Your search keyword '"Nickolas H. Anderson"' showing total 21 results

1. Chlorination of Pu and U Metal Using GaCl3

Author

Stephanie H. Carpenter, Bonnie E. Klamm, Taylor V. Fetrow, Brian L. Scott, Andrew J. Gaunt, Nickolas H. Anderson, and Aaron M. Tondreau

Subjects

Inorganic Chemistry, Physical and Theoretical Chemistry

Published

2023

2. Using molten salts to probe outer-coordination sphere effects on lanthanide(<scp>iii</scp>)/(<scp>ii</scp>) electron-transfer reactions

Author

Kristen A. Pace, Stosh A. Kozimor, Veronika Mocko, Ping Yang, Jennifer N. Wacker, Francisca R. Rocha, Cecilia Eiroa-Lledo, Molly M. MacInnes, Karah E. Knope, Nickolas H. Anderson, Enrique R. Batista, Ida M. DiMucci, Zachary R. Jones, Bo Li, Maksim Y. Livshits, and Benjamin W. Stein

Subjects

Inorganic Chemistry, Metal, Lanthanide, Coordination sphere, Absorption spectroscopy, Oxidation state, Chemistry, visual_art, visual_art.visual_art_medium, Physical chemistry, Molten salt, Redox, Ion

Abstract

Controlling structure and reactivity by manipulating the outer-coordination sphere around a given reagent represents a longstanding challenge in chemistry. Despite advances toward solving this problem, it remains difficult to experimentally interrogate and characterize outer-coordination sphere impact. This work describes an alternative approach that quantifies outer-coordination sphere effects. It shows how molten salt metal chlorides (MCln; M = K, Na, n = 1; M = Ca, n = 2) provided excellent platforms for experimentally characterizing the influence of the outer-coordination sphere cations (Mn+) on redox reactions accessible to lanthanide ions; Ln3+ + e1− → Ln2+ (Ln = Eu, Yb, Sm; e1− = electron). As a representative example, X-ray absorption spectroscopy and cyclic voltammetry results showed that Eu2+ instantaneously formed when Eu3+ dissolved in molten chloride salts that had strongly polarizing cations (like Ca2+ from CaCl2) via the Eu3+ + Cl1− → Eu2+ + ½Cl2 reaction. Conversely, molten salts with less polarizing outer-sphere M1+ cations (e.g., K1+ in KCl) stabilized Ln3+. For instance, the Eu3+/Eu2+ reduction potential was >0.5 V more positive in CaCl2 than in KCl. In accordance with first-principle molecular dynamics (FPMD) simulations, we postulated that hard Mn+ cations (high polarization power) inductively removed electron density from Lnn+ across Ln–Cl⋯Mn+ networks and stabilized electron-rich and low oxidation state Ln2+ ions. Conversely, less polarizing Mn+ cations (like K1+) left electron density on Lnn+ and stabilized electron-deficient and high-oxidation state Ln3+ ions.

Published

2021

3. Origin of Bond Elongation in a Uranium(IV) cis-Bis(imido) Complex

Author

María J. Beltrán-Leiva, Matthias Zeller, Nickolas H. Anderson, Suzanne C. Bart, Tyler S. Collins, Thomas E. Albrecht-Schönzart, and Cristian Celis-Barros

Subjects

Steric effects, chemistry.chemical_element, Uranium, Antibonding molecular orbital, Uranyl, Ion, Inorganic Chemistry, chemistry.chemical_compound, Crystallography, chemistry, Amide, Proton NMR, Physical and Theoretical Chemistry, Tetrahydrofuran

Abstract

The activation of U-N multiple bonds in an imido analogue of the uranyl ion is accomplished by using a system that is very electron-rich with sterically encumbering ligands. Treating the uranium(VI) trans-bis(imido) UI2(NDIPP)2(THF)3 (DIPP = 2,6-diisopropylphenyl and THF = tetrahydrofuran) with tert-butyl(dimethylsilyl)amide (NTSA) results in a reduction and rearrangement to form the uranium(IV) cis-bis(imido) [U(NDIPP)2(NTSA)2]K2 (1). Compound 1 features long U-N bonds, pointing toward substantial activation of the N═U═N unit, as determined by X-ray crystallography and 1H NMR, IR, and electronic absorption spectroscopies. Computational analyses show that uranium(IV)-imido bonds in 1 are significantly weakened multiple bonds due to polarization toward antibonding and nonbonding orbitals. Such geometric control has important effects on the electronic structures of these species, which could be useful in the recycling of spent nuclear fuels.

