Establishing Cost-Effective Computational Models for the Prediction of Lanthanoid Binding in [Ln(NO 3 )] 2+ (with Ln = La to Lu)

Peterson, Charles C.; Penchoff, Deborah A.; Auxier, II, John D.; Hall, Howard L.

doi:10.1021/acsomega.8b02403

Title: Establishing Cost-Effective Computational Models for the Prediction of Lanthanoid Binding in [Ln(NO ₃ )] ²⁺ (with Ln = La to Lu)

Abstract

Evaluating the efficiency of predictive methods is critical to the processes of upscaling laboratory processes to full-scale operations on an industrial scale. With regard to separation of lanthanoids, there is a considerable motivation to optimize these processes because of immediate use in nuclear fuel cycle operations, nuclear forensics applications, and rare-earth metal recovery. Efficient predictive capabilities in Gibbs free energies of reaction are essential to optimize separations and ligand design for selective binding needed for various radiochemical applications such as nuclear fuel disposition and recycling of lanthanoid fission products into useful radioisotope products. Ligand design is essential for selective binding of lanthanoids, as separating contiguous lanthanoids is challenging because of the similar behavior these elements exhibit. Modeling including electronic structure calculations of lanthanoid-containing compounds is particularly challenging because of the associated computational cost encountered with the number of electrons correlated in these systems and relativistic considerations. This study evaluates the predictive capabilities of various ab initio methods in the calculation of Gibbs free energies of reaction for [Ln(NO₃)]²⁺ compounds (with Ln = La to Lu), as nitrates are critical in traditional separation processes utilizing nitric acid. The composite methodologies evaluated predict Gibbs free energies of reaction for [Ln(NO₃)]²⁺ compounds withinmore »« less

Authors:

Peterson, Charles C. ^[1];

^[2]; Auxier, II, John D. ^[3]; Hall, Howard L. ^[4]

Research Information Technology Services, University of North Texas, 225 S. Avenue B, Denton, Texas 76201, United States, Institute for Nuclear Security, University of Tennessee, 1640 Cumberland Avenue, Knoxville, Tennessee 37996, United States
Institute for Nuclear Security, University of Tennessee, 1640 Cumberland Avenue, Knoxville, Tennessee 37996, United States
Department of Nuclear Engineering, University of Tennessee, 301 Middle Dr., Pasqua Nuclear Engineering Bldg., Knoxville, Tennessee 37996, United States
Institute for Nuclear Security, University of Tennessee, 1640 Cumberland Avenue, Knoxville, Tennessee 37996, United States, Department of Nuclear Engineering, University of Tennessee, 301 Middle Dr., Pasqua Nuclear Engineering Bldg., Knoxville, Tennessee 37996, United States, Radiochemistry Center of Excellence (RCOE), University of Tennessee, 1508 Middle Dr., Ferris Hall, Knoxville, Tennessee 37996, United States, Y-12 National Security Complex, Oak Ridge, Tennessee 37830, United States

Publication Date:: Wed Jan 16 00:00:00 EST 2019

Research Org.:: Univ. of Tennessee, Knoxville, TN (United States)

Sponsoring Org.:: USDOE National Nuclear Security Administration (NNSA); USDOE Office of Science (SC); National Science Foundation (NSF)

OSTI Identifier:: 1491051

Alternate Identifier(s):: OSTI ID: 1508790

Grant/Contract Number:: NA0001983; AC02-05CH11231; ACI-1548562

Resource Type:: Published Article

Journal Name:: ACS Omega

Additional Journal Information:: Journal Name: ACS Omega Journal Volume: 4 Journal Issue: 1; Journal ID: ISSN 2470-1343

Publisher:: American Chemical Society (ACS)

Country of Publication:: United States

Language:: English

Subject:: 36 MATERIALS SCIENCE; 37 INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY; 11 NUCLEAR FUEL CYCLE AND FUEL MATERIALS; free energy; materials science; organic compounds and functional groups; quantum mechanical methods; rare earth salts; theory

Citation Formats


                    Peterson, Charles C., Penchoff, Deborah A., Auxier, II, John D., and Hall, Howard L. Establishing Cost-Effective Computational Models for the Prediction of Lanthanoid Binding in [Ln(NO 3 )] 2+ (with Ln = La to Lu).  United States: N. p., 2019. 
Web.  doi:10.1021/acsomega.8b02403.

