Alexander Boldyrev

Last updated
Alexander I. Boldyrev
Alexander Boldyrev.jpg
Born
Alexander Ivanovich Boldyrev

(1951-12-19)19 December 1951
Died 26 August 2023(2023-08-26) (aged 71)
Alma mater Novosibirsk University

Moscow State University

USSR/Physico-Chemical Institute
Known forSuperhalogens; Superalkalis; Tetracoordinated planar carbon; All-metal aromaticity/antiaromaticity; Multicenter bonding; Multiple aromaticity/antiaromaticity; Conflicting aromaticity; Double inorganic helix; Boron and Aluminum clusters;
Scientific career
FieldsComputational Chemistry; Quantum Chemistry; Materials Science;
Websiteion.chem.usu.edu/~boldyrev/

Alexander I. Boldyrev (December 19, 1951 - August 26, 2023) was a Russian-American computational chemist and R. Gaurth Hansen Professor at Utah State University. Professor Boldyrev is known for his pioneering works on superhalogens, superalkalis, tetracoordinated planar carbon, inorganic double helix, boron and aluminum clusters, and chemical bonding theory, especially aromaticity/antiaromaticity in all-metal structures, and development of the Adaptive Natural Density Partitioning (AdNDP) method. [1]

Contents

Biography and Education

Alexander Boldyrev was born in the industrial Siberian city Novokuznetsk. After graduation from Specialized Educational Scientific Center at Novosibirsk University located in Siberian Akademgorodok, he was admitted to the Department of Chemistry at Novosibirsk University. While pursuing the B.Sc./M.Sc. degree, Alexander Boldyrev was doing his research at the Institute of Catalysis, USSR Academy of Sciences under Dr. Vasily Avdeev supervision. During this time, Alexander Boldyrev first encountered quantum-chemical calculations which shaped his further scientific career. After graduation from the university, he moved to another academic city, Chernogolovka, and joined Dr. Oleg Charkin's group when he worked on Non-rigid molecules and polytopic bonds. Later, he extended this study to his Ph.D. thesis which he defended in 1978. Following years, Dr. Boldyrev spent studying superhalogens and superallakis in Chernogolovka. [2]

In 1983, Alexander joined Prof. Ovchinnikov lab at the Institute of Chemical Physics, USSR Academy of Science. In 1986, he received a Doctor of Science degree, the highest scientific degree in the USSR. In 1990, Dr. Boldyrev left USSR to join Paul von Ragué Schleyer group in Germany as a postdoc. There, he made a contribution to the theoretical chemistry of planar tetracoordinate carbon. [2]

Further, Dr. Boldyrev moved to the United States where he worked for 7 year in Prof. Jack Simons research group. His research spanned hypervalent (“Rydberg”) molecules and stability of multiply charged anions (SO42−, PO43-) and their solvated forms. In 1999, Dr. Boldyrev became an assistant professor at Utah State University. Six years later, Alexander I. Boldyrev became a Full Professor, and in 2020 was awarded the R. Gaurth Hansen Professorship. [3]

Research

During his academic career, Alexander Boldyrev worked on a wide range of topics related to quantum chemistry and physical chemistry. His works together with Paul von Ragué Schleyer were among the prediction of new way to achieve planar tetracoordinated carbon and participated in the first experimental conformation of such species in molecular beams with Prof. Lai-Sheng Wang. [4] Dr. Boldyrev and Dr. Gutsev also developed the theory of superhalogens [5] – molecules with high Electron affinity exceeding 7 eV in some cases (while the Electron affinity of halogens are 3-3.6 eV). In analogy to superhalogens, Boldyrev and Gutsev introduced superalkalis, [6] species with extremely low Ionization potential, lower than that of a Caesium atom. Alexander Boldyrev together with Lai-Sheng Wang made a large contribution to the theory of chemical bonding, especially in the topic of Aromaticity and Antiaromaticity.

Adaptive Natural Density Partitioning Algorithm

Example of AdNDP analysis of TaB10 molecule. The following notation is used here: n-center 2-electron bonding element is denoted as nc-2e; occupation number is denoted as ON. TaB10.tif
Example of AdNDP analysis of TaB10 molecule. The following notation is used here: n-center 2-electron bonding element is denoted as nc-2e; occupation number is denoted as ON.