Published

2020

4. A Solid-State Support for Separating Astatine-211 from Bismuth

Author

Eva R. Birnbaum, Yawen Li, Andrew C. Akin, David H. Woen, Kevin T. Bennett, Donald K. Hamlin, Veronika Mocko, Eric Dorman, D. Scott Wilbur, Stosh A. Kozimor, Nickolas H. Anderson, Frankie D. White, Elodie Dalodière, Cecilia Eiroa-Lledo, Mark Brugh, Laura M. Lilley, Sara L. Thiemann, Maryline G. Ferrier, and Anastasia V. Blake

Subjects

Inorganic Chemistry, chemistry, Radiochemistry, Solid-state, chemistry.chemical_element, Physical and Theoretical Chemistry, Astatine, Bismuth

Abstract

Increasing access to the short-lived α-emitting radionuclide astatine-211 (211At) has the potential to advance targeted α-therapeutic treatment of disease and to solve challenges facing the medical...

Published

2020

5. Isolation and characterization of a californium metallocene

Author

William J. Evans, Conrad A. P. Goodwin, Joseph M. Sperling, Thomas E. Albrecht-Schönzart, Jing Su, Stosh A. Kozimor, Lauren M. Stevens, Justin C. Wedal, Ping Yang, Frankie D. White, Zachary R. Jones, Sasha F. Briscoe, Alyssa N. Gaiser, Cory J. Windorff, Enrique R. Batista, Andrew J. Gaunt, Joseph W. Ziller, Brian L. Scott, Nickolas H. Anderson, Michael R. James, John D. Auxier, Justin N. Cross, Tener F. Jenkins, and Michael T. Janicke

Subjects

chemistry.chemical_compound, Crystallography, Multidisciplinary, Valence (chemistry), chemistry, Chemical bond, Bent metallocene, chemistry.chemical_element, Molecule, Ionic bonding, Californium, Isostructural, Organometallic chemistry

Abstract

Californium (Cf) is currently the heaviest element accessible above microgram quantities. Cf isotopes impose severe experimental challenges due to their scarcity and radiological hazards. Consequently, chemical secrets ranging from the accessibility of 5f/6d valence orbitals to engage in bonding, the role of spin–orbit coupling in electronic structure, and reactivity patterns compared to other f elements, remain locked. Organometallic molecules were foundational in elucidating periodicity and bonding trends across the periodic table1–3, with a twenty-first-century renaissance of organometallic thorium (Th) through plutonium (Pu) chemistry4–12, and to a smaller extent americium (Am)13, transforming chemical understanding. Yet, analogous curium (Cm) to Cf chemistry has lain dormant since the 1970s. Here, we revive air-/moisture-sensitive Cf chemistry through the synthesis and characterization of [Cf(C5Me4H)2Cl2K(OEt2)]n from two milligrams of 249Cf. This bent metallocene motif, not previously structurally authenticated beyond uranium (U)14,15, contains the first crystallographically characterized Cf–C bond. Analysis suggests the Cf–C bond is largely ionic with a small covalent contribution. Lowered Cf 5f orbital energy versus dysprosium (Dy) 4f in the colourless, isoelectronic and isostructural [Dy(C5Me4H)2Cl2K(OEt2)]n results in an orange Cf compound, contrasting with the light-green colour typically associated with Cf compounds16–22.