Copy to clipboard


                    Peterson, Charles C., Penchoff, Deborah A., Auxier, II, John D., & Hall, Howard L. Establishing Cost-Effective Computational Models for the Prediction of Lanthanoid Binding in [Ln(NO 3 )] 2+ (with Ln = La to Lu).  United States.  https://doi.org/10.1021/acsomega.8b02403

Copy to clipboard


                    Peterson, Charles C., Penchoff, Deborah A., Auxier, II, John D., and Hall, Howard L. Wed .  
"Establishing Cost-Effective Computational Models for the Prediction of Lanthanoid Binding in [Ln(NO 3 )] 2+ (with Ln = La to Lu)".  United States.  https://doi.org/10.1021/acsomega.8b02403.

Copy to clipboard


                    
@article{osti_1491051,

  title        = {Establishing Cost-Effective Computational Models for the Prediction of Lanthanoid Binding in [Ln(NO 3 )] 2+ (with Ln = La to Lu)},

  author       = {Peterson, Charles C. and Penchoff, Deborah A. and Auxier, II, John D. and Hall, Howard L.},

  abstractNote = {Evaluating the efficiency of predictive methods is critical to the processes of upscaling laboratory processes to full-scale operations on an industrial scale. With regard to separation of lanthanoids, there is a considerable motivation to optimize these processes because of immediate use in nuclear fuel cycle operations, nuclear forensics applications, and rare-earth metal recovery. Efficient predictive capabilities in Gibbs free energies of reaction are essential to optimize separations and ligand design for selective binding needed for various radiochemical applications such as nuclear fuel disposition and recycling of lanthanoid fission products into useful radioisotope products. Ligand design is essential for selective binding of lanthanoids, as separating contiguous lanthanoids is challenging because of the similar behavior these elements exhibit. Modeling including electronic structure calculations of lanthanoid-containing compounds is particularly challenging because of the associated computational cost encountered with the number of electrons correlated in these systems and relativistic considerations. This study evaluates the predictive capabilities of various ab initio methods in the calculation of Gibbs free energies of reaction for [Ln(NO3)]2+ compounds (with Ln = La to Lu), as nitrates are critical in traditional separation processes utilizing nitric acid. The composite methodologies evaluated predict Gibbs free energies of reaction for [Ln(NO3)]2+ compounds within 5 kcal mol–1 in most cases from the target method [CCSD(T)-FSII/cc-pwCV∞Z-DK3+SO] at a fraction of the computational cost.},

  doi          = {10.1021/acsomega.8b02403},

  journal      = {ACS Omega},

  number       = 1,

  volume       = 4,

  place        = {United States},

  year         = {Wed Jan 16 00:00:00 EST 2019},

  month        = {Wed Jan 16 00:00:00 EST 2019}

}

Copy to clipboard

Journal Article:

Free Publicly Available Full Text

Publisher's Version of Record
https://doi.org/10.1021/acsomega.8b02403

Other availability

Search WorldCat to find libraries that may hold this journal

Citation Metrics:

Cited by: 5 works

Citation information provided by
Web of Science

Figures / Tables:

Table 1: Electronic Configuration for Ln IV and Ln III⁴³

All figures and tables (12 total)

Save / Share:

Export Metadata

Save to My Library

Works referenced in this record:

The role of databases in support of computational chemistry calculations
journal, October 1996

Feller, David
Journal of Computational Chemistry, Vol. 17, Issue 13
DOI: 10.1002/(SICI)1096-987X(199610)17:13<1571::AID-JCC9>3.0.CO;2-P

Review Article: The Effects of Radiation Chemistry on Solvent Extraction: 2. A Review of Fission‐Product Extraction
journal, May 2009

Mincher, Bruce J.; Modolo, Giuseppe; Mezyk, Stephen P.
Solvent Extraction and Ion Exchange, Vol. 27, Issue 3
DOI: 10.1080/07366290902821263

