Glossary

9.4 Josephson junctions

6 min readaugust 20, 2024

are crucial components in superconducting electronics and quantum computing. These devices consist of two superconductors separated by a thin insulating layer, allowing Cooper pairs to tunnel between them.

The junctions exhibit unique quantum phenomena like DC and AC Josephson effects, , and . These properties make them invaluable for applications in voltage standards, , and for quantum computing.

Josephson junctions

  • Josephson junctions are a fundamental building block in superconducting electronics and quantum computing
  • Consist of two superconductors separated by a thin insulating layer, allowing of Cooper pairs
  • Exhibit unique quantum phenomena such as the DC and AC Josephson effects, flux quantization, and Shapiro steps

Superconductor-insulator-superconductor structure

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  • Josephson junctions have a sandwich-like structure: two superconducting electrodes separated by a thin insulating barrier
  • The insulating layer is typically a few nanometers thick ( or )
  • The superconducting electrodes are often made of low-temperature superconductors such as aluminum, , or
  • The insulating barrier allows quantum tunneling of Cooper pairs between the superconductors

Tunneling of Cooper pairs

  • In superconductors, electrons form Cooper pairs due to electron-phonon interactions
  • Cooper pairs can tunnel through the insulating barrier in a Josephson junction without any applied voltage
  • The tunneling of Cooper pairs is a macroscopic quantum effect, demonstrating quantum behavior at the macroscopic scale
  • The tunneling current depends on the between the two superconducting electrodes

DC Josephson effect

  • The describes the flow of a supercurrent through the Josephson junction without any applied voltage
  • The supercurrent is given by: I=Icsin(δ)I = I_c \sin(\delta), where IcI_c is the and δ\delta is the phase difference between the superconductors
  • The critical current IcI_c depends on the properties of the junction (barrier thickness, area, and the superconducting gap)
  • The DC demonstrates the coherence and phase-locking of the superconducting wavefunctions across the junction

AC Josephson effect

  • When a DC voltage VV is applied across the Josephson junction, an AC supercurrent oscillates with a frequency f=(2e/h)Vf = (2e/h)V
  • This is known as the , and the frequency is proportional to the applied voltage
  • The AC Josephson effect provides a precise relationship between frequency and voltage, making it useful for voltage standards and high-frequency applications
  • The -voltage relation is given by: f=(483.6 GHz/mV)×Vf = (483.6 \text{ GHz/mV}) \times V

Josephson current vs voltage

  • The current-voltage (I-V) characteristic of a Josephson junction is highly nonlinear
  • For currents below the critical current IcI_c, the junction exhibits a supercurrent with zero voltage drop (DC Josephson effect)
  • When the current exceeds IcI_c, a voltage develops across the junction, and the junction enters the resistive state
  • In the resistive state, the junction exhibits the AC Josephson effect, with an oscillating supercurrent and a DC voltage

Shapiro steps

  • When an AC current is applied to a Josephson junction in addition to a DC bias, the I-V curve displays voltage steps known as Shapiro steps
  • Shapiro steps occur at voltages Vn=nhf/2eV_n = nhf/2e, where nn is an integer, hh is Planck's constant, ff is the frequency of the AC current, and ee is the electron charge
  • The height of the Shapiro steps is proportional to the amplitude of the applied AC current
  • Shapiro steps are used in voltage standards and for studying the dynamics of Josephson junctions

Josephson penetration depth

  • The λJ\lambda_J characterizes the length scale over which magnetic fields penetrate the Josephson junction
  • It is given by: λJ=/2eμ0Jcd\lambda_J = \sqrt{\hbar/2e\mu_0 J_c d}, where \hbar is the reduced Planck's constant, μ0\mu_0 is the vacuum permeability, JcJ_c is the critical current density, and dd is the effective magnetic thickness of the junction
  • The Josephson penetration depth determines the spatial variation of the phase difference and the current density along the junction
  • Junctions with dimensions smaller than λJ\lambda_J are considered "short" junctions, while those larger than λJ\lambda_J are "long" junctions

Flux quantization in Josephson junctions

  • In a superconducting loop containing a Josephson junction, the magnetic flux threading the loop is quantized in units of the Φ0=h/2e\Phi_0 = h/2e
  • The quantization of flux leads to periodic modulation of the critical current as a function of the applied magnetic field
  • This effect is used in superconducting quantum interference devices (SQUIDs) for sensitive magnetic field measurements
  • The flux quantization condition is given by: φdl=2πn(2π/Φ0)Φ\oint \nabla \varphi \cdot dl = 2\pi n - (2\pi/\Phi_0) \Phi, where φ\varphi is the phase of the superconducting wavefunction, nn is an integer, and Φ\Phi is the enclosed magnetic flux