Published

2021

6. (Invited, Digital Presentation) Tuning the Electrodeposition of Actinides in Molten Alkali Halide Salts

Author

Molly M MacInnes, Kristen A Pace, Ida M DiMucci, Nickolas H Anderson, Benjamin W Stein, Stosh Kozimor, Francisca R Rocha, Zachary R Jones, Veronika Mocko, Enrique R Batista, Cecilia Eiroa-Lledo, Maksim Y Livshits, Jennifer N Wacker, Karah E Knope, and Ping Yang

Abstract

Molten salts have found use as solvents in numerous applications including nuclear reactors, batteries, and the extraction and purification of various metals. Unfortunately, understanding of the chemistry of molten salt solutions is limited. In this presentation we explore the use of molten salts as a testbed for understanding both outer and inner coordination sphere effects on dissolved metal ions. The electron transfer reactions available to lanthanides (Eu3+, Sm3+, and Yb3+) and actinides (U3+, U4+, and Th4+) were explored in a series of alkali and alkaline earth halide salts. We present electrochemical data that demonstrate significant shifts in the reduction potentials of these metal ions as a function of the anion and cation identities of the molten salt solvent. We hypothesize that effects on the reduction potential of these metals come from two sources: (1) the primary coordination sphere and (2) the secondary coordination sphere. The influence from the primary coordination sphere is dominated by the degree of covalency in the coordination bonds between the Lnn+ and Ann+ cations and the molten salt anions. The influence of the secondary coordination sphere is dominated by the electron-withdrawing character of the salt cations. EXAFS data and computational results that support these hypotheses are presented. Further, we provide insight into electrodeposition of the An0 metals under these conditions and highlight temperature and molten salt effects that influence these electrodepositions. Specifically, we propose that increased mobility of solid-state atoms at high temperature (> 800°C) influence the properties of electrodeposited metals.

Published

2022

7. Origin of Bond Elongation in a Uranium(IV)

Author

Tyler S, Collins, Cristian, Celis-Barros, María J, Beltrán-Leiva, Nickolas H, Anderson, Matthias, Zeller, Thomas, Albrecht-Schönzart, and Suzanne C, Bart

Abstract

The activation of U-N multiple bonds in an imido analogue of the uranyl ion is accomplished by using a system that is very electron-rich with sterically encumbering ligands. Treating the uranium(VI)

Published

2020

8. Oxidation of uranium(<scp>iv</scp>) mixed imido–amido complexes with PhEEPh and to generate uranium(<scp>vi</scp>) bis(imido) dichalcogenolates, U(NR)2(EPh)2(L)2

Author

James M. Boncella, Neil C. Tomson, Brian L. Scott, Aaron M. Tondreau, and Nickolas H. Anderson

Subjects

010405 organic chemistry, Ligand, Erythropoietin-producing hepatocellular (Eph) receptor, chemistry.chemical_element, Uranium, 010402 general chemistry, Uranyl, 01 natural sciences, Medicinal chemistry, 0104 chemical sciences, Inorganic Chemistry, chemistry.chemical_compound, chemistry, Salt metathesis reaction

Abstract

This work provides new routes for the conversion of U(iv) into U(vi) bis(imido) complexes and offers new information on the manner in which the U(vi) compounds form. Many compounds from the series described by the general formula U(NR)2(EPh)2(L)2 (R = 2,6-diisopropylphenyl, tert-butyl; E = S, Se, Te; L = py, EPh) were synthesized via oxidation of an in situ generated U(iv) amido-imido species with Ph2E2. This synthetic sequence provides a general route into bis(imido) U(vi) chalcogenolate complexes, circumventing the need to perform problematic salt metathesis reactions on U(vi) iodides. Investigation into the speciation of the U(iv) complexes that form prior to oxidation found a significant dependence on the identity of the ancillary ligands, with tBu2bpy forming the isolable imido-(bis)amido complex, U(NDipp)(NHDipp)2(tBu2bpy)2. Together, these data are consistent with the view that the bis(imido) U(vi) motif - much like the uranyl ion, UO22+- is a thermodynamic sink into which simple ligand frameworks are unable to prevent uranium from falling when in the presence of a suitable retinue of imido proligands.

