High-tech materials discusses carbon fiber, graphene, and magnesium alloys. Carbon fiber is strong, light, and resistant to heat and chemicals. It is made from polymers through carbonization and is used in vehicles, aircraft, and sports equipment to reduce weight. Graphene is the thinnest known material, with unprecedented strength and conductivity. It is being researched for applications in electronics, filtration, and composites. Magnesium alloys have high strength to weight ratios and are used in cameras, cars, sports gear, and aircraft to lower component weights. The document concludes that advanced materials have driven major technological advances and can be recycled to reduce resource usage.

1. High-tech materials
Matyáš Pospíšil, Adéla Novotná

2. GENERAL OVERVIEW
• Imagine a material that shifts and moves according to the
temperature of the outside air - like a flower opening up for sunlight
and closing its petals at night. New high-tech smart materials have
allowed this idea to thrive and the possibilities are endless.

3. CARBON FIBER

4. GENERAL INFORMATION
• a carbon fiber is a long, thin strand of material about 0.005-0.010 mm in
diameter (composed by carbon atoms)
• high tensile strength, high chemical resistance, high stiffness, low thermal
expansion, and low weight properties
• carbon Fibre is very rigid, reinforced plastic is over 4 times stiffer than Glass,
corrosion resistant and chemicaly stable, Carbon fiber is Electrically conductive

5. FABRICATION
• 90% of the carbon fibers produced are made from polyacrylonitrile (PAN)
• 10% are made from rayon or petroleum pitch
• variety of gases and liquids are used (some designed to react and achieve a
special effect or prevent certain reactions)
• Carbon fibres are made in 5 cycles
• Spinning (Acrylonitrile plastic powder is mixed with another plastic)
• Stabilizing (heating the fibers in air)
• Carbonizing (for several minutes in a furnace filled with a gas mixture without
oxygen)
• Treating the surface (surface is slightly oxidized)
• Sizing (coated to be protected from damage)

6. UTILIZATION
• Automobile industry (i.e car maker Pagani started making thier new Zonda F
and by using carbon and magnesium fiber they reduced the weight by 40%
to 1000 kilograms)
• Aircraft industry: (i.e aircraft maker Boeing is using carbon fiber for their
new type of machine called „the dreamliner“ and they claim that is the
lightest aircraft for public ever made)
• Aerospace industry (They are spending financial resources on research and
development of carbon fiber. They are trying to improve the quality of these
carbon fiber)
• Tour de france ( Carbon fiber for its specific abilities has forever changed the
way profesionals ride their vehicle)

8. GRAPHENE

9. GENERAL INFORMATION
• a thin layer of pure carbon
• a single, tightly packed layer of carbon atoms that are bonded
together in a hexagonal lattice
• the slimmest compound known (one atom thick)
• the lightest material
• the strongest compound discovered (100-300 stronger then steel)
• the best conductor of heat
• the best conductor of electricity
• unique level of light absorbtion
• The Nobel Prize in Physics for 2010 was awarded for experiments
regarding graphene

10. FABRICATION
• many techniques
1. Mechanical exfoliation (exfoliating graphite with sticky tape and
depositing it on a substrate)
2. Chemical vapor deposition on copper (a substrate is exposed to
several precursor gases containing reactive elements)
3. Substrate layout (the most common nanofabrication techniques used
to fabricate graphene)

11. UTILIZATION
• Biological engineering: bioelectric sensory devices with the ability to monitor
glucose levels, haemoglobin levels, cholesterol and even DNA sequencing
• Optical electronics: phone makers (Samsung, LG) are working on flexible
displays made of graphene. Soon we will see graphene in touchscreens, OLEDs
and LCDs.
• Ultrafiltration: gaphene can be use as a ultrafiltration medium to act as a
barrier between two substances (water filtration systems)
• Composite materials: graphene can replace steel in the structure of aircraf,
coat aircraft surface and measure strain rate
• Bill Gates funds scientific research to develop the thinnest and strongest
condoms ever

13. MAGNESIUM ALLOY

14. GENERAL INFORMATION
• the strenght to weight ratio is better than other alloys
• despite the active nature of the metal, magnesium and its alloys
have good resistance to corrosion
• merits are similar to alluminium such as: low specific gravity with
satisfactory strenght
• Magnesium casting proof stress is typically 75-200 MPa, tensile
strength 135-285 MPa and elongation 2-10%. Typical density is
1.8 g/cm3

15. FABRICATION
• Hot and cold working (Magnesium alloys harden rapidly with any type
of cold work)
• The percipationally hardened alloys are used in casting
• Then welding, soldering, and riveting are taking part
• A particular attraction of magnesium alloys lies in their extraordinarily
good machining properties, so machining is taking part.
• Not much pure magnesium is extruded, for it has somewhat poor
properties, especially as regards its proof stress, so we heat it up….

16. UTILIZATION
• Magnesium is used for camera lightings
• it is also used in car industry for its strenght and lightnes
• we can find it very often in sport equipment
• In aircraft industry it plays a crucial role
• the most interesting usedge of alluminium is how alloys are
used for replacing human body parts

18. ENVIROMENTAL IMPACT
• We think, that the inviromental impact done by advanced materials is
very positive. Thanks to the advanced technology production we no
longer have to mine so many mineral resources and it also opens a
brand new way to their recyclation.

19. RESUMÉ
• From the research that we have done, we conclude that the discovery
of advanced materials went hand in hand with the biggest milestones
of modern history.

20. SOURCES
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