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Alkenes are converted to 1,2-diols or glycols through a process called dihydroxylation. It involves the addition of two hydroxyl groups across the double bond with two different stereochemical approaches, namely anti and syn. Dihydroxylation using osmium tetroxide progresses with syn stereochemistry.
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A pure, perfectly crystalline solid possessing no kinetic energy (that is, at a temperature of absolute zero, 0 K) may be described by a single microstate, as its purity, perfect crystallinity,and complete lack of motion means there is but one possible location for each identical atom or molecule comprising the crystal (W = 1). According to the Boltzmann equation, the entropy of this system is zero.
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A reduction-oxidation reaction is commonly called a redox reaction. In a redox reaction, electrons are transferred from one species to another rather than being shared between or among atoms. The reducing agent or reductant is the species that loses electrons and gets oxidized in the process. The species that gains electrons and gets reduced in the process is the oxidizing agent or oxidant. Redox reactions are represented as two separate equations called half-reactions, where one equation...
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Updated: Sep 9, 2025

Bulk and Thin Film Synthesis of Compositionally Variant Entropy-stabilized Oxides
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Bulk and Thin Film Synthesis of Compositionally Variant Entropy-stabilized Oxides

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Thermodynamics-inspired high-entropy oxide synthesis.

Saeed S I Almishal1, Matthew Furst2, Yueze Tan2

  • 1Department of Materials Science and Engineering, The Pennsylvania State University, University Park, PA, USA. saeedsialmishal@gmail.com.

Nature Communications
|September 2, 2025
PubMed
Summary

Controlling oxygen chemical potential in high-entropy oxides (HEOs) forces multivalent cations into divalent states. This discovery enables predicting HEO stability and synthesis, expanding material design possibilities.

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Area of Science:

  • Materials Science
  • Solid-State Chemistry
  • Thermodynamics

Background:

  • High-entropy oxides (HEOs) exhibit complex thermodynamics influenced by factors beyond temperature.
  • Oxygen chemical potential is a critical, yet often overlooked, variable in HEO systems.
  • Understanding cation valence states is crucial for predicting HEO properties and stability.

Purpose of the Study:

  • To experimentally demonstrate the influence of oxygen chemical potential on cation valence in rock salt HEOs.
  • To develop a predictive framework for HEO stability and synthesizability.
  • To explore new HEO compositions with tunable properties.

Main Methods:

  • Experimental control of oxygen chemical potential to influence cation valence.
  • Construction of preferred valence phase diagrams and enthalpic stability maps.
  • Synthesis and characterization of equimolar rock salt HEOs using XRD, XRF, EDS, and XAFS.
  • Atomistic calculations with machine learning interatomic potentials.

Main Results:

  • Demonstrated coercion of multivalent cations (Mn, Fe) into predominantly divalent states in rock salt HEOs by controlling oxygen chemical potential.
  • Successfully synthesized seven new equimolar, single-phase rock salt HEOs.
  • Validated homogeneous cation distribution and confirmed divalent cation states.
  • Developed a preferred valence phase diagram and an enthalpic stability map.

Conclusions:

  • Oxygen chemical potential is a key thermodynamic parameter for HEO design and synthesis.
  • Oxygen chemical potential overlap serves as a crucial descriptor for predicting HEO stability.
  • The developed framework is broadly applicable to various HEO compositions and structures.