Published

2019

9. Investigation of Nitrile Hydration Chemistry by Two Transition Metal Hydroxide Complexes: Mn–OH and Ni–OH Nitrile Insertion Chemistry

Author

James M. Boncella, Nickolas H. Anderson, and Aaron M. Tondreau

Subjects

Nitrile, 010405 organic chemistry, Chemistry, Organic Chemistry, chemistry.chemical_element, 010402 general chemistry, 01 natural sciences, Medicinal chemistry, 0104 chemical sciences, Catalysis, Inorganic Chemistry, chemistry.chemical_compound, Nickel, Transition metal, Moiety, Hydroxide, Reactivity (chemistry), Physical and Theoretical Chemistry, Phosphine

Abstract

Herein we describe the synthesis of a series of nickel complexes, including the formation of [(iPrPNHP)Ni(PMe3)][BPh4] (iPrPNHP = HN(CH2CH2(PiPr2))2). The ability of this phosphine complex to perform the 1,2-addition of H2O to produce the Ni–OH species [(iPrPNHP)NiOH][BPh4] has been investigated. The nucleophilicity of the hydroxide moiety of both [(iPrPNHP)NiOH][BPh4] and the previously reported (iPrPNHP)MnOH(CO)2 was investigated through the hydration of aryl and alkyl nitriles, leading to the formation of a number of metal carboxamide (RC(O)NH–) bonds. This reactivity generated complexes with the general structures of [(iPrPNHP)Ni(NHC(O)R)][BPh4] for nickel and (iPrPNHP)Mn(NHC(O)R)(CO)2 for manganese. Under catalytic conditions, the hydration of nitriles using nickel complexes yielded only a single turnover. However, (iPrPNHP)MnOH(CO)2 produced several turnovers, and the reaction conditions were probed for optimization.

Published

2018

10. Non-aqueous neptunium and plutonium redox behaviour in THF – access to a rare Np(<scp>iii</scp>) synthetic precursor

Author

Scott A. Pattenaude, Brian L. Scott, Andrew J. Gaunt, Suzanne C. Bart, and Nickolas H. Anderson

Subjects

Aqueous solution, 010405 organic chemistry, Chemistry, Neptunium, Metals and Alloys, chemistry.chemical_element, Halide, General Chemistry, Radiation chemistry, 010402 general chemistry, 01 natural sciences, Redox, Medicinal chemistry, Catalysis, 0104 chemical sciences, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Metal, Solvent, visual_art, Yield (chemistry), Materials Chemistry, Ceramics and Composites, visual_art.visual_art_medium

Abstract

Solvent exchange of NpCl4(DME)2 with THF proceeds simply to yield NpCl4(THF)3, whereas PuCl4(DME)2 is unstable in THF, partially decomposing to the mixed valent [PuIIICl2(THF)5][PuIVCl5(THF)] salt. Reduction of NpCl4(THF)3 with CsC8 ultimately afforded NpCl3(py)4, the only example of a structurally characterized solvated Np(iii) halide. The method demonstrates a route to a well-defined Np(iii) starting material without the need to employ scarcely available Np metal.

Published

2018

11. Reactivity of Silanes with ( t Bu PONOP)Ruthenium Dichloride: Facile Synthesis of Chloro-Silyl Ruthenium Compounds and Formic Acid Decomposition

Author

James M. Boncella, Nickolas H. Anderson, and Aaron M. Tondreau

Subjects

010405 organic chemistry, Organic Chemistry, chemistry.chemical_element, General Chemistry, 010402 general chemistry, Metathesis, 01 natural sciences, Medicinal chemistry, Catalysis, 0104 chemical sciences, Ruthenium, chemistry.chemical_compound, chemistry, Phenylsilane, Pyridine, Organic chemistry, Reactivity (chemistry), Triethylsilane, Triethylamine, Trifluoromethanesulfonate

Abstract

The coordination of tBu PONOP (tBu PONOP=2,6-bis(ditert-butylphosphinito)pyridine) to different ruthenium starting materials, to generate (tBu PONOP)RuCl2 , was investigated. The resultant (tBu PONOP)RuCl2 reactivity with three different silanes was then investigated and contrasted dramatically with the reactivity of (iPr PONOP)RuCl2 (DMSO) (iPr PONOP=2,6-bis(diisopropylphosphinito)pyridine) with the same silanes. The 16-electron species (tBu PONOP)Ru(H)Cl was produced from the reaction of triethylsilane with (tBu PONOP)RuCl2 . Reactions of (tBu PONOP)RuCl2 with both phenylsilane or diphenylsilane afforded the 16-electron hydrido-silyl species (tBu PONOP)Ru(H)(PhSiCl2 ) and (tBu PONOP)Ru(H)(Ph2 SiCl), respectively. Reactions of all three of these complexes with silver triflate afforded the simple salt metathesis products of (tBu PONOP)Ru(H)(OTf), (tBu PONOP)Ru(H)(PhSiCl(OTf)), and (tBu PONOP)Ru(H)(Ph2 Si(OTf)). Formic acid dehydrogenation was performed in the presence of triethylamine (TEA), and each species proved competent for gas-pressure generation of CO2 and H2 . The hydride species (tBu PONOP)Ru(H)Cl, (tBu PONOP)Ru(H)(OTf), and (tBu PONOP)Ru(H)(PhSiCl2 ) exhibited faster catalytic activity than the other compounds tested.