The Adaptive Natural Density Partitioning Algorithm (AdNDP) is a theoretical tool for deciphering chemical bonding. It is generally applicable to any chemical system including molecules, clusters, mechanically bonded structures and solvated species. The algorithm was developed in 2008 by Dmitry Zubarev and Alexander Boldyrev. [8] The AdNDP is based on the concept of occupancies of multicenter bonds. Thus, it represents the electronic structure in terms of n-center two-electron (nc-2e) bonds. AdNDP recovers both Lewis bonding elements (1c-2e and 2c-2e elements, corresponding to the lone pairs and two-center two-electron bonds, respectively) and deslocalized bonding elements, which are associated with the concepts of aromaticity and antiaromaticity. From this point of view, AdNDP achieves a seamless description of systems featuring both localized and delocalized bonding without invoking the concept of resonance (although, AdNDP is also capable of providing resonance structures). Essentially, AdNDP is a very efficient and illustrative approach for interpretation of the molecular orbital-based wave functions. [8] [9] AdNDP is closely related to Natural bond orbital theory but allows any number of atoms to participate in bond localization.

In 2013, a Solid State Adaptive Natural Density Partitioning (SSAdNDP), an extension of AdNDP, was introduced by Timur Galeev and Alexander Boldyrev in collaboration with Benjamin D. Dunnington and J. R. Schmidt. [10] The algorithm enables the application of AdNDP formalism to periodic systems. As in the original AdNDP algorithm, SSAdNDP allows the interpretation of chemical bonding in systems with translational symmetry in terms of classical lone pairs, two-center bonds, as well as multi-center delocalized bonding elements.

Honors and awards

Selected publications

Related Research Articles

<span class="mw-page-title-main">Conjugated system</span> System of connected p-orbitals with delocalized electrons in a molecule

In theoretical chemistry, a conjugated system is a system of connected p-orbitals with delocalized electrons in a molecule, which in general lowers the overall energy of the molecule and increases stability. It is conventionally represented as having alternating single and multiple bonds. Lone pairs, radicals or carbenium ions may be part of the system, which may be cyclic, acyclic, linear or mixed. The term "conjugated" was coined in 1899 by the German chemist Johannes Thiele.

<span class="mw-page-title-main">Aromaticity</span> Chemical property

In organic chemistry, aromaticity is a chemical property describing the way in which a conjugated ring of unsaturated bonds, lone pairs, or empty orbitals exhibits a stabilization stronger than would be expected by the stabilization of conjugation alone. The earliest use of the term was in an article by August Wilhelm Hofmann in 1855. There is no general relationship between aromaticity as a chemical property and the olfactory properties of such compounds.

<span class="mw-page-title-main">Hückel's rule</span> Method of determining aromaticity in organic molecules

In organic chemistry, Hückel's rule predicts that a planar ring molecule will have aromatic properties if it has 4n + 2 π-electrons, where n is a non-negative integer. The quantum mechanical basis for its formulation was first worked out by physical chemist Erich Hückel in 1931. The succinct expression as the 4n + 2 rule has been attributed to W. v. E. Doering (1951), although several authors were using this form at around the same time.

Antiaromaticity is a chemical property of a cyclic molecule with a π electron system that has higher energy, i.e., it is less stable due to the presence of 4n delocalised electrons in it, as opposed to aromaticity. Unlike aromatic compounds, which follow Hückel's rule and are highly stable, antiaromatic compounds are highly unstable and highly reactive. To avoid the instability of antiaromaticity, molecules may change shape, becoming non-planar and therefore breaking some of the π interactions. In contrast to the diamagnetic ring current present in aromatic compounds, antiaromatic compounds have a paramagnetic ring current, which can be observed by NMR spectroscopy.

Pentazole is an aromatic molecule consisting of a five-membered ring with all nitrogen atoms, one of which is bonded to a hydrogen atom. It has the molecular formula HN5. Although strictly speaking a homocyclic, inorganic compound, pentazole has historically been classed as the last in a series of heterocyclic azole compounds containing one to five nitrogen atoms. This set contains pyrrole, imidazole, pyrazole, triazoles, tetrazole, and pentazole.