Density‐functional thermochemistry. III. The role of exact exchange
journal, April 1993

Becke, Axel D.
The Journal of Chemical Physics, Vol. 98, Issue 7, p. 5648-5652
DOI: 10.1063/1.464913

The synthesis and spectroscopic characterization of an aromatic uranium amidoxime complex
journal, September 2014

Bernstein, Karl J.; Do-Thanh, Chi-Linh; Penchoff, Deborah A.
Inorganica Chimica Acta, Vol. 421
DOI: 10.1016/j.ica.2014.06.023

Relativistic double-zeta, triple-zeta, and quadruple-zeta basis sets for the lanthanides La–Lu
journal, January 2010

Gomes, André S. P.; Dyall, Kenneth G.; Visscher, Lucas
Theoretical Chemistry Accounts, Vol. 127, Issue 4
DOI: 10.1007/s00214-009-0725-7

Molpro: a general-purpose quantum chemistry program package: Molpro
journal, July 2011

Werner, Hans-Joachim; Knowles, Peter J.; Knizia, Gerald
Wiley Interdisciplinary Reviews: Computational Molecular Science, Vol. 2, Issue 2
DOI: 10.1002/wcms.82

Ab initio total atomization energies of small molecules — towards the basis set limit
journal, September 1996

Martin, Jan M. L.
Chemical Physics Letters, Vol. 259, Issue 5-6
DOI: 10.1016/0009-2614(96)00898-6

Relativistic Douglas-Kroll-Hess theory: Relativistic DKH theory
journal, June 2011

Reiher, Markus
Wiley Interdisciplinary Reviews: Computational Molecular Science, Vol. 2, Issue 1
DOI: 10.1002/wcms.67

Synthesis and Molecular Structure of a Plutonium(IV) Coordination Complex: [Pu(NO ₃ ) ₂ {2,6-[(C ₆ H ₅ ) ₂ P(O)CH ₂ ] ₂ C ₅ H ₃ NO} ₂ ](NO ₃ ) ₂ •1.5H ₂ O•0.5MeOH
journal, September 2000

Bond, Evelyn M.; Duesler, Eileen N.; Paine, Robert T.
Inorganic Chemistry, Vol. 39, Issue 18
DOI: 10.1021/ic000146z

Perspective: Fifty years of density-functional theory in chemical physics
journal, May 2014

Becke, Axel D.
The Journal of Chemical Physics, Vol. 140, Issue 18
DOI: 10.1063/1.4869598

Characterization of Lanthanide Complexes with Bis-1,2,3-triazole-bipyridine Ligands Involved in Actinide/Lanthanide Separation
journal, October 2016

Muller, Julie M.; Galley, Shane S.; Albrecht-Schmitt, Thomas E.
Inorganic Chemistry, Vol. 55, Issue 21
DOI: 10.1021/acs.inorgchem.6b02005

Basis Set Exchange: A Community Database for Computational Sciences
journal, March 2007

Schuchardt, Karen L.; Didier, Brett T.; Elsethagen, Todd
Journal of Chemical Information and Modeling, Vol. 47, Issue 3
DOI: 10.1021/ci600510j

Cerium(IV), Neptunium(IV), and Plutonium(IV) 1,2-Phenylenediphosphonates: Correlations and Differences between Early Transuranium Elements and Their Proposed Surrogates
journal, November 2010

Diwu, Juan; Wang, Shuao; Liao, Zuolei
Inorganic Chemistry, Vol. 49, Issue 21
DOI: 10.1021/ic1015912

Self‐consistent molecular orbital methods. XX. A basis set for correlated wave functions
journal, January 1980

Krishnan, R.; Binkley, J. S.; Seeger, R.
The Journal of Chemical Physics, Vol. 72, Issue 1
DOI: 10.1063/1.438955

The correlation consistent composite approach (cc CA ): An alternative to the Gaussian-n methods
journal, March 2006

DeYonker, Nathan J.; Cundari, Thomas R.; Wilson, Angela K.
The Journal of Chemical Physics, Vol. 124, Issue 11
DOI: 10.1063/1.2173988