Published

2017

12. Elucidating bonding preferences in tetrakis(imido)uranate(VI) dianions

Author

Matthias Zeller, Laura Gagliardi, Suzanne C. Bart, Nickolas H. Anderson, Debmalya Ray, and Jing Xie

Subjects

Steric effects, 010405 organic chemistry, Trans effect, General Chemical Engineering, chemistry.chemical_element, General Chemistry, Uranium, 010402 general chemistry, Uranyl, Photochemistry, 01 natural sciences, Multiple bonds, 0104 chemical sciences, chemistry.chemical_compound, Crystallography, Chemical bond, chemistry, Moiety, Uranate

Abstract

Actinyl species, [AnO2]2+, are well-known derivatives of the f-block because of their natural occurrence and essential roles in the nuclear fuel cycle. Along with their nitrogen analogues, [An(NR)2]2+, actinyls are characterized by their two strong trans-An–element multiple bonds, a consequence of the inverse trans influence. We report that these robust bonds can be weakened significantly by increasing the number of multiple bonds to uranium, as demonstrated by a family of uranium(VI) dianions bearing four U–N multiple bonds, [M]2[U(NR)4] (M = Li, Na, K, Rb, Cs). Their geometry is dictated by cation coordination and sterics rather than by electronic factors. Multiple bond weakening by the addition of strong π donors has the potential for applications in the processing of high-valent actinyls, commonly found in environmental pollutants and spent nuclear fuels. The field of high-valent uranium chemistry has been dominated by the linear uranyl moiety [UO2]2+ and its imido analogues. A family of tetrakis(imido)uranate dianions has now been developed that displays four uranium–nitrogen multiple bonds. Their geometry is dictated by cation coordination and steric factors rather than electronic ones.

Published

2017

13. Oxidation of uranium(iv) mixed imido-amido complexes with PhEEPh and to generate uranium(vi) bis(imido) dichalcogenolates, U(NR)

Author

Neil C, Tomson, Nickolas H, Anderson, Aaron M, Tondreau, Brian L, Scott, and James M, Boncella

Abstract

This work provides new routes for the conversion of U(iv) into U(vi) bis(imido) complexes and offers new information on the manner in which the U(vi) compounds form. Many compounds from the series described by the general formula U(NR)

Published

2019

14. Manganese-Mediated Formic Acid Dehydrogenation

Author

Aaron M. Tondreau, James M. Boncella, and Nickolas H. Anderson

Subjects

010405 organic chemistry, Formic acid, Ligand, Organic Chemistry, chemistry.chemical_element, General Chemistry, Manganese, engineering.material, 010402 general chemistry, 01 natural sciences, Medicinal chemistry, Catalysis, 0104 chemical sciences, chemistry.chemical_compound, chemistry, Pyridine, Dehydrohalogenation, engineering, Dehydrogenation, Noble metal

Abstract

A robust and rapid manganese formic acid (FA) dehydrogenation catalyst is reported. The manganese is supported by the recently developed, hybrid backbone chelate ligand tBu PNNOP (tBu PNNOP=2,6-(di-tert-butylphosphinito)(di-tert-butylphosphinamine)pyridine) (1) and the catalyst is readily prepared with MnBrCO5 to form [(tBu PNNOP)Mn(CO)2 ][Br] (2). Dehydrohalogenation of 2 generated the neutral five coordinate complex (tBu PNNOP)Mn(CO)2 (3). Dehydrogenation of FA by 2 and 3 was found to be highly efficient, exhibiting turnover frequencies (TOFs) exceeding 8500 h-1 , rivaling many noble metal systems. The parent chelate, tBu PONOP (tBu PONOP=2,6-bis(di-tert-butylphosphinito)pyridine) or tBu PNNNP (tBu PNNNP=2,6-bis (di-tert-butylphosphinamine)pyridine), coordination complexes of Mn were synthesized, respectively affording [(tBu PONOP)Mn(CO)2 ][Br] (4) and [(tBu PNNNP)Mn(CO)2 ][Br] (5). FA dehydrogenation with the hybrid-ligand supported 2 exhibits superior catalysis to 4 and 5.