<span class="mw-page-title-main">Cyclooctatetraene</span> Chemical compound

1,3,5,7-Cyclooctatetraene (COT) is an unsaturated derivative of cyclooctane, with the formula C8H8. It is also known as [8]annulene. This polyunsaturated hydrocarbon is a colorless to light yellow flammable liquid at room temperature. Because of its stoichiometric relationship to benzene, COT has been the subject of much research and some controversy.

Gold clusters in cluster chemistry can be either discrete molecules or larger colloidal particles. Both types are described as nanoparticles, with diameters of less than one micrometer. A nanocluster is a collective group made up of a specific number of atoms or molecules held together by some interaction mechanism. Gold nanoclusters have potential applications in optoelectronics and catalysis.

Metal aromaticity or metalloaromaticity is the concept of aromaticity, found in many organic compounds, extended to metals and metal-containing compounds. The first experimental evidence for the existence of aromaticity in metals was found in aluminium cluster compounds of the type MAl
4 where M stands for lithium, sodium or copper. These anions can be generated in a helium gas by laser vaporization of an aluminium / lithium carbonate composite or a copper or sodium / aluminium alloy, separated and selected by mass spectrometry and analyzed by photoelectron spectroscopy. The evidence for aromaticity in these compounds is based on several considerations. Computational chemistry shows that these aluminium clusters consist of a tetranuclear Al2−
4 plane and a counterion at the apex of a square pyramid. The Al2−
4 unit is perfectly planar and is not perturbed by the presence of the counterion or even the presence of two counterions in the neutral compound M
2Al
4. In addition its HOMO is calculated to be a doubly occupied delocalized pi system making it obey Hückel's rule. Finally a match exists between the calculated values and the experimental photoelectron values for the energy required to remove the first 4 valence electrons. The first fully metal aromatic compound was a cyclogallane with a Ga32- core discovered by Gregory Robinson in 1995.

In chemistry, π-effects or π-interactions are a type of non-covalent interaction that involves π systems. Just like in an electrostatic interaction where a region of negative charge interacts with a positive charge, the electron-rich π system can interact with a metal, an anion, another molecule and even another π system. Non-covalent interactions involving π systems are pivotal to biological events such as protein-ligand recognition.

<span class="mw-page-title-main">Lai-Sheng Wang</span> Chinese chemist

Lai-Sheng Wang is an experimental physical chemist currently serving as the Chair of the Chemistry Department at Brown University. Wang is known for his work on atomic gold pyramids and planar boron clusters.

<span class="mw-page-title-main">Borophene</span> Allotrope of boron

Borophene is a crystalline atomic monolayer of boron, i.e., it is a two-dimensional allotrope of boron and also known as boron sheet. First predicted by theory in the mid-1990s, different borophene structures were experimentally confirmed in 2015.

<span class="mw-page-title-main">Borospherene</span> Chemical compound

Borospherene (B40) is an electron-deficient cluster molecule containing 40 boron atoms. It bears similarities to other homoatomic cluster strucrures such as buckminsterfullerene (C60), stannaspherene, and plumbaspherene, but with a different symmetry. The first experimental evidence for borospherene was reported in July 2014, and is described in the journal Nature Chemistry. The molecule includes unusual hexagonal and heptagonal faces. Despite many calculation-based investigations into its structure and properties, a viable route for the synthesis and isolation of borospherene has yet to be established, and as a consequence it is still relatively poorly understood.

<span class="mw-page-title-main">Triboracyclopropenyl</span>

The triboracyclopropenyl fragment is a cyclic structural motif in boron chemistry, named for its geometric similarity to cyclopropene. In contrast to nonplanar borane clusters that exhibit higher coordination numbers at boron (e.g., through 3-center 2-electron bonds to bridging hydrides or cations), triboracyclopropenyl-type structures are rings of three boron atoms where substituents at each boron are also coplanar to the ring. Triboracyclopropenyl-containing compounds are extreme cases of inorganic aromaticity. They are the lightest and smallest cyclic structures known to display the bonding and magnetic properties that originate from fully delocalized electrons in orbitals of σ and π symmetry. Although three-membered rings of boron are frequently so highly strained as to be experimentally inaccessible, academic interest in their distinctive aromaticity and possible role as intermediates of borane pyrolysis motivated extensive computational studies by theoretical chemists. Beginning in the late 1980s with mass spectrometry work by Anderson et al. on all-boron clusters, experimental studies of triboracyclopropenyls were for decades exclusively limited to gas-phase investigations of the simplest rings (ions of B3). However, more recent work has stabilized the triboracyclopropenyl moiety via coordination to donor ligands or transition metals, dramatically expanding the scope of its chemistry.

