Katie A. Lundell scite author profile

The discovery of homodinuclear multiple bonds composed of Group 13 elements represents one of the most challenging frontiers in modern chemistry. A classical triple bond such as N≡N and HC≡CH contains one σ bond and two π bonds constructed from the p orbitals perpendicular to the σ bond. However, the traditional textbook triple bond between two Al atoms has remained elusive. Here we report an Al≡Al triple bond in the designer Na Al cluster predicted in silico, which was subsequently generated by pulsed arc discharge followed by mass spectrometry and photoelectron spectroscopy characterizations. Being effectively Al due to the electron donation from Na, the Al atoms in Na Al undergo a double electronic transmutation into Group 15 elements, thus the Al ≡Al kernel mimics the P≡P and N≡N molecules. We anticipate this work will stimulate more endeavors in discovering materials using Al ≡Al as a building block in the gas phase and in the solid state.

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The Existence of a Designer Al=Al Double Bond in the LiAl₂H₄⁻ Cluster Formed by Electronic Transmutation

Lundell

Zhang

Boldyrev

et al. 2017

Angew Chem Int Ed

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The Al=Al double bond is elusive in chemistry. Herein we report the results obtained via combined photoelectron spectroscopy and ab initio studies of the LiAl H cluster that confirm the formation of a conventional Al=Al double bond. Comprehensive searches for the most stable structures of the LiAl H cluster have shown that the global minimum isomer I possesses a geometric structure which resembles that of Si H , demonstrating a successful example of the transmutation of Al atoms into Si atoms by electron donation. Theoretical simulations of the photoelectron spectrum discovered the coexistence of two isomers in the ion beam, including the one with the Al=Al double bond.

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Electronic Transmutation (ET): Chemically Turning One Element into Another

Zhang

Lundell

Olson

et al. 2018

Chemistry A European J

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The concept of electronic transmutation (ET) depicts the processes that by acquiring an extra electron, an element with the atomic number Z begins to have properties that were known to only belong to its neighboring element with the atomic number Z+1. Based on ET, signature compounds and chemical bonds that are composed of certain elements can now be designed and formed by other electronically transmutated elements. This Minireview summarizes the recent developments and applications of ET on both the theoretical and experimental fronts. Examples on the ET of Group 13 elements into Group 14 elements, Group 14 elements into Group 15 elements, and Group 15 elements into Group 16 elements are discussed. Compounds and chemical bonding composed of carbon, silicon, germanium, phosphorous, oxygen and sulfur now have analogues using transmutated boron, aluminum, gallium, silicon, nitrogen, and phosphorous.

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Tug-of-war between classical and multicenter bonds in H-(Be)n-H species

Lundell

Boldyrev

2018

Chemical Physics Letters

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Realization of an Al≡Al Triple Bond in the Gas‐Phase Na₃Al₂⁻ Cluster via Double Electronic Transmutation

et al. 2018

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The discovery of homodinuclear multiple bonds composed of Group 13 elements represents one of the most challenging frontiers in modern chemistry.Aclassical triple bond such as NNand HCCH contains one s bond and two p bonds constructed from the porbitals perpendicular to the s bond. However,the traditional textbook triple bond between two Al atoms has remained elusive.H ere we report an Al Al triple bond in the designer Na 3 Al 2 À cluster predicted in silico, which was subsequently generated by pulsed arc discharge followed by mass spectrometry and photoelectron spectroscopy characterizations.Being effectively Al 2À due to the electron donation from Na, the Al atoms in Na 3 Al 2 À undergo adouble electronic transmutation into Group 15 elements,t hus the Al 2À Al 2À kernel mimics the P Pa nd N Nm olecules.W e anticipate this work will stimulate more endeavors in discovering materials using Al 2À Al 2À as abuilding blocki nt he gas phase and in the solid state.

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Katie A. Lundell

Realization of an Al≡Al Triple Bond in the Gas‐Phase Na₃Al₂⁻ Cluster via Double Electronic Transmutation

The Existence of a Designer Al=Al Double Bond in the LiAl₂H₄⁻ Cluster Formed by Electronic Transmutation

Electronic Transmutation (ET): Chemically Turning One Element into Another

Tug-of-war between classical and multicenter bonds in H-(Be)n-H species

Realization of an Al≡Al Triple Bond in the Gas‐Phase Na₃Al₂⁻ Cluster via Double Electronic Transmutation

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Katie A. Lundell

Realization of an Al≡Al Triple Bond in the Gas‐Phase Na3Al2− Cluster via Double Electronic Transmutation

The Existence of a Designer Al=Al Double Bond in the LiAl2H4− Cluster Formed by Electronic Transmutation

Electronic Transmutation (ET): Chemically Turning One Element into Another

Tug-of-war between classical and multicenter bonds in H-(Be)n-H species

Realization of an Al≡Al Triple Bond in the Gas‐Phase Na3Al2− Cluster via Double Electronic Transmutation

Contact Info

Product

Resources

About

Realization of an Al≡Al Triple Bond in the Gas‐Phase Na₃Al₂⁻ Cluster via Double Electronic Transmutation

The Existence of a Designer Al=Al Double Bond in the LiAl₂H₄⁻ Cluster Formed by Electronic Transmutation

Realization of an Al≡Al Triple Bond in the Gas‐Phase Na₃Al₂⁻ Cluster via Double Electronic Transmutation