All Stories

  1. Assessing the exchange coupling in binuclear lanthanide(iii) complexes and the slow relaxation of the magnetization in the antiferromagnetically coupled Dy2 derivative
  2. Sculpting Metal-binding Environments inDe NovoDesigned Three-helix Bundles
  3. Correction: Assessing the exchange coupling in binuclear lanthanide(iii) complexes and the slow relaxation of the magnetization in the antiferromagnetically coupled Dy2 derivative
  4. Variable primary coordination environments of Cd(ii) binding to three helix bundles provide a pathway for rapid metal exchange
  5. A De Novo Designed Metalloenzyme for the Hydration of CO 2
  6. A De Novo Designed Metalloenzyme for the Hydration of CO2
  7. Understanding Spin Structure in Metallacrown Single-Molecule Magnets using Magnetic Compton Scattering
  8. Highly Emitting Near-Infrared Lanthanide “Encapsulated Sandwich” Metallacrown Complexes with Excitation Shifted Toward Lower Energy
  9. Controllable Formation of Heterotrimetallic Coordination Compounds: Systematically Incorporating Lanthanide and Alkali Metal Ions into the Manganese 12-Metallacrown-4 Framework
  10. Isolation of Elusive Tetranuclear and Pentanuclear M(II)–Hydroximate Intermediates in the Assembly of Lanthanide [15-Metallacrown-5] Complexes
  11. Influence of Active Site Location on Catalytic Activity in de Novo -Designed Zinc Metalloenzymes
  12. Insight into the structural versatility of the Ln(III)[15-metallacrown-5] platform by comparing analogs with Ni(II), Cu(II), and Zn(II) ring ions
  13. Selective anion encapsulation in solid-state Ln(iii)[15-metallacrown-5]3+ compartments through secondary sphere interactions
  14. Enhanced Guest Affinity and Enantioselectivity through Variation of the Gd 3+ [15-Metallacrown-5] Side Chain
  15. Influencing the Size and Anion Selectivity of Dimeric Ln 3+ [15-Metallacrown-5] Compartments through Systematic Variation of the Host Side Chains and Central Metal
  16. Single Molecule Magnet Behavior of a Pentanuclear Mn-Based Metallacrown Complex: Solid State and Solution Magnetic Studies
  17. Assembly of Near-Infrared Luminescent Lanthanide Host(Host-Guest) Complexes With a Metallacrown Sandwich Motif
  18. Assembly of Near-Infrared Luminescent Lanthanide Host(Host-Guest) Complexes With a Metallacrown Sandwich Motif
  19. Gd(III)[15-Metallacrown-5] Recognition of Chiral α-Amino Acid Analogues
  20. A Mixed 3d−4f 14-Metallacrown-5 Complex That Displays Slow Magnetic Relaxation through Geometric Control of Magnetoanisotropy
  21. Cover Picture: Voltammetric Characterization of Redox-Inactive Guest Binding to LnIII[15-Metallacrown-5] Hosts Based on Competition with a Redox Probe (Chem. Eur. J. 23/2010)
  22. Thermodynamics of Core Metal Replacement and Self-Assembly of Ca 2+ 15-Metallacrown-5 †
  23. Voltammetric Characterization of Redox-Inactive Guest Binding to LnIII[15-Metallacrown-5] Hosts Based on Competition with a Redox Probe
  24. Disruption of the La(III)[15-Metallacrown-5] Cavity through Bithiophene Dicarboxylate Inclusion
  25. Chiral Metallacrown Supramolecular Compartments that Template Nanochannels: Self-Assembly and Guest Absorption
  26. Cover Picture: Chiral Metallacrown Supramolecular Compartments that Template Nanochannels: Self-Assembly and Guest Absorption (Chem. Asian J. 1/2010)
  27. Establishing the Binding Affinity of Organic Carboxylates to 15-Metallacrown-5 Complexes
  28. Harnessing natures ability to control metal ion coordination geometry using de novo designed peptides
  29. Tuning the Redox Properties of Manganese(II) and Its Implications to the Electrochemistry of Manganese and Iron Superoxide Dismutases
  30. In Search of Elusive High-Valent Manganese Species That Evaluate Mechanisms of Photosynthetic Water Oxidation
  31. Reevaluation of the Kinetics of Polynuclear Mimics for Manganese Catalases
  32. Titelbild: Heterochromia in Designed Metallopeptides: Geometry-Selective Binding of CdII in a De Novo Peptide (Angew. Chem. 35/2007)
  33. Heterochromia in Designed Metallopeptides: Geometry-Selective Binding of CdII in a De Novo Peptide
  34. Heterochromia in Designed Metallopeptides: Geometry-Selective Binding of CdII in a De Novo Peptide
  35. Assessing Guest Selectivity within Metallacrown Host Compartments
  36. Metallacrown-based compartments: selective encapsulation of three isonicotinate anions in non-centrosymmetric solids
  37. Insight into the Catalytic Mechanism of Vanadium Haloperoxidases. DFT Investigation of Vanadium Cofactor Reactivity
  38. Quantum Mechanics/Molecular Mechanics Calculations of the Vanadium Dependent Chloroperoxidase
  39. Probing metal–protein interactions using a de novo design approach
  40. Synthetic and computational modeling of the vanadium-dependent haloperoxidases
  41. Reactivity of Peroxo Forms of the Vanadium Haloperoxidase Cofactor. A DFT Investigation
  42. Understanding Metalloprotein Folding Using a de Novo Design Strategy
  43. Structural, Spectroscopic, and Reactivity Models for the Manganese Catalases
  44. Structural, Spectroscopic, and Reactivity Models for the Manganese Catalases
  45. Probing metallopeptide folding mechanisms using de novo design peptides
