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Related Concept Videos

The Role of Ion Channels in Neuronal Computation01:19

The Role of Ion Channels in Neuronal Computation

A postsynaptic neuron usually receives numerous impulses from several other presynaptic neurons. The axon hillock of the postsynaptic neuron integrates all these signals and determines the likelihood of firing an action potential.
Sometimes a single EPSP is strong enough to induce an action potential in the postsynaptic neuron. However, multiple presynaptic inputs must often create EPSPs around the same time for the postsynaptic neuron to be sufficiently depolarized to fire an action potential.
Non-gated Ion Channels01:24

Non-gated Ion Channels

Ion channels are specialized proteins on the plasma membrane that allow charged ions to pass down their electrochemical gradient. Their main function is to maintain the membrane potential which is critical for cell viability. These channels are either gated or non-gated and can transport more than a thousand ions within milliseconds for the cellular event to occur.
Compared to the gated ion channels, the non-gated channels, also known as leakage or passive channels, have no gating mechanism.
Non-gated Ion Channels01:24

Non-gated Ion Channels

Ion channels are specialized proteins on the plasma membrane that allow charged ions to pass down their electrochemical gradient. Their main function is to maintain the membrane potential which is critical for cell viability. These channels are either gated or non-gated and can transport more than a thousand ions within milliseconds for the cellular event to occur.
Compared to the gated ion channels, the non-gated channels, also known as leakage or passive channels, have no gating mechanism.
Facilitated Transport01:19

Facilitated Transport

The chemical and physical properties of plasma membranes cause them to be selectively permeable. Since plasma membranes have both hydrophobic and hydrophilic regions, substances need to be able to transverse both regions. The hydrophobic area of membranes repels substances such as charged ions. Therefore, such substances need special membrane proteins to cross a membrane successfully. In  facilitated transport, also known as facilitated diffusion, molecules and ions travel across a membrane via...
Ion Channels01:19

Ion Channels

The movement of ions like sodium, potassium, and calcium into and out of the cell is essential to maintain the electrochemical gradient in living cells. The ion channels—a class of membrane transport proteins—help maintain this ionic gradient for the smooth functioning of physiological activities such as maintaining cell size and volume, conducting nerve impulses, and gas and nutrient exchange.
Ion channels are specialized integral membrane proteins on the plasma membrane that allow specific...
Voltage-gated Ion Channels01:26

Voltage-gated Ion Channels

Voltage-gated ion channels are transmembrane proteins that open and close in response to changes in the membrane potential. They are present on the membranes of all electrically excitable cells such as neurons, heart, and muscle cells.
Generally, all voltage-gated ion channels have a 'voltage-sensing domain' that spans the lipid bilayer. The charged residues in the sensor move in response to the membrane potential changes that open the channel allowing ions movement. There are several types of...

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Related Experiment Video

Updated: Jun 25, 2026

Generation and Coherent Control of Pulsed Quantum Frequency Combs
06:42

Generation and Coherent Control of Pulsed Quantum Frequency Combs

Published on: June 8, 2018

Can nonprivate channels transmit quantum information?

Graeme Smith1, John A Smolin

  • 1IBM T. J. Watson Research Center, Yorktown Heights, New York 10598, USA. gsbsmith@gmail.com

Physical Review Letters
|March 5, 2009
PubMed
Summary
This summary is machine-generated.

Quantum channels with limited private capacity can transmit significantly more quantum information when paired. This finding challenges assumptions about quantum communication and reveals a large violation of additivity for private capacity.

More Related Videos

Quantum State Engineering of Light with Continuous-wave Optical Parametric Oscillators
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Quantum State Engineering of Light with Continuous-wave Optical Parametric Oscillators

Published on: May 30, 2014

Related Experiment Videos

Last Updated: Jun 25, 2026

Generation and Coherent Control of Pulsed Quantum Frequency Combs
06:42

Generation and Coherent Control of Pulsed Quantum Frequency Combs

Published on: June 8, 2018

Quantum State Engineering of Light with Continuous-wave Optical Parametric Oscillators
09:23

Quantum State Engineering of Light with Continuous-wave Optical Parametric Oscillators

Published on: May 30, 2014

Area of Science:

  • Quantum Information Science
  • Quantum Communication Theory
  • Information Theory

Background:

  • Quantum channels are essential for transmitting quantum states.
  • Privacy is a fundamental requirement for quantum communication.
  • The private capacity quantifies the rate of private information transmission.

Purpose of the Study:

  • To investigate the communication capabilities of quantum channels with minimal or no private capacity.
  • To explore the additivity properties of private capacity for composite quantum channels.
  • To identify scenarios where the sum of individual channel capacities is less than the joint capacity.

Main Methods:

  • Analysis of quantum channel properties, focusing on private communication.
  • Theoretical investigation of composite channel behavior.
  • Mathematical formulation and proof of capacity additivity violations.

Main Results:

  • Demonstrated pairs of quantum channels with low individual private capacities exhibiting a large joint quantum capacity.
  • Presented specific quantum channels that show a significant violation of additivity for private capacity.
  • Identified channels that severely violate additivity for the Holevo information.

Conclusions:

  • Quantum channels with limited private capacity can be surprisingly effective for information transmission when combined.
  • The study reveals a substantial breakdown of additivity for private capacity, challenging established theoretical frameworks.
  • Findings have implications for understanding the fundamental limits of quantum communication and information processing.