Jove
Visualize
Contact Us
JoVE
x logofacebook logolinkedin logoyoutube logo
ABOUT JoVE
OverviewLeadershipBlogJoVE Help Center
AUTHORS
Publishing ProcessEditorial BoardScope & PoliciesPeer ReviewFAQSubmit
LIBRARIANS
TestimonialsSubscriptionsAccessResourcesLibrary Advisory BoardFAQ
RESEARCH
JoVE JournalMethods CollectionsJoVE Encyclopedia of ExperimentsArchive
EDUCATION
JoVE CoreJoVE BusinessJoVE Science EducationJoVE Lab ManualFaculty Resource CenterFaculty Site
Terms & Conditions of Use
Privacy Policy
Policies

Related Concept Videos

Composite Masonry Walls01:18

Composite Masonry Walls

1.1K
Composite masonry walls combine multiple wythes of the same or different masonry materials to create a unified structure. These walls feature wythes that are bonded together either through mortar-filled collar joints, grouted spaces, or more commonly, with rigid metal ties and reinforcements, with the use of masonry header units being rare. Metal ties are preferred because they effectively minimize water penetration, as these walls primarily absorb moisture and then release it into the...
1.1K
Masonry Curtain Walls01:20

Masonry Curtain Walls

1.0K
Masonry curtain walls employ brick or stone veneers supported by the building's structure to form an external cladding system that is both aesthetically appealing and functional. These walls are erected through two principal techniques, first by traditional layering of masonry units and second by using prefabricated panels. Traditional construction relies on steel shelf angles attached to the spandrel beam for support, with high-bond mortars ensuring secure attachment of masonry veneer...
1.0K
Masonry Loadbearing Walls01:16

Masonry Loadbearing Walls

102
Masonry load-bearing walls, constructed from materials like brick, stone, or concrete masonry units, serve as a crucial component in building structures by supporting the loads from floors and roofs and transferring them to the foundation. These walls, known for their compressive strength, can be reinforced or unreinforced to suit different building needs, accommodating both the dead and live loads while maintaining safety through lower working stresses compared to the materials' ultimate...
102
Masonry Cavity Walls01:26

Masonry Cavity Walls

1.0K
Cavity walls feature a hollow space between the outer and inner wythes, connected only by corrosion-resistant metal ties. When water seeps through the outer wythe, it descends within this cavity, intercepted by flashing and eventually exiting through weep holes. To enhance moisture resistance, the inner wythe's cavity side often receives damp-proofing, doubling as an air barrier. The cavity can also house insulation to mitigate heat transfer.
Maintaining a clean cavity during construction...
1.0K
Brick Masonry01:12

Brick Masonry

97
Brick masonry uses bricks as the building blocks and involves building walls from individual bricks laid in mortar. The basic building block of brick masonry is the wythe, a vertical layer of bricks with a thickness of one brick. Within a wythe, bricks can be laid in various courses or patterns, with the most common being the stretcher course, where bricks are laid with their long edge horizontal and face parallel to the wall.
For thicker walls, multiple wythes are bonded together using...
97
Mortar01:29

Mortar

207
Mortar, a mixture of Portland cement, hydrated lime, sand, and water, is a crucial binding material in construction. Its primary function is to join masonry units together, filling gaps and ensuring a uniform distribution of weight across the structure. This helps in preventing potential weaknesses. Mortar also serves as a protective barrier against environmental elements such as water and wind, thereby safeguarding the interior of the structure. It also compensates for surface irregularities...
207

You might also read

Related Articles

Articles linked to this work by shared authors, journal, and citation graph.

Sort by
Same author

Noise-induced shallow circuits and the absence of barren plateaus.

Nature physics·2026
Same author

Computing efficiently in QLDPC codes.

Nature communications·2026
Same author

Measurement-Driven Quantum Advantages in Shallow Circuits.

Physical review letters·2026
Same author

Learning quantum states of continuous-variable systems.

Nature physics·2025
Same author

Large-scale stochastic simulation of open quantum systems.

Nature communications·2025
Same author

In the Shadow of the Hadamard Test: Using the Garbage State for Good and Further Modifications.

Physical review letters·2025
Same journal

Erratum: Bacterial Turbulence at Compressible Fluid Interfaces [Phys. Rev. Lett. 136, 138301 (2026)].