Comment on: “Estimating the Hartree–Fock limit from finite basis set calculations” [Jensen F (2005) Theor Chem Acc 113:267]
journal, December 2005

Karton, Amir; Martin, Jan M. L.
Theoretical Chemistry Accounts, Vol. 115, Issue 4
DOI: 10.1007/s00214-005-0028-6

Parallel Douglas–Kroll energy and gradients in NWChem: Estimating scalar relativistic effects using Douglas–Kroll contracted basis sets
journal, January 2001

de Jong, W. A.; Harrison, R. J.; Dixon, D. A.
The Journal of Chemical Physics, Vol. 114, Issue 1
DOI: 10.1063/1.1329891

Synthesis, Lanthanide Coordination Chemistry, and Liquid–Liquid Extraction Performance of CMPO-Decorated Pyridine and Pyridine N -Oxide Platforms
journal, March 2013

Rosario-Amorin, Daniel; Ouizem, Sabrina; Dickie, Diane A.
Inorganic Chemistry, Vol. 52, Issue 6
DOI: 10.1021/ic3025342

Structural Analysis of the Complexation of Uranyl, Neptunyl, Plutonyl, and Americyl with Cyclic Imide Dioximes
journal, October 2018

Penchoff, Deborah A.; Peterson, Charles C.; Camden, Jon P.
ACS Omega, Vol. 3, Issue 10
DOI: 10.1021/acsomega.8b02068

Toward Chemical Accuracy in ab Initio Thermochemistry and Spectroscopy of Lanthanide Compounds: Assessing Core–Valence Correlation, Second-Order Spin–Orbit Coupling, and Higher Order Effects in Lanthanide Diatomics
journal, October 2017

Solomonik, Victor G.; Smirnov, Alexander N.
Journal of Chemical Theory and Computation, Vol. 13, Issue 11
DOI: 10.1021/acs.jctc.7b00408

NWChem: A comprehensive and scalable open-source solution for large scale molecular simulations
journal, September 2010

Valiev, M.; Bylaska, E. J.; Govind, N.
Computer Physics Communications, Vol. 181, Issue 9, p. 1477-1489
DOI: 10.1016/j.cpc.2010.04.018

Structural Characteristics, Population Analysis, and Binding Energies of [An(NO ₃ )] ²⁺ (with An = Ac to Lr)
journal, October 2018

Penchoff, Deborah A.; Peterson, Charles C.; Quint, Mark S.
ACS Omega, Vol. 3, Issue 10
DOI: 10.1021/acsomega.8b01800

Lanthanide Speciation in Potential SANEX and GANEX Actinide/Lanthanide Separations Using Tetra-N-Donor Extractants
journal, June 2012

Whittaker, Daniel M.; Griffiths, Tamara L.; Helliwell, Madeleine
Inorganic Chemistry, Vol. 52, Issue 7
DOI: 10.1021/ic301599y

Chelating properties of 2-((diphenylphosphino)methyl)pyridine N,P-dioxide and 2,6-bis((diphenylphosphino)methyl)pyridine N,P,P'-trioxide toward f-element ions
journal, May 1993

Rapko, B. M.; Duesler, E. N.; Smith, P. H.
Inorganic Chemistry, Vol. 32, Issue 10
DOI: 10.1021/ic00062a047

Separation of Americium from Lanthanides by Purified Cyanex 301 Countercurrent Extraction in Miniature Centrifugal Contactors
journal, January 2012

Chen, Jing; Wang, Shuwei; Xu, Chao
Procedia Chemistry, Vol. 7
DOI: 10.1016/j.proche.2012.10.029

Development of Highly Selective Ligands for Separations of Actinides from Lanthanides in the Nuclear Fuel Cycle
journal, October 2011

Lewis, Frank; Hudson, Michael; Harwood, Laurence
Synlett, Vol. 2011, Issue 18
DOI: 10.1055/s-0030-1289557

Ab initio approaches for the determination of heavy element energetics: Ionization energies of trivalent lanthanides (Ln = La-Eu)
journal, November 2015

