and antioxidant properties before and after antioxidant modification, greatly limiting the improvement of the antioxidant properties of composites and their application scope. In this work, we successfully prepared bis-hindered phenolic antioxidants containing silica hydroxyl groups (Bis-mAO) and loaded them onto silicon dioxide (SiO 2 ) to get the nanocomposites (Bis-mAO-SiO 2 ). The melt blending method further prepared the corresponding polyphenylene sulfide (PPS)/Bis-mAO-SiO 2 composites. The results showed that the higher antioxidant loading and more suitable antioxidant structure made Bis-mAO-SiO 2 possess excellent antioxidant properties. The prepared PPS/Bis-mAO-SiO 2 composites remained stable under high temperatures and oxygen environments. Impressively, the maximum weight loss rate temperature of PPS/Bis-mAO-SiO 2 was increased by 11.60 degrees C compared to that of PPS, and after accelerated thermal oxidation at 220 degrees C for 24 h, the relative intensity ratio between O and C of PPS/Bis-mAO-SiO 2 only increased to 0.086, much lower than 0.132 for PPS. Moreover, the viscosity of PPS/Bis-mAO-SiO 2 only increased by 29.05 % and 88.75 % after accelerated thermal oxidation at 220 degrees C for 12, 24 h. Compared, PPS ' s viscosity increased substantially by 79.22 % and 250.3 %, respectively. This meant that the Bis-mAO-SiO 2 successfully achieved a synergistic integration of high antioxidant properties and thermal stability, implying that the work offered a strategy for fabricating hightemperature resistant antioxidant composites.
Keyword :
Hindered phenolic Hindered phenolic Polyphenylene sulfide Polyphenylene sulfide Rheological properties Rheological properties Silicon dioxide Silicon dioxide Thermal oxidation stability Thermal oxidation stability
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| GB/T 7714 | Cai, Weilong , You, Jian , Wang, Wei et al. Double-hindered phenolic SiO 2 composites with excellent oxidation resistance and thermal stability for enhanced thermal oxidation stability of PPS [J]. | CHEMICAL ENGINEERING JOURNAL , 2024 , 487 . |
| MLA | Cai, Weilong et al. "Double-hindered phenolic SiO 2 composites with excellent oxidation resistance and thermal stability for enhanced thermal oxidation stability of PPS" . | CHEMICAL ENGINEERING JOURNAL 487 (2024) . |
| APA | Cai, Weilong , You, Jian , Wang, Wei , Chen, Huaiyin , Liu, Longmin , Ma, Yuhan et al. Double-hindered phenolic SiO 2 composites with excellent oxidation resistance and thermal stability for enhanced thermal oxidation stability of PPS . | CHEMICAL ENGINEERING JOURNAL , 2024 , 487 . |
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