Published

2019

15. Radical Reductive Elimination from Tetrabenzyluranium Mediated by an Iminoquinone Ligand

Author

Sebastian M. Franke, Ellen M. Matson, Nickolas H. Anderson, Phillip E. Fanwick, Suzanne C. Bart, and Timothy D. Cook

Subjects

Tris, Ligand, Organic Chemistry, Alkylation, Medicinal chemistry, Reductive elimination, Quinone, Inorganic Chemistry, chemistry.chemical_compound, chemistry, Crossover experiment, Oxidation state, Bibenzyl, Physical and Theoretical Chemistry

Abstract

Reductive elimination from U(CH2Ph)4 (1-Ph) mediated by 4,6-di-tert-butyl-2-[(2,6-diisopropylphenyl)imino]quinone (dippiq) was observed, resulting in the formation of (dippap)2U(CH2Ph)2(THF)2 (2) (dippap = 4,6-di-tert-butyl-2-[(2,6-diisopropylphenyl)amido]phenolate) and bibenzyl. The crossover experiment with U(CD2C6D5)4 showed formation of bibenzyl-d7, indicating that reductive elimination occurs in a stepwise fashion via benzyl radical extrusion, presumably through an iminosemiquinone tris(benzyl) intermediate, (dippisq)U(CH2Ph)3. Synthesis of this intermediate was attempted by addition of the iminoquinone ligand to UI3(THF)4 to form (dippisq)UI3 (3), followed by alkylation with 3 equiv of benzylpotassium. However, this only resulted in the isolation of 2. Reduction of 3 with KC8 afforded the amidophenolate diiodide species (dippap)UI2(THF)2 (4), maintaining the tetravalent oxidation state of the uranium and reducing the ligand. Attempts at the formation of 2 via addition of 2 equiv of benzylpotassium t...

Published

2014

16. Cover Feature: Manganese‐Mediated Formic Acid Dehydrogenation (Chem. Eur. J. 45/2019)

Author

Aaron M. Tondreau, Nickolas H. Anderson, and James M. Boncella

Subjects

chemistry.chemical_compound, chemistry, Formic acid, Feature (computer vision), Organic Chemistry, Organic chemistry, chemistry.chemical_element, Cover (algebra), Dehydrogenation, General Chemistry, Manganese, Catalysis

Published

2019

17. Investigation of Uranium Tris(imido) Complexes: Synthesis, Characterization, and Reduction Chemistry of [U(NDIPP)3(thf)3]

Author

Phillip E. Fanwick, Suzanne C. Bart, Haolin Yin, Nickolas H. Anderson, John J. Kiernicki, and Eric J. Schelter

Subjects

Tris, Inorganic chemistry, chemistry.chemical_element, General Chemistry, Crystal structure, Uranium, Catalysis, chemistry.chemical_compound, Crystallography, Magnetization, chemistry, Octahedron, Proton NMR, Absorption (chemistry), Spectroscopy

Abstract

Addition of KC8 to trivalent [UI3(thf)4] in the presence of three equivalents of 2,6-diisopropylphenylazide (N3DIPP) results in the formation of the hexavalent uranium tris(imido) complex [U(NDIPP)3(thf)3] (1) through a facile, single-step synthesis. The X-ray crystal structure shows an octahedral complex that adopts a facial orientation of the imido substituents. This structural trend is maintained during the single-electron reduction of 1 to form dimeric [U(NDIPP)3{K(Et2O)}]2 (2). Variable-temperature/field magnetization studies of 2 show two independent U(V) 5f (1) centers, with no antiferromagnetic coupling present. Characterization of these complexes was accomplished using single-crystal X-ray diffraction, variable-temperature (1)H NMR spectroscopy, as well as IR and UV/Vis absorption spectroscopic studies.