Peterson, Charles; Penchoff, Deborah A.; Wilson, Angela K.
The Journal of Chemical Physics, Vol. 143, Issue 19
DOI: 10.1063/1.4935809

Correlation consistent basis sets for lanthanides: The atoms La–Lu
journal, August 2016

Lu, Qing; Peterson, Kirk A.
The Journal of Chemical Physics, Vol. 145, Issue 5
DOI: 10.1063/1.4959280

Crystallographic and Spectroscopic Characterization of Americium Complexes Containing the Bis[(phosphino)methyl]pyridine-1-oxide (NOPOPO) Ligand Platform
journal, February 2018

Corbey, Jordan F.; Rapko, Brian M.; Wang, Zheming
Inorganic Chemistry, Vol. 57, Issue 4
DOI: 10.1021/acs.inorgchem.7b03154

Figures / Tables found in this record:

Figures/Tables have been extracted from DOE-funded journal article accepted manuscripts.

Similar Records in DOE PAGES and OSTI.GOV collections:

A new series of lanthanoid containing Keggin-type germanotungstates with acetate chelators: [{l_brace}Ln(CH{sub 3}COO)GeW{sub 11}O{sub 39}(H{sub 2}O){r_brace}{sub 2}]{sup 12-} {l_brace}Ln=Eu{sup III}, Gd{sup III}, Tb{sup III}, Dy{sup III}, Ho{sup III}, Er{sup III}, Tm{sup III}, and Yb{sup III{r_brace}}

Journal Article Hussain, Firasat ; Sandriesser, Stefan ; Speldrich, Manfred ; ... - Journal of Solid State Chemistry

A series of head-on complexes of lanthanoid containing germanotungstates was isolated from a one pot reaction in an acetate buffer at pH 4.5. This convenient approach brought forward the [{l_brace}Ln(CH{sub 3}COO)GeW{sub 11}O{sub 39}(H{sub 2}O){r_brace}{sub 2}]{sup 12-} (Ln=Eu{sup III}, Gd{sup III}, Tb{sup III}, Dy{sup III}, Ho{sup III}, Er{sup III}, Tm{sup III}, and Yb{sup III}) family with acetate chelators in the rarely observed {mu}{sub 2}: {eta}{sup 2}-{eta}{sup 1} mode. All compounds were structurally characterized using various solid state analytics, such as single crystal X-ray diffraction, FT-IR spectroscopy, and thermogravimetric analysis. The isostructural polyanions crystallize in the monoclinic system (S.G. P2{sub 1}/c). Temperature-dependentmore »« less
https://doi.org/10.1016/j.jssc.2010.11.005
Synthesis, properties, and x-ray structures of the lanthanide {eta}{sup 6}-arene-bridged aryloxide dimers Ln{sub 2}(O-2,6-i-Pr{sub 2}H{sub 3}){sub 6} and their Lewis base adducts Ln(O-2,6-i-Pr{sub 2}C{sub 6}H{sub 3}){sub 3}(THF){sub 2}(Ln = Pr, Nd, Sm, Gd, Er, Yb, Lu)

Journal Article Barnhart, D M ; Clark, D L ; Gordon, J C ; ... - Inorganic Chemistry

Reaction of 3 equiv of 2,6-diisopropylphenol with Ln[N(SiMe{sub 3}){sub 2}]{sub 3}(Ln=Nd, Sm, Er) in refluxing toluene and subsequent crystallization yield pale blue (Nd), deep yellow (Sm), or light pink (Er) crystals of the tris(aryloxide) complexes Ln{sub 2}(O-2,6-i-Pr{sub 2}C{sub 6}H{sub 3}){sub 6}(Ln = Nd(1), Sm(2), Er(3)) in good yield. X-ray crystallographic studies of 1 and 2 reveal centrosymmetric, dimeric units bridged by {eta}{sup 6}-{pi}-arene interactions of a unique aryloxide ligand. Ln-O bond lengths average 2.122(9) (1,Nd) and 2.101(6) {Angstrom} (2,Sm) for terminal ligands and 2.211(8) (1) and 2.198(5) {Angstrom} (2) for bridging aryloxide ligands. {eta}{sup 6}-Arene bridges hold the dimeric unitsmore »« less
https://doi.org/10.1021/ic00094a009
Synthesis and characterization of Ln(B{sub 0.5}Mn{sub 0.5})O{sub 3} (Ln-lanthanoid; B = Ni, Co) perovskites