Physical review letters·2026
Same journal

Unveiling Light-Quark Yukawa Flavor Structure via Dihadron Fragmentation at Lepton Colliders.

Physical review letters·2026
Same journal

Adaptable Route to Fast Coherent State Transport via Bang-Bang-Bang Protocols.

Physical review letters·2026
Same journal

Topological Transition and Emergence of Elasticity of Dislocation in Skyrmion Lattice: Beyond Kittel's Magnetic-Polar Analogy.

Physical review letters·2026
Same journal

Pound-Drever-Hall Method for Superconducting-Qubit Readout.

Physical review letters·2026
Same journal

Coupling a ^{73}Ge Nuclear Spin to an Electrostatically Defined Quantum Dot in Silicon.

Physical review letters·2026
See all related articles

Related Experiment Video

Updated: Jun 11, 2025

Application of Membrane and Cell Wall Selective Fluorescent Dyes for Live-Cell Imaging of Filamentous Fungi
07:44

Application of Membrane and Cell Wall Selective Fluorescent Dyes for Live-Cell Imaging of Filamentous Fungi

Published on: November 28, 2019

21.0K

Domain Wall Color Code.

Konstantin Tiurev1, Arthur Pesah2, Peter-Jan H S Derks3

  • 1HQS Quantum Simulations GmbH, Rintheimer Strasse 23, 76131 Karlsruhe, Germany.

Physical Review Letters
|September 27, 2024
PubMed
Summary
This summary is machine-generated.

We developed a new quantum error-correcting code with high error thresholds for biased noise. This domain wall color code offers resource efficiency for realistic quantum computing applications.

More Related Videos

Histochemical Staining of Arabidopsis thaliana Secondary Cell Wall Elements
10:39

Histochemical Staining of Arabidopsis thaliana Secondary Cell Wall Elements

Published on: May 13, 2014

40.7K
A Standardized Obstacle Course for Assessment of Visual Function in Ultra Low Vision and Artificial Vision
09:29

A Standardized Obstacle Course for Assessment of Visual Function in Ultra Low Vision and Artificial Vision

Published on: February 11, 2014

13.0K

Related Experiment Videos

Last Updated: Jun 11, 2025

Application of Membrane and Cell Wall Selective Fluorescent Dyes for Live-Cell Imaging of Filamentous Fungi
07:44

Application of Membrane and Cell Wall Selective Fluorescent Dyes for Live-Cell Imaging of Filamentous Fungi

Published on: November 28, 2019

21.0K
Histochemical Staining of Arabidopsis thaliana Secondary Cell Wall Elements
10:39

Histochemical Staining of Arabidopsis thaliana Secondary Cell Wall Elements

Published on: May 13, 2014

40.7K
A Standardized Obstacle Course for Assessment of Visual Function in Ultra Low Vision and Artificial Vision
09:29

A Standardized Obstacle Course for Assessment of Visual Function in Ultra Low Vision and Artificial Vision

Published on: February 11, 2014

13.0K

Area of Science:

  • Quantum Information Science
  • Quantum Error Correction
  • Condensed Matter Theory

Background:

  • Quantum error correction is crucial for fault-tolerant quantum computing.
  • Biased noise poses a significant challenge for existing quantum codes.
  • Color codes offer a flexible framework for designing quantum error-correcting codes.

Purpose of the Study:

  • Introduce a novel quantum error-correcting code, the domain wall color code.
  • Investigate its performance under biased noise conditions.
  • Assess its suitability for practical implementation in quantum systems.

Main Methods:

  • Developed a new variant of the quantum color code incorporating domain walls.
  • Analyzed the code's behavior in both infinite and finite bias regimes.
  • Designed a scalable restriction decoder utilizing a matching algorithm.

Main Results:

  • The domain wall color code achieves high code-capacity error thresholds for biased noise.
  • In the infinite bias limit, it decouples to repetition codes with a 50% threshold.
  • At finite bias, it matches the performance of the XZZX surface code for Pauli noise.

Conclusions:

  • The domain wall color code is a resource-efficient quantum error-correcting code.
  • It demonstrates exceptional performance against realistic, biased noise channels.
  • The code is highly suitable for practical implementation in quantum computing architectures.