1. Le graph\u00e8ne<\/h2>\n
Development Trend:<\/strong> The 2010 Nobel Prize in Physics has made graphene hot in technology and capital markets in recent years. It will be used in optoelectronic displays, semiconductors, touch screens, electronic devices, energy storage batteries, displays, sensors, aerospace, military, and composite materials, biomedicine, and other fields will grow explosively.<\/p>\n Main Research Institutions (Companies):<\/strong> Graphene Technologies, Angstron Materials, Graphene Square, Forsman Technology, etc.<\/p>\n Development Trend:<\/strong> New materials with great potential have great potential in the fields of energy conservation and environmental protection, thermal insulation and electrical appliances, and construction.<\/p>\n Main Research Institutions (Companies):<\/strong> Forsman Technology, W.R. Grace, Japan Fuji-Silysia, etc.<\/p>\n Development Trend:<\/strong> Electrodes of functional devices, catalyst carriers, sensors, etc.<\/p>\n Main Research Institutions (Companies):<\/strong> Unidym, Inc., Toray Industries, Inc., Bayer Materials Science AG, Mitsubishi Rayon Co., Ltd., Forsman Technology, Suzhou First Element, etc.<\/p>\n Development Trend:<\/strong> The future has important prospects in the fields of life sciences, medicine, astrophysics, etc., and is expected to be used in optoelectronic devices such as optical converters, signal conversions, and data storage.<\/p>\n Main Research Institutions (Companies):<\/strong> Michigan State University, Xiamen Funa New Materials, etc.<\/p>\n Development Trend:<\/strong> High-frequency low-loss transformers, structural parts of mobile terminal equipment, etc.<\/p>\n Main Research Institutions (Companies):<\/strong> Liquidmetal Technologies, Inc., Chinese Academy of Sciences Metals Institute, BYD Co., Ltd., etc.<\/p>\n Development Trend:<\/strong> It has conductivity and can replace the application areas where inorganic non-metallic materials cannot conduct electricity; it has great potential in the field of sound insulation and noise reduction.<\/p>\n Main Research Institutions (Companies):<\/strong> Alcan, Rio Tinto, Symat, Norsk Hydro, etc.<\/p>\n Development Trend:<\/strong> It has broad application prospects in the field of the green chemical industry, as well as in the field of biology and catalysis.<\/p>\n Main Research Institutions (Companies):<\/strong> Solvent Innovation, BASF, Lanzhou Institute of Physics, Chinese Academy of Sciences, Tongji University, etc.<\/p>\n Development Trend:<\/strong> It has great prospects in biomedicine, enhancer, paper industry, purification, conductive and inorganic compound food, and industrial magnetic compound.<\/p>\n Main Research Institutions (Companies):<\/strong> Cellu Force (Canada), US Forest Service (US Forest Service), Innventia (Sweden), etc.<\/p>\n Breakthrough:<\/strong> Nano-dot perovskite has giant magnetoresistance, high ionic conductivity, and plays a catalytic role in the precipitation and reduction of oxygen.<\/p>\n Development Trend:<\/strong> The future has huge potential in the fields of catalysis, storage, sensors, and light absorption.<\/p>\n Main Research Institutions (Companies):<\/strong> Epry, AlfaAesar, etc.<\/p>\n Development Trend:<\/strong> The revolutionary molding method has great prospects in the field of complex structure molding and rapid processing molding.<\/p>\n Main Research Institutions (Companies):<\/strong> Object, 3DSystems, Stratasys, Huashu Hi-Tech, etc.<\/p>\n Development Trend:<\/strong> The future of flexible display and foldable devices has great prospects.<\/p>\n Main Research Institutions (Companies):<\/strong> Corning, Germany SCHOTT, etc.<\/p>\n Development Trend:<\/strong> Changing traditional materials preparation and materials repair methods will have great prospects in the fields of molecular devices, surface engineering, and nanotechnology.<\/p>\n Main Research Institutions (Companies):<\/strong> Harvard University, etc.<\/p>\n Development Trend:<\/strong> The future substitutes for traditional plastics have great prospects.<\/p>\n Main Research Institutions (Companies):<\/strong> Natureworks, BASF, Kaneka, etc.<\/p>\n Development Trend:<\/strong> In the future, it has a wide potential for environmental applications such as lightweight, high strength, and corrosion resistance.<\/p>\n Main Research Institutions (Companies):<\/strong> Harbin Institute of Technology, etc.<\/p>\n Development Trend:<\/strong> Change the traditional concept of processing according to the nature of materials. In the future, the characteristics of materials can be designed according to needs.<\/p>\n Main Research Institutions (Companies):<\/strong> Boeing, Kymeta, Shenzhen Guangqi Research Institute, etc.