Journal Article Troyanchuk, I O ; Samsonenko, N V ; Shapovalova, E F ; ... - Materials Research Bulletin

The Ln(B{sub 0.5}Mn{sub 0.5})O{sub 3} (Ln-lanthanoid; B = Ni, Co) compounds with the orthorhombic perovskite structure have been prepared by a solid state reaction. They are ferromagnets with relatively high Curie temperatures. The Curie temperature decreases with decreasing average radii of the Ln-ion. It is shown that the Ln(Co{sub 0.5}Mn{sub 0.5})O{sub 3} (Ln = Gd, Tb, Dy, Y, Ho) are metamagnets.
https://doi.org/10.1016/S0025-5408(96)00158-4
Crystal structure, spectroscopic properties, and magnetic behavior of the fluoride-derivatized lanthanoid(III) ortho-oxomolybdates(VI) LnF[MoO{sub 4}] (Ln=Sm-Tm)

Journal Article Hartenbach, Ingo ; Strobel, Sabine ; Department of Chemistry, Colorado State University, Fort Collins, CO ; ... - Journal of Solid State Chemistry

The fluoride-derivatized lanthanoid(III) ortho-oxomolybdates(VI) LnF[MoO{sub 4}] (Ln=Sm-Tm) crystallize in the monoclinic space group P2{sub 1}/c with four formula units per unit cell (a=516-528 pm, b=1220-1248 pm, c=659-678 pm, {beta}=112.5-113.1{sup o}). The structure contains one crystallographically unique Ln{sup 3+} cation surrounded by two fluoride and six oxide anions in a square antiprism (CN=8). The square antiprisms [LnF{sub 2}O{sub 6}] are interconnected via three edges to form layers {sub {infinity}}{sup 2}{l_brace}[LnF{sub 2/2}{sup e}O{sub 4/2}{sup e}O{sub 2/1}{sup t}]{sup 6-}{r_brace} parallel (010), which are cross-linked along [010] by Mo{sup 6+} in tetrahedral oxygen coordination to form the three-dimensional crystal structure. The fluoride anions withinmore »« less
https://doi.org/10.1016/j.jssc.2008.07.016
X-Ray Absorption Fine Structure Spectroscopic Studies of Octakis(DMSO)Lanthanoid(III) Complexes in Solution And in the Solid Iodides

Journal Article Persson, I ; Risberg, E Damian ; D'Angelo, P ; ... - Inorg. Chem. 46:7742,2007

Octakis(DMSO)lanthanoid(III) iodides (DMSO = dimethylsulfoxide), [Ln(OS(CH{sub 3}){sub 2}){sub 8}]I{sub 3}, of most lanthanoid(III) ions in the series from La to Lu have been studied in the solid state and in DMSO solution by extended X-ray absorption fine structure (EXAFS) spectroscopy. L{sub 3}-edge and also some K-edge spectra were recorded, which provided mean Ln-O bond distances for the octakis(DMSO)lanthanoid(III) complexes. The agreement with the average of the Ln-O bond distances obtained in a separate study by X-ray crystallography was quite satisfactory. The crystalline octakis(DMSO)lanthanoid(III) iodide salts have a fairly broad distribution of Ln-O bond distances, ca. 0.1 {angstrom}, with a fewmore »« less

Similar Records

Title: Establishing Cost-Effective Computational Models for the Prediction of Lanthanoid Binding in [Ln(NO 3 )] 2+ (with Ln = La to Lu)

Abstract

Citation Formats

Figures / Tables:

The role of databases in support of computational chemistry calculations journal, October 1996

Review Article: The Effects of Radiation Chemistry on Solvent Extraction: 2. A Review of Fission‐Product Extraction journal, May 2009

Density‐functional thermochemistry. III. The role of exact exchange journal, April 1993