SQUID: Superconducting quantum interference device

  • A SQUID consists of a superconducting loop interrupted by one (RF SQUID) or two (DC SQUID) Josephson junctions
  • SQUIDs are highly sensitive magnetometers that can measure extremely small magnetic fields (down to 101510^{-15} T)
  • The critical current of a SQUID is modulated by the applied magnetic flux due to interference effects
  • DC SQUIDs are operated with a constant bias current, and the voltage across the SQUID is measured as a function of the applied magnetic flux
  • RF SQUIDs are operated with an AC bias current, and the changes in the resonant frequency are detected

RCSJ model of Josephson junctions

  • The resistively and capacitively shunted junction (RCSJ) model describes the dynamics of a Josephson junction
  • In the RCSJ model, the Josephson junction is represented by an ideal junction (governed by the ) in parallel with a resistor and a capacitor
  • The resistor represents the quasiparticle tunneling and dissipation in the junction, while the capacitor represents the junction's geometric capacitance
  • The RCSJ model leads to the following equation of motion for the phase difference: C(δ¨)+/R(δ˙)+Icsin(δ)=I\hbar C (\ddot{\delta}) + \hbar/R (\dot{\delta}) + I_c \sin(\delta) = I, where CC is the capacitance, RR is the resistance, and II is the bias current
  • The RCSJ model is used to study the dynamics and switching behavior of Josephson junctions

Josephson junction applications

  • Josephson junctions have numerous applications in superconducting electronics, metrology, and quantum computing
  • Voltage standards: The AC Josephson effect provides a precise relationship between frequency and voltage, enabling the realization of high-precision voltage standards
  • SQUIDs: Superconducting quantum interference devices are used for ultra-sensitive magnetic field measurements in various fields (geophysics, biomagnetism, and materials characterization)
  • Superconducting qubits: Josephson junctions are the key building blocks for superconducting qubits, such as flux qubits, charge qubits, and transmon qubits
  • Superconducting digital electronics: Josephson junctions can be used to create high-speed, low-power digital circuits, such as rapid single flux quantum (RSFQ) logic

Superconducting qubits for quantum computing

  • Superconducting qubits are a leading platform for quantum computing, relying on Josephson junctions as the nonlinear circuit element
  • Flux qubits: Consist of a superconducting loop interrupted by one or more Josephson junctions, with the qubit states defined by the direction of the circulating current
  • Charge qubits: Consist of a superconducting island connected to a reservoir through a Josephson junction, with the qubit states defined by the number of excess Cooper pairs on the island
  • Transmon qubits: A variant of charge qubits with reduced sensitivity to charge noise, achieved by operating in the regime where the Josephson energy dominates the charging energy
  • Phase qubits: Exploit the different energy levels in a current-biased Josephson junction, with the qubit states defined by the phase difference across the junction
  • Josephson junctions enable the strong nonlinearity required for qubit operations and the tunability of the qubit parameters

Key Terms to Review (27)

