Draft:Goniopolar materials

Submission rejected on 5 January 2024 by Ldm1954 (talk). This submission is contrary to the purpose of Wikipedia. Rejected by Ldm1954 4 months ago. Last edited by Citation bot 59 days ago. Ask for advice

Submission declined on 4 January 2024 by Qcne (talk). This submission does not appear to be written in the formal tone expected of an encyclopedia article. Entries should be written from a neutral point of view, and should refer to a range of independent, reliable, published sources. Please rewrite your submission in a more encyclopedic format. Please make sure to avoid peacock terms that promote the subject. Declined by Qcne 4 months ago.

• Comment: This article is currently very inappropriate. No attempt is made to show notability, the sources (references) are inappropriate: 1 is a proposal, 2 & 3 are off topic. The sections about work at Ohio State are advertising.
  What is discussed herein in not new, it is an extreme example of highly anisotripic effective mass tensors. Wikipedia is not the place for this. Ldm1954 (talk) 03:06, 5 January 2024 (UTC)

• Comment: This actually looks like a really interesting field of new research. Unfortunately, at this time, I think it's too soon for a useful article to be written. Until potential applications have been explored and developed, this phenomenon appears to be just a curiosity. WikiDan61^ChatMe!_ReadMe!! 22:12, 4 January 2024 (UTC)

• Comment: Was this written by ChatGPT? Qcne (talk) 16:28, 4 January 2024 (UTC)

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Goniopolar Material

Goniopolar Materials

Goniopolar materials^[1] represent a unique class of materials characterized by their ability to exhibit dual conductivity behavior, conducting both n-type (electron-conducting) and p-type (hole-conducting) carriers^[2] along distinct crystallography axes simultaneously. This phenomenon contrasts with conventional electronic materials, which typically demonstrate either n-type or p-type conduction along their principal axes.

Characteristics

Goniopolar materials are distinguished by their anisotropic bonding and crystal structures often manifesting in layered or chain-like frameworks.^[3] Within these structures, the band curvatures along different axes vary significantly. This variance results in distinct mobility tensors for electrons and holes, leading to substantially higher electron and hole mobilities along orthogonal crystallographic directions when both types of carriers are present.

Properties and Applications

The unique property of goniopolarity holds promise for diverse applications in electronic and energy-related technologies. The simultaneous conduction of electrons and holes along orthogonal axes within these materials opens possibilities for enhanced performance in various devices. Potential applications include telecommunications, antennas, quantum computers, and energy-harvesting technologies.

Scientific Investigations and Research

Several studies and research articles have delved into the properties and potential applications of goniopolar materials. Michael Richard Scudder's work in "Materials with Axis-Dependent Conduction Polarity and their Application in Transverse Thermoelectric Devices". proquest.com. and research published in "The Fermi Surface Geometrical Origin of Axis-Dependent Conduction Polarity in Layered Materials". nature.com. explore the characteristics and implications of goniopolarity in materials science.

There is currently research^[1] being pursued at the Ohio State University on goniopolar material and its technological application. "GonioTech LLC". goniotech.com. is collaborating with Ohio State to exploit goniopolar properties and uses in electronic devices.

References

1. "Public Abstract | PAMS". pamspublic.science.energy.gov. Retrieved 2024-01-04.
2. "I. P-Type, N-Type Semiconductors". Engineering LibreTexts. 2018-11-03. Retrieved 2024-01-04.
3. Pearce, Amanda K.; Wilks, Thomas R.; Arno, Maria C.; O'Reilly, Rachel K. (January 2021). "Synthesis and applications of anisotropic nanoparticles with precisely defined dimensions". Nature Reviews Chemistry. 5 (1): 21–45. doi:10.1038/s41570-020-00232-7. ISSN 2397-3358. PMID 37118104. S2CID 227236564.

External links

• Goniopolar materials: fundamentals and applications - nature.com
• Goniopolar Materials and Applications - dtic.mil
• Materials with Axis-Dependent Conduction Polarity and their Application in Transverse Thermoelectric Devices - proquest.com
• The Fermi Surface Geometrical Origin of Axis-Dependent Conduction Polarity in Layered Materials - nature.com
• GonioTech LLC - goniotech.com
• MSE Colloquium - Wolfgang Windl - Last Lecture: Semiconductors, Goniopolar Materials or? - mse.osu.edu
• Researchers discover new material to help power electronics - news.osu.edu