The synthesis and spectroscopic characterization of an aromatic uranium amidoxime complex journal, September 2014

Relativistic double-zeta, triple-zeta, and quadruple-zeta basis sets for the lanthanides La–Lu journal, January 2010

Molpro: a general-purpose quantum chemistry program package: Molpro journal, July 2011

Ab initio total atomization energies of small molecules — towards the basis set limit journal, September 1996

Relativistic Douglas-Kroll-Hess theory: Relativistic DKH theory journal, June 2011

Synthesis and Molecular Structure of a Plutonium(IV) Coordination Complex: [Pu(NO 3 ) 2 {2,6-[(C 6 H 5 ) 2 P(O)CH 2 ] 2 C 5 H 3 NO} 2 ](NO 3 ) 2 •1.5H 2 O•0.5MeOH journal, September 2000

Perspective: Fifty years of density-functional theory in chemical physics journal, May 2014

Characterization of Lanthanide Complexes with Bis-1,2,3-triazole-bipyridine Ligands Involved in Actinide/Lanthanide Separation journal, October 2016

Basis Set Exchange: A Community Database for Computational Sciences journal, March 2007

Cerium(IV), Neptunium(IV), and Plutonium(IV) 1,2-Phenylenediphosphonates: Correlations and Differences between Early Transuranium Elements and Their Proposed Surrogates journal, November 2010

Self‐consistent molecular orbital methods. XX. A basis set for correlated wave functions journal, January 1980

The correlation consistent composite approach (cc CA ): An alternative to the Gaussian-n methods journal, March 2006

Comment on: “Estimating the Hartree–Fock limit from finite basis set calculations” [Jensen F (2005) Theor Chem Acc 113:267] journal, December 2005

Parallel Douglas–Kroll energy and gradients in NWChem: Estimating scalar relativistic effects using Douglas–Kroll contracted basis sets journal, January 2001

Synthesis, Lanthanide Coordination Chemistry, and Liquid–Liquid Extraction Performance of CMPO-Decorated Pyridine and Pyridine N -Oxide Platforms journal, March 2013

Structural Analysis of the Complexation of Uranyl, Neptunyl, Plutonyl, and Americyl with Cyclic Imide Dioximes journal, October 2018

Toward Chemical Accuracy in ab Initio Thermochemistry and Spectroscopy of Lanthanide Compounds: Assessing Core–Valence Correlation, Second-Order Spin–Orbit Coupling, and Higher Order Effects in Lanthanide Diatomics journal, October 2017

NWChem: A comprehensive and scalable open-source solution for large scale molecular simulations journal, September 2010

Structural Characteristics, Population Analysis, and Binding Energies of [An(NO 3 )] 2+ (with An = Ac to Lr) journal, October 2018

Lanthanide Speciation in Potential SANEX and GANEX Actinide/Lanthanide Separations Using Tetra-N-Donor Extractants journal, June 2012

Chelating properties of 2-((diphenylphosphino)methyl)pyridine N,P-dioxide and 2,6-bis((diphenylphosphino)methyl)pyridine N,P,P'-trioxide toward f-element ions journal, May 1993

Separation of Americium from Lanthanides by Purified Cyanex 301 Countercurrent Extraction in Miniature Centrifugal Contactors journal, January 2012

Development of Highly Selective Ligands for Separations of Actinides from Lanthanides in the Nuclear Fuel Cycle journal, October 2011

Ab initio approaches for the determination of heavy element energetics: Ionization energies of trivalent lanthanides (Ln = La-Eu) journal, November 2015

Correlation consistent basis sets for lanthanides: The atoms La–Lu journal, August 2016

Crystallographic and Spectroscopic Characterization of Americium Complexes Containing the Bis[(phosphino)methyl]pyridine-1-oxide (NOPOPO) Ligand Platform journal, February 2018

Title: Establishing Cost-Effective Computational Models for the Prediction of Lanthanoid Binding in [Ln(NO ₃ )] ²⁺ (with Ln = La to Lu)

The role of databases in support of computational chemistry calculations
journal, October 1996

