Superconductivity: From Phenomenon to Practical Applications

June 11, 2024 360 0

Superconductivity is a remarkable phenomenon where certain materials can conduct electricity without any resistance and expel magnetic fields when cooled below a critical temperature. Discovered over a century ago, this property has led to significant technological advancements. Despite our understanding of some aspects of superconductivity, the discovery of new high-temperature superconductors continues to challenge and expand our knowledge.

An Overview of Superconductor

Understanding Electrical Resistance and Superconductors

  • Electrical Resistance: At normal temperatures, all materials resist the flow of electricity, like a narrow pipe resists water flow. 
    • This resistance causes energy loss as heat in devices like computers and cell phones. 
    • Most materials keep this resistance even at very low temperatures. 
  •  Superconductors: However, superconductors are special materials that, when cooled below a critical temperature (Tc), can conduct electricity without any energy loss
    • They also expel magnetic fields in this state.

Discovery and Explanation

  • Superconductivity was discovered over 100 years ago in mercury cooled to liquid helium temperatures (-452°F). 
  • In 1957, three physicists used quantum mechanics to explain that below Tc, electrons form pairs held together by vibrations called phonons
  • These pairs move through the material without resistance
Key Superconductivity Facts

  • 1911: Superconductivity was discovered by Heike Kamerlingh-Onnes, who won the 1913 Nobel Prize in Physics.
  • Nobel Prizes: Five Nobel Prizes were awarded for superconductivity research (1913, 1972, 1973, 1987, 2003).
  • Low-Temperature Superconductors: About half the elements can become superconductors at low temperatures, but alloys like niobium-titanium are often used for practical applications, such as in MRI machines.

 

Key Aspects of Superconductivity Technology

  • Superconductivity is a phenomenon observed in certain materials where they can conduct electricity with zero electrical resistance and expel magnetic fields. Here are key aspects of superconductivity technology:
  • Zero Electrical Resistance: The most distinguishing feature of superconductors is their ability to conduct electricity without any resistance. 
  • This means that once a current is established in a superconducting loop, it can persist indefinitely without any loss of energy.
  • Critical Temperature (Tc): Superconductivity is typically observed below a critical temperature unique to each material. 
  • Above this critical temperature, the material behaves like a normal conductor, but below it, the superconducting state emerges.

Types of Superconductors

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  • Type I Superconductors: Exhibit a sharp transition to the superconducting state at a specific critical temperature. 
    • Examples: include lead and mercury.
  • Type II Superconductors: Have a more gradual transition and can exist in a mixed state where some parts are superconducting and others are not. 
    • Examples: include niobium-titanium and yttrium-barium-copper oxide.

Applications

  • Magnetic Levitation: Superconductors expel magnetic fields, leading to applications like magnetic levitation (Maglev) trains
    • The lack of resistance allows Maglev trains to travel at high speeds with minimal energy loss.
  • MRI (Magnetic Resonance Imaging): Superconducting magnets are used in medical imaging devices like MRI machines, providing strong and stable magnetic fields for detailed imaging.
  • Electric Power Transmission: Superconductors can be used in power cables to transmit electricity with minimal loss, increasing the efficiency of power distribution.
  • Quantum Computing: Superconducting materials are being explored for use in quantum computers, where the qubits can be implemented as superconducting circuits.

High-Temperature Superconductors (HTS)

  • Early superconductors required extremely low temperatures (near absolute zero), but HTS materials can exhibit superconductivity at higher temperatures, although still below room temperature.
  • In 1986, scientists found copper-oxide materials that became superconductors at much higher temperatures than previous materials, some above liquid nitrogen temperatures (-321°F). 
  • This discovery hinted at new technological possibilities and suggested that even higher-temperature superconductors might be found.
  • Yttrium-barium-copper oxide (YBCO) is an example of a high-temperature superconductor.

Challenges and Limitations

  • Cooling Requirements: Many superconductors require extremely low temperatures to maintain their superconducting state, which can be a technological challenge.
  • Material Cost: Some superconducting materials, especially high-temperature superconductors, can be expensive.
  • Current Limitations: Practical applications are often limited by the current-carrying capacity and stability of superconductors.

Ongoing Research and Development

  • Ongoing research aims to discover new superconducting materials with higher critical temperatures and better properties for various applications.
  • Since then, many new high-temperature superconductors have been discovered through experiments and educated guesses, including iron-based materials
  • However, the existing theory for metal superconductors doesn’t explain these new materials, presenting a fresh challenge to scientists.
  • Scientists are exploring ways to overcome existing challenges and make superconductivity more practical for widespread use.
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Conclusion

  • Superconductivity holds immense potential for various applications, from powerful magnets in MRI machines to efficient power transmission and quantum computing
  • While challenges such as cooling requirements and material costs persist, ongoing research aims to find new materials with higher critical temperatures and improved properties. 
  • The future of superconductivity promises revolutionary advancements in technology and science.
Related Articles 
Superconductivity Electricity: Basics of Electrical Components
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