Published

2015

18. Investigation of the electronic ground states for a reduced pyridine(diimine) uranium series: evidence for a ligand tetraanion stabilized by a uranium dimer

Author

Andrew J. Lewis, Samuel O. Odoh, Laura Gagliardi, Suzanne C. Bart, Gregory L. Wagner, Juan S. Lezama Pacheco, Nickolas H. Anderson, Stosh A. Kozimor, Ursula J. Williams, and Eric J. Schelter

Subjects

Models, Molecular, Stereochemistry, Pyridines, Dimer, Molecular Conformation, chemistry.chemical_element, Electrons, Ligands, Biochemistry, Catalysis, chemistry.chemical_compound, Colloid and Surface Chemistry, Pyridine, Organometallic Compounds, Singlet state, Diimine, Diradical, Chemistry, Ligand, Magnetic Phenomena, General Chemistry, Uranium, Crystallography, Monomer, Quantum Theory, Dimerization, Oxidation-Reduction

Abstract

The electronic structures of a series of highly reduced uranium complexes bearing the redox-active pyridine(diimine) ligand, (Mes)PDI(Me) ((Mes)PDI(Me) = 2,6-(2,4,6-Me3-C6H2-N═CMe)2C5H3N) have been investigated. The complexes, ((Mes)PDI(Me))UI3(THF) (1), ((Mes)PDI(Me))UI2(THF)2 (2), [((Mes)PDI(Me))UI]2 (3), and [((Mes)PDI(Me))U(THF)]2 (4), were examined using electronic and X-ray absorption spectroscopies, magnetometry, and computational analyses. Taken together, these studies suggest that all members of the series contain uranium(IV) centers with 5f (2) configurations and reduced ligand frameworks, specifically [(Mes)PDI(Me)](•/-), [(Mes)PDI(Me)](2-), [(Mes)PDI(Me)](3-) and [(Mes)PDI(Me)](4-), respectively. In the cases of 2, 3, and 4 no unpaired spin density was found on the ligands, indicating a singlet diradical ligand in monomeric 2 and ligand electron spin-pairing through dimerization in 3 and 4. Interaction energies, representing enthalpies of dimerization, of -116.0 and -144.4 kcal mol(-1) were calculated using DFT for the monomers of 3 and 4, respectively, showing there is a large stabilization gained by dimerization through uranium-arene bonds. Highlighted in these studies is compound 4, bearing a previously unobserved pyridine(diimine) tetraanion, that was uniquely stabilized by backbonding between uranium cations and the η(5)-pyridyl ring.

Published

2015

19. Isolation of a uranium(III) benzophenone ketyl radical that displays redox-active ligand behaviour

Author

Nickolas H. Anderson, Phillip E. Fanwick, Ellen M. Matson, Suzanne C. Bart, and John J. Kiernicki

Subjects

Chemistry, Infrared, Ligand, chemistry.chemical_element, Uranium, Photochemistry, Inorganic Chemistry, Metal, chemistry.chemical_compound, Ketyl, visual_art, Benzophenone, Proton NMR, visual_art.visual_art_medium, Absorption (chemistry)

Abstract

The first uranium(III) charge separated ketyl radical complex, Tp*2U(OC·Ph2), has been isolated and characterized by infrared, (1)H NMR, and electronic absorption spectroscopies, along with X-ray crystallography. Tp*2U(OC·Ph2) is a potent two-electron reductant towards N3Mes (Mes = 2,4,6-trimethylphenyl) and (2,2,6,6-tetramethyl-piperidin-1-yl)oxyl (TEMPO), with reducing equivalents derived from the metal centre and the redox-active benzophenone.