Review Article: The Effects of Radiation Chemistry on Solvent Extraction: 2. A Review of Fission‐Product Extraction
journal, May 2009

Density‐functional thermochemistry. III. The role of exact exchange
journal, April 1993

The synthesis and spectroscopic characterization of an aromatic uranium amidoxime complex
journal, September 2014

Relativistic double-zeta, triple-zeta, and quadruple-zeta basis sets for the lanthanides La–Lu
journal, January 2010

Molpro: a general-purpose quantum chemistry program package: Molpro
journal, July 2011

Ab initio total atomization energies of small molecules — towards the basis set limit
journal, September 1996

Relativistic Douglas-Kroll-Hess theory: Relativistic DKH theory
journal, June 2011

Synthesis and Molecular Structure of a Plutonium(IV) Coordination Complex: [Pu(NO ₃ ) ₂ {2,6-[(C ₆ H ₅ ) ₂ P(O)CH ₂ ] ₂ C ₅ H ₃ NO} ₂ ](NO ₃ ) ₂ •1.5H ₂ O•0.5MeOH
journal, September 2000

Perspective: Fifty years of density-functional theory in chemical physics
journal, May 2014

Characterization of Lanthanide Complexes with Bis-1,2,3-triazole-bipyridine Ligands Involved in Actinide/Lanthanide Separation
journal, October 2016

Basis Set Exchange: A Community Database for Computational Sciences
journal, March 2007

Cerium(IV), Neptunium(IV), and Plutonium(IV) 1,2-Phenylenediphosphonates: Correlations and Differences between Early Transuranium Elements and Their Proposed Surrogates
journal, November 2010

Self‐consistent molecular orbital methods. XX. A basis set for correlated wave functions
journal, January 1980

The correlation consistent composite approach (cc CA ): An alternative to the Gaussian-n methods
journal, March 2006

Comment on: “Estimating the Hartree–Fock limit from finite basis set calculations” [Jensen F (2005) Theor Chem Acc 113:267]
journal, December 2005

Parallel Douglas–Kroll energy and gradients in NWChem: Estimating scalar relativistic effects using Douglas–Kroll contracted basis sets
journal, January 2001

Synthesis, Lanthanide Coordination Chemistry, and Liquid–Liquid Extraction Performance of CMPO-Decorated Pyridine and Pyridine N -Oxide Platforms
journal, March 2013

Structural Analysis of the Complexation of Uranyl, Neptunyl, Plutonyl, and Americyl with Cyclic Imide Dioximes
journal, October 2018

Toward Chemical Accuracy in ab Initio Thermochemistry and Spectroscopy of Lanthanide Compounds: Assessing Core–Valence Correlation, Second-Order Spin–Orbit Coupling, and Higher Order Effects in Lanthanide Diatomics
journal, October 2017

NWChem: A comprehensive and scalable open-source solution for large scale molecular simulations
journal, September 2010

Structural Characteristics, Population Analysis, and Binding Energies of [An(NO ₃ )] ²⁺ (with An = Ac to Lr)
journal, October 2018

Lanthanide Speciation in Potential SANEX and GANEX Actinide/Lanthanide Separations Using Tetra-N-Donor Extractants
journal, June 2012

Chelating properties of 2-((diphenylphosphino)methyl)pyridine N,P-dioxide and 2,6-bis((diphenylphosphino)methyl)pyridine N,P,P'-trioxide toward f-element ions
journal, May 1993

Separation of Americium from Lanthanides by Purified Cyanex 301 Countercurrent Extraction in Miniature Centrifugal Contactors
journal, January 2012

Development of Highly Selective Ligands for Separations of Actinides from Lanthanides in the Nuclear Fuel Cycle
journal, October 2011

Ab initio approaches for the determination of heavy element energetics: Ionization energies of trivalent lanthanides (Ln = La-Eu)
journal, November 2015

Correlation consistent basis sets for lanthanides: The atoms La–Lu
journal, August 2016

Crystallographic and Spectroscopic Characterization of Americium Complexes Containing the Bis[(phosphino)methyl]pyridine-1-oxide (NOPOPO) Ligand Platform
journal, February 2018