Track the most promising cutting-edge new materials

Synchronized cognition and top scientists

Don’t miss potential opportunities

Changing urban catering and kitchenware technology

Impact on sports and fitness experience

Investment institutions look for investment directions

Decision-making assistance for public officials

Education practitioners help teach

Science enthusiasts learn about cutting-edge breakthroughs

On the eve of change, opportunities appear explosively

The best time to learn cutting-edge materials science

Materials have been used in televisions and other fields

Make full use of and expand application fields

Invite experts to share the latest information

Introducing the latest research results of academicians

Seize new opportunities in an era of fierce competition

The light of the future hidden in materials science

High technical content

Large impact

Long product iteration cycle

The world's top scientists pay attention

People around the world are eager to explore new opportunities

The scale of matter is compressed to the nanometer level

Quantum effects have special phenomena in the microscopic world

Example: Li-ion battery & graphene & blue LED

4 cutting-edge materials won awards

Need to make outstanding contributions in application

Lithium-ion battery and blue LED

Nanoparticle materials with quantum effects

Radiate light of different wavelengths

Material properties can be controlled by size

Milestones precisely controlled at microscopic scale

Huge application potential

The Nobel Prize is an important indicator

Inspiring research and application exploration by scientists around the world

The speed of industrial development exceeds the speed of innovation

Technical optimization key tasks

Packaging materials affect optimization results

Limited applications in the textile industry

R&D achievements of the scientific research team

Materials related to chip technology breakthroughs

Commercialization opportunities subject to cost

Technology responds to nuclear wastewater discharge

Protein membrane is highly efficient and low cost

The protective layer changes when exposed to light

Have high precision requirements

Problems with traditional photoresist

Processing smaller chips

Higher accuracy

prone to deformation

Accuracy is difficult to guarantee

Introducing hybridization of inorganic and organic matter

Improve accuracy and stability

High mechanical strength

Will not deform

Does not destroy hybrid material properties

Materials are tightly bound

A huge breakthrough in photoresist

Drawing attention to technology competition

relatively simple

Plexiglass materials are easily available and stable

Market demand drives

Photoresist technology development accelerates

Prepared using polymer systems

Published in top journals

Coral reef degradation accelerates

Some sunscreen ingredients are toxic if they enter the water

Many countries ban certain sunscreens in specific sea areas

The ban is getting stricter

Animal experiments verify protective effect

Experiment and screen to find suitable monomer molecules

Toxicity test results are good

Industry has more choices

The product has commercial value

Mid- to high-end areas can maintain market competitiveness

Natural diamonds are rare and expensive

Man-made diamonds are larger in size and have more carats

Diamonds used in superhard cutting tools

Most man-made diamonds are for industrial use

Diamond is considered a wide bandgap semiconductor

Used in manufacturing electronic components and semiconductor devices

Creating large diamonds by separating graphite and diamond growth sites

Adding alloy catalysts to improve diamond purity

Prices of gem-quality diamonds fell, and the market changed significantly

There are more opportunities in industrial applications such as optical instruments

Mass production is already underway in the laboratory, but technical challenges remain

Quality stability and guarantee are key issues

Technology is still evolving and improving

Continuous improvement will lead to more amazing results

Fire extinguishing requires the use of other substances

Fire has always been difficult to control

Burns when powered on, extinguishes when powered off

The flame is more controllable

Flame retardants interrupt the combustion process

Adding salts can improve the flame retardancy of materials

The combustion process involves intermediates transferring electrons

The high temperature area of ​​the flame produces ions

Using ionic liquids as materials

Select imidazole cations and perchlorate anions for design

Using electricity to achieve combustion and smoke release

Stop powering and extinguish the flame

Solve safety issues such as spontaneous combustion of automobiles

Potential applications in space and deep sea scenarios

Add partners to achieve mass production

Although the cost is high, priority should be given to application needs

The temperature critical point is 80K

Belongs to a new type of high-temperature superconducting material

Breaking through previous copper-barium and iron-based superconducting material systems

Achieve superconductivity under conditions of more than 100,000 atmospheres

The first superconducting material discovered was mercury

Barium-copper system superconducting material appeared in 1986

Yttrium barium copper oxide superconductor was discovered in 1987

Iron-based superconducting materials were discovered in 2008

Barium-copper systems have been used in maglev trains and laboratory instruments

High-temperature superconducting materials have potential for more practical applications

The application of lanthanum nickel oxide 327 is limited by pressure conditions

Future technological advances may overcome application difficulties

Breakthroughs in high-temperature superconducting materials are based on traditional superconducting theory

The findings of Zhang Guangming and Wang Meng's team break conservative concepts

Breakthroughs are further discoveries that build on past research

High-temperature superconducting materials promote further development in the field of superconductivity

The mechanism of superconductivity is not yet fully understood

The application of high-temperature superconducting materials requires further research

High-temperature superconducting materials need to understand their principles

High-temperature superconducting materials continue to receive attention in the scientific community

High-temperature superconductivity research has long lacked major breakthroughs

The discovery by the team of Zhang Guangming and Wang Meng attracted global attention

Breakthroughs in high-temperature superconducting materials affect the development of the field of superconductivity

High-temperature superconductivity research could change perceptions of its prospects

The critical temperature of lanthanum nickel oxide 327 exceeds 77K

The superconducting material was successfully verified by international peers

Lanthanum nickel oxide 327 is a new type of high-temperature superconducting material

The findings of the team of Zhang Guangming and Wang Meng were recognized by the academic community

The industrialization of high-temperature superconducting materials faces challenges

High-temperature superconducting materials need to overcome difficulties in practical application

The research team’s results have potential impact on the industrialization of superconducting materials

High-temperature superconducting materials still require further research and development

3D printing is no longer cutting-edge technology

Research and develop cutting-edge materials to achieve fine printing

Additive manufacturing printing crafts

Macroscopic 3D printing has limited accuracy

Light curing method is used at the micro level

Achieve printing with micron-level precision

Limited accuracy due to optical diffraction phenomena

Wavelength selection is difficult, short wavelengths damage materials

Using two-photon absorption to improve accuracy

Using femtosecond pulse laser two-photon technology

Professor Sun Hongbo’s groundbreaking work

The mixing method has insufficient adhesion and uneven results.

Material properties are affected by mixing and performance is reduced

Nanocolloidal modified materials achieve two-photon absorption

Increase material surface and light curing capabilities

Improve accuracy without mixing materials

Technical difficulties need to be overcome

Problems with performance and cycle charge and discharge

Aluminum resources are abundant and easy to obtain

Theoretical power is close to lithium ion

Competitive performance

Actual efficiency is low

Cannot be recharged, only suitable for disposable batteries

Wang Lili’s team designs new electrode materials

The problem is that aluminum tetrachloride causes insufficient battery and the inability to recharge

Introducing MXene carrier to optimize electrode materials

Enhance the cycle life and power performance of aluminum-ion batteries

Research team conducts more optimization on new electrode materials

The industry has a relatively rapid industrialization of aluminum-ion batteries

Aluminum-ion battery development is relatively easy to standardize

Distinguish between aluminum-air batteries and aluminum-ion batteries

It is still necessary to continue to track improvements and breakthroughs in aluminum-ion batteries