<\/p>\n Development Trend:<\/strong> If breakthroughs in high-temperature superconducting technology are expected in the future, it is expected to solve problems such as power transmission losses, heating of electronic devices, and new green transmission magnetic suspension technologies.<\/p>\n Main Research Institutions (Companies):<\/strong> Sumitomo Japan, Bruker Germany, Chinese Academy of Sciences, etc.<\/p>\n Development Trend:<\/strong> It has huge potential in the fields of space technology, medical equipment, mechatronics, and other fields.<\/p>\n Main Research Institutions (Companies):<\/strong> Research and development of new materials, etc.<\/p>\n Development Trend:<\/strong> It is widely used in intelligent structural devices, shock absorption devices, energy conversion structures, high-precision motors, and other fields, and its performance is better than that of piezoelectric ceramics under some conditions.<\/p>\n Main Research Institutions (Companies):<\/strong> ETMRA Corporation of the United States, Rare Earth Products Corporation of Britain, Sumitomo Light Metal Corporation of Japan, etc.<\/p>\n Development Trend:<\/strong> It is applied to the fields of the magnetic seal, magnetic refrigeration, magnetic heat pump, etc., and changes the traditional sealed refrigeration and other methods.<\/p>\n Main Research Institutions (Companies):<\/strong> American ATA Applied Technology Corporation, Japan Panasonic, etc.<\/p>\n Development Trend:<\/strong> The expansion-contraction cycle of intelligent polymer gel can be used for chemical valves, adsorption separation, sensors, and memory materials; the power provided by the cycle is used to design “chemical engines”; the controllability of the mesh is suitable for intelligent drug release systems Wait.<\/p>\n Main Research Institutions (Companies):<\/strong> American and Japanese universities.<\/p>\n The rapid evolution of advanced materials is not only reshaping industries like electronics, aerospace, and medicine but also revolutionizing the mining sector. From high-strength, corrosion-resistant titanium carbon composites<\/strong> for deep-earth drilling to self-assembling materials<\/strong> that could reinforce mine structures or even repair infrastructure autonomously, these innovations offer mining companies unprecedented efficiency and sustainability.<\/p>\n Prendre graph\u00e8ne<\/strong>\u2014its ultra-light yet ultra-strong properties could lead to more durable and lightweight \u00e9quipement minier<\/a>, reducing energy consumption in excavation and transport. Nanocrystalline cellulose\u2019s<\/strong> exceptional filtration capabilities could transform water treatment in traitement des minerais<\/a>, helping mines meet stringent environmental regulations. Superconducting materials<\/strong>, if commercialized for power transmission, could drastically cut energy waste in large-scale mining operations.<\/p>\n Even biodegradable plastics<\/strong> hold potential in reducing plastic waste from mining polymers, while aerogels<\/strong> could improve thermal insulation for equipment in extreme environments. Meanwhile, smart gels and shape-memory alloys<\/strong> might enable adaptive support systems for underground mines, enhancing safety.<\/p>\n![\"graph\u00e8ne\"](\"https:\/\/www.jxscmachine.com\/wp-content\/uploads\/2020\/02\/graphene.jpg\")
\nBreakthrough:<\/strong> Extraordinary electrical conductivity, extremely low electrical resistivity, and fast electron migration speed, tens of times stronger than steel, and excellent light transmission.<\/p>\n2. A\u00e9rogel<\/h2>\n
![\"a\u00e9rogel\"](\"https:\/\/www.jxscmachine.com\/wp-content\/uploads\/2020\/02\/aerogel.jpg\")
\nBreakthrough:<\/strong> High porosity, low density, light weight, low thermal conductivity, excellent thermal insulation properties.<\/p>\n3. Carbon Nanotubes (CNTs)<\/h2>\n
![\"CNT](\"https:\/\/www.jxscmachine.com\/wp-content\/uploads\/2020\/02\/CNTcarbon-nano-tube.jpg\")
\nBreakthrough:<\/strong> High electrical conductivity, high thermal conductivity, high elastic modulus, high tensile strength, etc.<\/p>\n4. Fuller\u00e8ne<\/h2>\n
![\"fuller\u00e8ne\"](\"https:\/\/www.jxscmachine.com\/wp-content\/uploads\/2020\/02\/fullerene.jpg\")
\nBreakthrough:<\/strong> With linear and nonlinear optical properties, alkali metal fullerene superconductivity, etc.<\/p>\n5. Alliage amorphe<\/h2>\n
![\"alliage](\"https:\/\/www.jxscmachine.com\/wp-content\/uploads\/2020\/02\/amorphous-alloy.jpg\")
\nBreakthrough:<\/strong> High strength and toughness, excellent magnetic permeability and low magnetic loss, excellent liquid flow.<\/p>\n6. Foam Metal<\/h2>\n
![\"mousse](\"https:\/\/www.jxscmachine.com\/wp-content\/uploads\/2020\/02\/foam-metal.jpg\")