<span class="mw-page-title-main">Nontrigonal pnictogen compounds</span>

Nontrigonal pnictogen compounds refer to tricoordinate trivalent pnictogen compounds that are not of typical trigonal pyramidal molecular geometry. By virtue of their geometric constraint, these compounds exhibit distinct electronic structures and reactivities, which bestow on them potential to provide unique nonmetal platforms for bond cleavage reactions.

<span class="mw-page-title-main">Metal cluster compound</span> Cluster of three or more metals

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<span class="mw-page-title-main">Hexaphosphabenzene</span> Chemical compound

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Anastassia N. Alexandrova is an American chemist who is a professor at the University of California, Los Angeles. Her research considers the computational design of functional materials.

<i>N</i>-Heterocyclic carbene boryl anion Isoelectronic structure

An N-heterocyclic carbene boryl anion is an isoelectronic structure of an N-heterocyclic carbene (NHC), where the carbene carbon is replaced with a boron atom that has a -1 charge. NHC boryl anions have a planar geometry, and the boron atom is considered to be sp2-hybridized. They serve as extremely strong bases, as they are very nucleophilic. They also have a very strong trans influence, due to the σ-donation coming from the boron atom. NHC boryl anions have stronger electron-releasing character when compared to normal NHCs. These characteristics make NHC boryl anions key ligands in many applications, such as polycyclic aromatic hydrocarbons, and more commonly low oxidation state main group element bonding.

Principal interacting orbital (PIO), based on quantum chemical calculations, provides chemists with visualization of a set of semi-localized dominant interacting orbitals. The method offers additional perspective to molecular orbitals (MO) obtained from quantum chemical calculations, which often provide extensively delocalized orbitals that are hard to interpret and relate with chemists' intuition on electronic structures and orbital interactions. Several other efforts have been made to help visualize semi-localized dominant interacting orbitals that represents well chemists' intuition, while maintaining the mathematical rigorosity. Notable examples include the natural atomic orbitals (NAO), natural bond orbitals (NBO), charge decomposition analysis (CDA), and adaptive natural density partitioning (AdNDP). PIO analysis uniquely provides semi-localized MOs that are chemically accurate and easy to interpret.

<span class="mw-page-title-main">Aurosilane</span> Chemical compound

Aurosilane is an inorganic compound with a chemical formula of SiAu4. In this compound, gold acts as an electron acceptor with a valence of -1. Aurosilane has been isolated as a type of gold silane. Its unit cell parameters are a=5.658, c=5.605 A. The LUMO and the four Si-Au bonding orbitals of SiAu4 are similar to those of SiH4.