Published

2014

20. Multielectron C-O bond activation mediated by a family of reduced uranium complexes

Author

Suzanne C. Bart, Nickolas H. Anderson, John J. Kiernicki, Ellen M. Matson, Phillip E. Fanwick, Matthew P. Shores, and Brian S. Newell

Subjects

Chemistry, Ligand, Stereochemistry, chemistry.chemical_element, Uranium, Medicinal chemistry, Inorganic Chemistry, Benzaldehyde, chemistry.chemical_compound, Cyclopentadienyl complex, Oxidation state, Pyridine, Benzophenone, Physical and Theoretical Chemistry, Diimine

Abstract

A family of cyclopentadienyl uranium complexes supported by the redox-active pyridine(diimine) ligand, (Mes)PDI(Me) ((Mes)PDI(Me) = 2,6-((Mes)N═CMe)2-C5H3N, Mes = 2,4,6-trimethylphenyl), has been synthesized. Using either Cp* or Cp(P) (Cp* = 1,2,3,4,5-pentamethylcyclopentadienide, Cp(P) = 1-(7,7-dimethylbenzyl)cyclopentadienide), uranium complexes of the type Cp(X)UI2((Mes)PDI(Me)) (1-Cp(X); X = * or P), Cp(X)UI((Mes)PDI(Me)) (2-Cp(X)), and Cp(X)U((Mes)PDI(Me))(THF)n (3-Cp(X); *, n = 1; P, n = 0) were isolated and characterized. The series was generated via ligand centered reduction events; thus the extent of (Mes)PDI(Me) reduction varies in each case, but the uranium(IV) oxidation state is maintained. Treating 2-Cp(X), which has a doubly reduced (Mes)PDI(Me), with furfural results in radical coupling between the substrate and (Mes)PDI(Me), leading to C-C bond formation to form Cp(X)UI((Mes)PDI(Me)-CHOC4H3O) (4-Cp(X)). Exposure of 3-Cp* and 3-Cp(P), which contain a triply reduced (Mes)PDI(Me) ligand, to benzaldehyde and benzophenone, respectively, results in the corresponding pinacolate complexes Cp*U(O2C2Ph2H2)((Mes)PDI(Me)) (5-Cp*) and Cp(P)U(O2C2Ph4)((Mes)PDI(Me)) (5-Cp(P)). The reducing equivalents required for this coupling are derived solely from the redox-active ligand, rather than the uranium center. Complexes 1-5 have been characterized by (1)H NMR and electronic absorption spectroscopies, and SQUID magnetometry was employed to confirm the mono(anionic) [(Mes)PDI(Me)](-) ligand in 1-Cp(P) and 5-Cp(P). Structural parameters of complexes 1-Cp(P), 2-Cp(X), 4-Cp*, and 5-Cp(X) have been elucidated by X-ray crystallography.

Published

2014

21. Harnessing redox activity for the formation of uranium tris(imido) compounds

Author

John J. Kiernicki, Laura Gagliardi, Ursula J. Williams, Yiyi Yao, Phillip E. Fanwick, Suzanne C. Bart, Samuel O. Odoh, Andrew J. Lewis, Nickolas H. Anderson, Justin R. Walensky, Brian A. Schaefer, Eric J. Schelter, and Mitchell D. Goshert

Subjects

inorganic chemicals, chemistry.chemical_classification, Ligand, General Chemical Engineering, Inorganic chemistry, chemistry.chemical_element, General Chemistry, Uranium, Coordination complex, chemistry.chemical_compound, chemistry, Oxidation state, Pyridine, Polymer chemistry, Reactivity (chemistry), Diimine, Group 2 organometallic chemistry

Abstract

Classically, late transition-metal organometallic compounds promote multielectron processes solely through the change in oxidation state of the metal centre. In contrast, uranium typically undergoes single-electron chemistry. However, using redox-active ligands can engage multielectron reactivity at this metal in analogy to transition metals. Here we show that a redox-flexible pyridine(diimine) ligand can stabilize a series of highly reduced uranium coordination complexes by storing one, two or three electrons in the ligand. These species reduce organoazides easily to form uranium-nitrogen multiple bonds with the release of dinitrogen. The extent of ligand reduction dictates the formation of uranium mono-, bis- and tris(imido) products. Spectroscopic and structural characterization of these compounds supports the idea that electrons are stored in the ligand framework and used in subsequent reactivity. Computational analyses of the uranium imido products probed their molecular and electronic structures, which facilitated a comparison between the bonding in the tris(imido) structure and its tris(oxo) analogue.

Published

2013