\nBreakthrough:<\/strong> Lightweight, low-density, high porosity, and large specific surface area.<\/p>\n7. Ionic Liquid<\/h2>\n
![\"liquide](\"https:\/\/www.jxscmachine.com\/wp-content\/uploads\/2020\/02\/ionic-liquid.jpg\")
\nBreakthrough:<\/strong> With high thermal stability, a wide liquid temperature range, adjustable acid and alkali, polarity, coordination ability, etc.<\/p>\n8. Nano-crystalline Cellulose<\/h2>\n
![\"cellulose](\"https:\/\/www.jxscmachine.com\/wp-content\/uploads\/2020\/02\/nano-crystalline-cellulose.jpg\")
\nBreakthrough:<\/strong> With good biocompatibility, water-holding capacity, a wide range of pH stability, nano-network structure, and high mechanical properties.<\/p>\n9. Nanocrystalline Perovskite<\/h2>\n
![\"P\u00e9rovskite](\"https:\/\/www.jxscmachine.com\/wp-content\/uploads\/2020\/02\/Nanocrystalline-perovskite.jpg\")
<\/p>\n10. 3D Printed Materials<\/h2>\n
![\"Mat\u00e9riaux](\"https:\/\/www.jxscmachine.com\/wp-content\/uploads\/2020\/02\/3D-printed-materials.jpg\")
\nBreakthrough:<\/strong> Changing traditional industrial processing methods can quickly achieve the formation of complex structures.<\/p>\n11. Verre de saule<\/h2>\n
![\"Verre](\"https:\/\/www.jxscmachine.com\/wp-content\/uploads\/2020\/02\/Willow-Glass.jpg\")
\nBreakthrough:<\/strong> Change the rigid and fragile characteristics of traditional glass and realize the revolutionary innovation of glass flexibility.<\/p>\n12. Self-assembling (Self-repairing) Material<\/h2>\n
![\"Mat\u00e9riau](\"https:\/\/www.jxscmachine.com\/wp-content\/uploads\/2020\/02\/Self-assembling-self-repairing-material.jpg\")
\nBreakthrough:<\/strong> Material molecules self-assemble to realize the “intelligence” of the material itself, change the previous method of material preparation, and enable the material to form a certain shape and structure spontaneously.<\/p>\n13. Biodegradable Plastics<\/h2>\n
![\"Plastiques](\"https:\/\/www.jxscmachine.com\/wp-content\/uploads\/2020\/02\/Biodegradable-plastics.jpg\")
\nBreakthrough:<\/strong> Naturally degradable, raw materials come from renewable resources, changing traditional plastics’ dependence on fossil resources such as oil, natural gas, coal, and reducing environmental pollution.<\/p>\n14. Titanium Carbon Composites<\/h2>\n
![\"Composites](\"https:\/\/www.jxscmachine.com\/wp-content\/uploads\/2020\/02\/Titanium-carbon-composites.jpg\")
\nBreakthrough:<\/strong> With high strength, low density, and excellent corrosion resistance, it has unlimited prospects in the aviation and civil fields.<\/p>\n15. M\u00e9tamat\u00e9riaux<\/h2>\n
![\"m\u00e9tamat\u00e9riau\"](\"https:\/\/www.jxscmachine.com\/wp-content\/uploads\/2020\/02\/metamaterial.jpg\")
\nBreakthrough:<\/strong> It has physical characteristics that conventional materials do not have, such as negative permeability and negative permittivity.<\/p>\n16. Superconducting Materials<\/h2>\n
![\"mat\u00e9riaux](\"https:\/\/www.jxscmachine.com\/wp-content\/uploads\/2020\/02\/superconducting-materials.jpg\")
\nBreakthrough:<\/strong> In the superconducting state, the material has zero resistance, no current loss, and the material exhibits anti-magnetic properties in a magnetic field.<\/p>\n17. Shape Memory Alloy<\/h2>\n
![\"alliage](\"https:\/\/www.jxscmachine.com\/wp-content\/uploads\/2020\/02\/shape-memory-alloy.jpg\")
\nBreakthrough:<\/strong> After pre-forming, after being forced to deform by external conditions, it will be restored to its original shape under certain conditions, to realize the design and application of material reversibility.<\/p>\n18. Magnetostriction Materials<\/h2>\n
![\"mat\u00e9riaux](\"https:\/\/www.jxscmachine.com\/wp-content\/uploads\/2020\/02\/magnetostriction-materials.jpg\")
\nBreakthrough:<\/strong> Under the action of the magnetic field, it can produce elongation or compression performance, and realize the interaction between material deformation and the magnetic field.<\/p>\n19. Magnetic (Electrical) Fluid Material<\/h2>\n
![\"Mat\u00e9riau](\"https:\/\/www.jxscmachine.com\/wp-content\/uploads\/2020\/02\/Magnetic-electrical-fluid-material.jpg\")
\nBreakthrough:<\/strong> Liquid state, with the magnetic properties of solid magnetic materials, and the fluidity of liquids. It has characteristics and applications that traditional magnetic bulk materials do not have.<\/p>\n20. Intelligent Polymer Gel<\/h2>\n
![\"Gel](\"https:\/\/www.jxscmachine.com\/wp-content\/uploads\/2020\/02\/Intelligent-polymer-gel.jpg\")
\nBreakthrough:<\/strong> Can sense and respond to changes in the surrounding environment, and has similar biological response characteristics.<\/p>\nConclusion: The Transformative Role of New Materials in the Future of Mining<\/h2>\n