1、Advanced chemical modification technology of inorganic oxide

In this comprehensive review, we explored advanced chemical modification techniques tailored for IONs incorporated into EP, providing a detailed examination of the mechanical characteristics of surface cm-ION/EP nanocomposites.

2、Preparation of Inorganic Filler Modified Epoxy Resin

Epoxy resin adhesive toughened and modified with two kinds of inorganic fillers, nano-titania and micro-alumina, were prepared and study the compatibility of modified epoxy resin adhesive with UDMH.

3、昆明理工大学材料学科2016

Ma, Ce modified Cu/Zn/Al catalysts for direct liquefaction of microcrystalline cellulose in supercritical methanol, Cellulose, 26 (2019) 8291-8300. [1109] G. Liu, J. Tao, F. Li, R. Bao, Y. Liu, C. Li, J. Yi, Optimizing the interface bonding in Cu matrix composites by using functionalized carbon nanotubes and cold rolling, J Mater Res ...

4、改性树脂_化工百科

改性树脂是一种经过化学改性处理的树脂材料，具有特定的性质和用途。 下面是关于改性树脂的性质、用途、制法和一些安全信息的介绍： - 改性树脂具有较优异的物理性质和化学稳定性，可以满足特定的需求。 - 常见的改性树脂可以提供良好的耐久性、抗化学腐蚀性能、耐高温性以及力学性能的改进。 - 改性树脂还可以通过调整其溶解度、粘度、硬度和弹性等性质来满足不同的应用要求。 - 改性树脂广泛应用于涂料、胶黏剂、塑料、纤维等领域。 - 涂料中的改性树脂可以提供优异的附着性、耐候性、抗刮擦性和耐化学腐蚀性。 - 在胶黏剂中，改性树脂可提供高粘接强度、耐化学腐蚀性和优异的耐热性能。 - 在塑料领域，改性树脂可以改善塑料的机械性能、热稳定性和可加工 …

5、代表性论文

Chemically inorganic modified ammonium polyphosphate as eco-friendly flame retardant and its high fire safety for epoxy resin. Composites Communications, 2021, 100959.

A novel organic

The organic-inorganic composite filler was added to epoxy resin to prepare a composite coating with long-lasting anti-corrosion and wear-resistance properties.

Facile Synthesize of an Inorganic–Organic Hybrid for a

In the present study, MH has been organically modified to investigate the potential of a novel organic–inorganic hybrid as a flame-retardant curing agent (CEPPM-MH) for flame retardancy of epoxy resins.

Organic

The utilization of organic-inorganic hybrid modified epoxy resin at the molecular level can enhance its anti-corrosion performance while imparting additional characteristics.

Investigation of sol

In this study, a commercial epoxy resin (KER 828) was employed as the organic component of the organic inorganic hybrid coating to enhance corrosion resistance while reducing production costs...

Preparation of organic

Preparation of organic-inorganic hybrid nanocomposites from chemically modified epoxy and novolac resins and silica-attached carbon nanotubes by sol-gel process: Investigation of thermal degradation and stability

In today's industrial landscape, the rapid advancement of materials science has made the development and application of new materials a key driver of technological progress. Among these, Mister Inorganic Modified Resin (MIMR) has emerged as a high-performance material garnering significant attention due to its exceptional properties and broad application prospects. This article explores MIMR’s definition, characteristics, applications, and future trends.

I. Definition of Mister Inorganic Modified Resin

Mister Inorganic Modified Resin is a novel composite material consisting of an inorganic filler-reinforced phase and an organic polymer matrix. By combining inorganic fillers such as glass fibers, carbon fibers, or others with organic polymers, MIMR leverages the high strength, hardness, and chemical stability of inorganic fillers, along with the superior processability and mechanical properties of organic polymers, to create a composite with excellent comprehensive performance.

II. Characteristics of Mister Inorganic Modified Resin

1. High Strength: MIMR exhibits outstanding compressive and flexural strength, meeting structural component requirements.
2. Excellent Wear Resistance: The inclusion of inorganic fillers endows MIMR with enhanced durability in abrasive applications.
3. Corrosion Resistance: MIMR resists chemical erosion, ensuring robust performance in corrosive environments.
4. Thermal Stability: It maintains performance integrity under high temperatures.
5. Strong Customizability: By adjusting the type and ratio of inorganic fillers, MIMR can be tailored to specific performance needs.

III. Applications of Mister Inorganic Modified Resin

1. Aerospace: Used in aircraft fuselages, engine components, and other critical parts, MIMR’s high strength and heat resistance ensure flight safety.
2. Automotive Industry: Applied in vehicle bodies, chassis, and suspension systems, it enhances load capacity and longevity.
3. Construction: Employed in bridges, building structures, and pipelines, MIMR’s corrosion resistance and durability extend infrastructure lifespan.
4. Electronics: Serves as protective layers for circuit boards and encapsulation material for electronic components, ensuring stability and reliability.

IV. Future Development Trends

Advancements in technology will further propel MIMR’s research and applications. Key trends include:

1. Material Optimization: Leveraging nanotechnology and molecular design to enhance mechanical, thermal, and corrosion-resistant properties.
2. Green Manufacturing: Developing eco-friendly processes to reduce pollution and energy consumption.
3. Multifunctionalization: Integrating self-healing, electromagnetic, or photonic functionalities to expand application scope.
4. Smart Integration: Combining MIMR with intelligent materials to enable adaptive or responsive capabilities.

As a cutting-edge material, Mister Inorganic Modified Resin holds immense potential in aerospace, automotive, construction, and electronics. With ongoing technological progress, MIMR is poised to play a pivotal role in advancing society and economic development, driving innovation across industries.