References

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  2. 1 2 Boldyrev, Alexander I. (2021-10-28). "An Autobiographical History of Alexander I. Boldyrev". The Journal of Physical Chemistry A. 125 (42): 9264–9266. Bibcode:2021JPCA..125.9264B. doi:10.1021/acs.jpca.1c08111. ISSN   1089-5639. PMID   34706545. S2CID   240073720.
  3. 1 2 3 4 University, Utah State (2021-11-02). "USU Chemist Alexander Boldyrev Recognized with Prestigious 'Festschrift' Tribute". Utah State Today. Retrieved 2021-12-13.
  4. 1 2 Li, Xi; Wang, Lai-Sheng; Boldyrev, Alexander I.; Simons, Jack (1999-06-01). "Tetracoordinated Planar Carbon in the Al 4 C - Anion. A Combined Photoelectron Spectroscopy and ab Initio Study". Journal of the American Chemical Society. 121 (25): 6033–6038. doi:10.1021/ja9906204. ISSN   0002-7863.
  5. 1 2 Gutsev, G.L.; Boldyrev, A.I. (April 1981). "DVM-Xα calculations on the ionization potentials of MXk+1− complex anions and the electron affinities of MXk+1 "superhalogens"". Chemical Physics. 56 (3): 277–283. doi:10.1016/0301-0104(81)80150-4.
  6. 1 2 Gutsev, G.L.; Boldyrev, A.I. (October 1982). "DVM Xα calculations on the electronic structure of "superalkali" cations". Chemical Physics Letters. 92 (3): 262–266. Bibcode:1982CPL....92..262G. doi:10.1016/0009-2614(82)80272-8.
  7. Galeev, Timur R.; Romanescu, Constantin; Li, Wei-Li; Wang, Lai-Sheng; Boldyrev, Alexander I. (2012-02-27). "Observation of the Highest Coordination Number in Planar Species: Decacoordinated Ta©B10− and Nb©B10− Anions". Angewandte Chemie. 124 (9): 2143–2147. Bibcode:2012AngCh.124.2143G. doi:10.1002/ange.201107880.
  8. 1 2 Zubarev, Dmitry Yu.; Boldyrev, Alexander I. (2008). "Developing paradigms of chemical bonding: adaptive natural density partitioning". Physical Chemistry Chemical Physics. 10 (34): 5207–5217. Bibcode:2008PCCP...10.5207Z. doi:10.1039/b804083d. ISSN   1463-9076. PMID   18728862.
  9. Tkachenko, Nikolay V.; Boldyrev, Alexander I. (2019). "Chemical bonding analysis of excited states using the adaptive natural density partitioning method". Physical Chemistry Chemical Physics. 21 (18): 9590–9596. Bibcode:2019PCCP...21.9590T. doi:10.1039/c9cp00379g. ISSN   1463-9076. PMID   31020963. S2CID   131777283.
  10. Galeev, Timur R.; Dunnington, Benjamin D.; Schmidt, J. R.; Boldyrev, Alexander I. (2013). "Solid state adaptive natural density partitioning: a tool for deciphering multi-center bonding in periodic systems". Physical Chemistry Chemical Physics. 15 (14): 5022–5029. Bibcode:2013PCCP...15.5022G. doi:10.1039/c3cp50350j. ISSN   1463-9076. PMID   23443061.
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  12. Muffoletto, Mary-Ann (25 January 2022). "PIO". usu.edu. Utah State University. Retrieved 26 January 2022.
  13. Li, Xi; Kuznetsov, Aleksey E.; Zhang, Hai-Feng; Boldyrev, Alexander I.; Wang, Lai-Sheng (2001-02-02). "Observation of All-Metal Aromatic Molecules". Science. 291 (5505): 859–861. Bibcode:2001Sci...291..859L. doi:10.1126/science.291.5505.859. ISSN   0036-8075. PMID   11157162.
  14. Kuznetsov, Aleksey E.; Birch, K. Alexander; Boldyrev, Alexander I.; Li, Xi; Zhai, Hua-Jin; Wang, Lai-Sheng (2003-04-25). "All-Metal Antiaromatic Molecule: Rectangular Al 4 4- in the Li 3 Al 4 - Anion". Science. 300 (5619): 622–625. doi:10.1126/science.1082477. ISSN   0036-8075. PMID   12714740. S2CID   14941291.
  15. Zhai, Hua-Jin; Alexandrova, Anastassia N.; Birch, K. Alexander; Boldyrev, Alexander I.; Wang, Lai-Sheng (2003-12-15). "Hepta- and Octacoordinate Boron in Molecular Wheels of Eight- and Nine-Atom Boron Clusters: Observation and Confirmation". Angewandte Chemie International Edition. 42 (48): 6004–6008. doi: 10.1002/anie.200351874 . ISSN   1433-7851. PMID   14679555.
  16. Zubarev, Dmitry Yu.; Boldyrev, Alexander I. (2008). "Developing paradigms of chemical bonding: adaptive natural density partitioning". Physical Chemistry Chemical Physics. 10 (34): 5207–5217. Bibcode:2008PCCP...10.5207Z. doi:10.1039/b804083d. ISSN   1463-9076. PMID   18728862.
  17. Huang, Wei; Sergeeva, Alina P.; Zhai, Hua-Jin; Averkiev, Boris B.; Wang, Lai-Sheng; Boldyrev, Alexander I. (March 2010). "A concentric planar doubly π-aromatic B19− cluster". Nature Chemistry. 2 (3): 202–206. Bibcode:2010NatCh...2..202H. doi:10.1038/nchem.534. ISSN   1755-4330. PMID   21124477.
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