Ac and dc Josephson effects: The ac and dc Josephson effects refer to the phenomena observed in Josephson junctions, where a supercurrent flows between two superconductors separated by a thin insulating barrier. The dc Josephson effect involves a constant supercurrent that can flow without any applied voltage, while the ac Josephson effect occurs when an oscillating supercurrent is generated in response to an applied voltage, leading to alternating current. Both effects are fundamental for understanding the behavior of superconductors and have significant implications for quantum computing and sensitive magnetometry.
Ac josephson effect: The ac Josephson effect describes the phenomenon where a supercurrent flows between two superconductors separated by a thin insulating barrier, producing an alternating current (ac) when an external voltage is applied. This effect is crucial for understanding the behavior of Josephson junctions, which are key components in various superconducting devices and applications, including quantum computing and sensitive magnetic field measurements.
Aluminum oxide: Aluminum oxide, commonly known as alumina, is a chemical compound composed of aluminum and oxygen, with the formula Al₂O₃. It is an important material in various fields, including electronics and solid-state physics, due to its excellent electrical insulation properties and ability to form a thin layer on metals, enhancing corrosion resistance.
Brian D. Josephson: Brian D. Josephson is a Welsh physicist who is best known for his discovery of the Josephson effect, which involves the tunneling of superconducting pairs through a thin insulating barrier between two superconductors. This phenomenon is foundational to the understanding of Josephson junctions, which are crucial in various applications, including quantum computing and sensitive magnetometers. His work has profoundly influenced both theoretical and applied physics in the field of superconductivity.
Critical Current: Critical current is the maximum electric current that a superconductor can carry without losing its superconducting properties. Exceeding this current causes the material to transition back to a resistive state, losing its ability to conduct electricity without resistance. The critical current is crucial in applications involving superconductors, such as in Josephson junctions, where it influences the performance and stability of these devices.
Dc Josephson effect: The dc Josephson effect is a phenomenon that occurs in a Josephson junction, where a supercurrent flows between two superconductors separated by a thin insulating barrier, without any voltage applied. This effect leads to a direct relationship between the supercurrent and the phase difference of the superconducting wave functions on either side of the junction. It's essential for understanding quantum tunneling and plays a vital role in various applications like superconducting qubits and sensitive magnetometers.
Flux quantization: Flux quantization is the phenomenon where the magnetic flux passing through a superconducting loop is quantized in discrete units, specifically integer multiples of the flux quantum, which is given by $$\Phi_0 = \frac{h}{2e}$$. This means that the magnetic flux can only take on specific values, leading to interesting implications in superconductivity and the behavior of Josephson junctions, where this quantization plays a crucial role in determining their properties and functionality.
Flux quantum: The flux quantum is a fundamental constant representing the smallest possible magnetic flux that can exist in a superconductor, denoted by the symbol $$\Phi_0$$ and equal to $$\frac{h}{2e}$$, where $$h$$ is Planck's constant and $$e$$ is the elementary charge. This value is crucial for understanding the behavior of superconductors and their interactions in phenomena like the Josephson junctions, where quantum tunneling of Cooper pairs occurs across a thin insulating barrier.
John Robert Schrieffer: John Robert Schrieffer was an American physicist renowned for his significant contributions to the field of superconductivity, particularly for co-developing the BCS theory with John Bardeen and Leon Cooper. His work has laid the foundation for understanding how certain materials can exhibit zero electrical resistance when cooled below a critical temperature, a phenomenon essential to various applications in electronics and quantum computing.
Josephson Effect: The Josephson Effect refers to the phenomenon where a supercurrent flows between two superconductors separated by a thin insulating barrier, without any voltage applied across it. This effect allows for the tunneling of Cooper pairs, which are pairs of electrons that contribute to superconductivity, across the barrier, leading to remarkable electrical properties and applications in quantum computing and sensitive measurement devices.
Josephson Equations: The Josephson equations describe the behavior of the supercurrent flowing through a Josephson junction, which is a thin insulating barrier between two superconductors. These equations capture the relationship between the supercurrent, the phase difference of the superconducting wave functions, and the voltage across the junction. Understanding these equations is crucial for analyzing how superconducting materials interact at the quantum level and for applications in quantum computing and sensitive magnetic field measurements.
Josephson frequency: Josephson frequency refers to the oscillation frequency of the supercurrent flowing through a Josephson junction, which is a thin insulating barrier between two superconductors. This frequency is crucial in understanding how the quantum mechanical properties of superconductors manifest in practical applications, such as in quantum computing and sensitive magnetometry. The Josephson frequency is directly related to the voltage across the junction, and it plays a key role in the dynamics of Josephson junctions.
Josephson Junctions: Josephson junctions are quantum devices formed by two superconductors separated by a thin insulating barrier. They exhibit unique properties such as the ability to allow supercurrent to flow without any voltage applied, enabling a variety of applications in quantum computing, sensitive magnetometry, and superconducting electronics. The behavior of Josephson junctions is governed by the Josephson effect, which describes the flow of Cooper pairs across the junction and can be manipulated using external magnetic fields and voltages.
Josephson Penetration Depth: Josephson penetration depth is a measure of how deeply a supercurrent can penetrate into a superconductor from its surface when influenced by an external magnetic field. This depth is crucial in understanding the behavior of superconductors and Josephson junctions, as it affects the coupling of superconducting wave functions and the performance of devices based on these principles.
Lead: Lead is a heavy metal with the chemical symbol Pb, known for its high density and malleability. In the context of superconductivity, lead is notable as it exhibits superconducting properties at low temperatures, making it one of the first elements discovered to become a superconductor. The ability of lead to transition into a superconducting state plays a crucial role in applications like Josephson junctions, where it facilitates quantum tunneling effects essential for advanced electronic devices.
Macroscopic quantum coherence: Macroscopic quantum coherence refers to the phenomenon where a large number of particles exhibit quantum behavior collectively, maintaining a coherent quantum state over macroscopic scales. This coherence is crucial in various quantum systems, enabling phenomena such as superfluidity and superconductivity, where classical physics fails to describe the behavior of materials. In particular, this concept plays a significant role in understanding the operation of devices like Josephson junctions, where the quantum mechanical properties of supercurrents emerge.
Magnesium oxide: Magnesium oxide (MgO) is a white solid mineral compound formed by the reaction of magnesium with oxygen. It plays a critical role in various applications, including as an insulating material in superconductors, particularly within Josephson junctions, where it helps maintain the necessary conditions for superconductivity and quantum behavior.
Magnetometry: Magnetometry is the measurement of magnetic fields and their properties, often used to analyze materials in solid state physics. This technique helps in understanding phenomena such as how materials respond to magnetic fields, which is crucial for studying superconductivity and other magnetic behaviors. It plays a significant role in exploring how different materials exhibit magnetic properties, including the effects seen in superconductors and their interactions with external magnetic fields.
Niobium: Niobium is a metallic element with the symbol Nb and atomic number 41, known for its excellent superconducting properties, especially at low temperatures. Its significance lies in its application in superconductors, particularly in Josephson junctions and its classification as a Type-II superconductor, which allows it to maintain superconductivity under higher magnetic fields compared to Type-I superconductors.
Phase Difference: Phase difference is the measure of the difference in phase between two periodic signals, typically expressed in degrees or radians. It is crucial in understanding how waves interact with each other, particularly in phenomena like interference and resonance, and plays a significant role in the operation of superconducting devices.
Quantum tunneling: Quantum tunneling is a quantum mechanical phenomenon where a particle passes through a potential energy barrier that it classically shouldn't be able to surmount. This occurs because particles, such as electrons, exhibit wave-like behavior, allowing them to have a non-zero probability of existing on the other side of an energy barrier. The effect is crucial in various applications, such as superconductivity and the operation of certain electronic devices.
Scanning Tunneling Microscopy: Scanning tunneling microscopy (STM) is a powerful technique that allows researchers to visualize surfaces at the atomic level by scanning a sharp metallic tip very close to a conductive surface. This method relies on quantum tunneling, where electrons tunnel between the tip and the surface, creating a current that is measured to provide detailed topographical and electronic information about the surface being studied.
Sfs junction: An sfs junction, or Superconductor-Ferromagnet-Superconductor junction, is a type of quantum device that consists of two superconductors separated by a ferromagnetic material. This structure is significant because it combines the unique properties of superconductivity with ferromagnetism, allowing for phenomena such as spin-polarized currents and Josephson effects that depend on the magnetic state of the ferromagnet. The behavior of sfs junctions can lead to interesting applications in spintronics and quantum computing.
Shapiro Steps: Shapiro steps are discrete voltage steps observed in the current-voltage (I-V) characteristics of Josephson junctions when they are subjected to an external microwave radiation. These steps occur at specific voltage values and indicate the quantized energy levels associated with the Cooper pairs in the superconductor, revealing important information about the dynamics of superconducting systems under microwave excitation.
SIS Junction: A SIS junction is a type of Josephson junction consisting of two superconductors separated by an insulating barrier. This configuration allows for the phenomenon of superconducting tunneling, enabling Cooper pairs to pass through the barrier, which is critical in the operation of superconducting devices. SIS junctions are important for their applications in quantum computing and other advanced electronic systems.
SQUIDs: SQUIDs, or Superconducting Quantum Interference Devices, are highly sensitive magnetometers used to measure extremely small magnetic fields. They operate based on the principles of superconductivity and quantum interference, allowing them to detect magnetic flux changes at the quantum level. Their unique properties make them crucial in various applications, including medical imaging and particle physics experiments.
Superconducting qubits: Superconducting qubits are the fundamental building blocks of quantum computers, utilizing the unique properties of superconductivity to create quantum bits that can exist in multiple states simultaneously. These qubits leverage Josephson junctions, which are thin insulating barriers between two superconductors, allowing for coherent quantum states and fast operations. The ability to manipulate and measure these states with high precision makes superconducting qubits a promising technology in the field of quantum computing.
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