  46. Preparation of Resolved Fourfold Symmetric Amphiphilic Helices Using Chiral Metallacrown Building Blocks
  47. Preparation of Resolved Fourfold Symmetric Amphiphilic Helices Using Chiral Metallacrown Building Blocks
  48. Oxidation of Organic Sulfides by Vanadium Haloperoxidase Model Complexes
  49. Preparation of Highly Efficient Manganese Catalase Mimics ‖
  50. Pseudohalide complexation by manganese 12-metallacrowns-4 complexes
  51. Chiral 15-Metallacrown-5 Complexes Differentially Bind Carboxylate Anions
  52. Lanthanide [15]Metallacrown-5 Complexes Form Nitrate-Selective Chiral Cavities
  53. Lanthanide [15]Metallacrown-5 Complexes Form Nitrate-Selective Chiral Cavities
  54. Preparation of a Chiral, 2-Dimensional Network Containing Metallacrown and Copper Benzoate Building Blocks
  55. Non-Heme Peroxidases and Catalases: Mechanistic Implications from the Studies of Manganese and Vanadium Model Compounds
  56. The Preparation, Characterization, and Magnetism of Copper 15-Metallacrown-5 Lanthanide Complexes
  57. Recent advances in the understanding of the biological chemistry of manganese
  58. Synthetic Models for Vanadium Haloperoxidases
  59. Preparation and Characterization of Chiral Copper 12-Metallacrown-4 Complexes, Inorganic Analogues of Tetraphenylporphyrinatocopper(II)
  60. Reactivity of Dioxovanadium(V) Complexes with Hydrogen Peroxide:  Implications for Vanadium Haloperoxidase
  61. Manganese Redox Enzymes and Model Systems: Properties, Structures, and Reactivity
  62. Structural and Solution Characterization of Mononuclear Vanadium(IV) Complexes That Help To Elucidate the Active Site Structure of the Reduced Vanadium Haloperoxidases
  63. Modeling the biological chemistry of vanadium: Structural and reactivity studies elucidating biological function
  64. A Planar[15]Metallacrown-5 That Selectively Binds the Uranyl Cation
  65. Reactivity and Mechanism of Manganese Enzymes
  66. Catalytic Disproportionation of Hydrogen Peroxide by the Tetranuclear Manganese Complex [Mn ll (2-OHpicpn)] 4
  67. Functional Models for Vanadium Haloperoxidase:  Reactivity and Mechanism of Halide Oxidation
  68. Facile Preparation of Face Differentiated, Chiral 15-Metallacrown-5 Complexes
  69. Structural Evaluation and Solution Integrity of Alkali Metal Salt Complexes of the Manganese 12-Metallacrown-4 (12-MC-4) Structural Type
  70. Synthesis and Crystal Structure of the First Inverse 12-Metallacrown-4
  71. Modeling the Chemistry and Properties of Multinuclear Manganese Enzymes
  72. Copper(II) 12-Metallacrown-4: Synthesis, Structure, Ligand Variability, and Solution Dynamics in the 12-MC-4 Structural Motif
  73. Interaction of Manganese with Dioxygen and Its Reduced Derivatives
  74. A functional model for vanadium haloperoxidase
  75. Generalizing the metallacrown analogy: ligand variation and solution stability of the VVO 9-metallacrown-3 structure type
  76. [Mn(III)(2-OHsalpn)]2 is an efficient functional model for the manganese catalases
  77. High-valent dinuclear manganese complexes as functional models of the catalase-like activity in the oxygen evolving complex
  78. Low valent, dinuclear manganese complexes as functional models for manganese catalases
  79. The synthesis and reactivity of peroxovanadium complexes as models for vanadium haloperoxidase.
  80. The fused metallacrown anion Na2{[Na0.5[Ga(salicylhydroximate)]4]2(.mu.2-OH)4}- is an inorganic analog of a cryptate
  81. Structural and magnetic characterization of trinuclear, mixed-valence manganese acetates
  82. Modeling vanadium bromoperoxidase: synthesis, structure, and spectral properties of vanadium(IV) complexes with coordinated imidazole
  83. Structural and spectroscopic characterization of vanadium(V)-oxoimidazole complexes
  84. Manganese-manganese separations in oxide- and alkoxide-bridged complexes: correlation of structure with ligand type and number
  85. Catalytic disproportionation of hydrogen peroxide by manganese complex [Mn(IV)(.mu.2-O)(SALPN)]2
  86. Modeling vanadium bromoperoxidase: Synthesis, structure and reactivity of vanadium-imidazole complexes.
  87. The peroxide-dependent .mu.2-O bond formation of manganese complex [Mn(IV)SALPN(O)]2
  88. Manganese complexes of .alpha.-hydroxy acids
  89. Development of Metallacrown Ethers: A New Class of Metal Clusters
  90. Stepwise, metal-assisted decarboxylation promoted by manganese: reactivity relationship between manganese and vanadium
  91. Structurally diverse manganese(III) Schiff base complexes: chains, dimers, and cages
  92. Structurally diverse manganese(III) Schiff base complexes: solution speciation via paramagnetic proton NMR spectroscopy and electrochemistry
  93. Structural characterization of [VO(salicylhydroximate)(CH3OH)]3: Applications to the biological chemistry of vanadium(V)
  94. Vanadium complexes of the tridentate Schiff base ligand N-salicylidene-N'-(2-hydroxyethyl)ethylenediamine: acid-base and redox conversion between vanadium(IV) and vanadium(V) imino phenolates
  95. STRUCTURAL PROPOSALS FOR THE MANGANESE CENTERS OF THE OXYGEN EVOLVING COMPLEX: AN INORGANIC CHEMIST'S PERSPECTIVE
  96. Mononuclear manganese(IV) complexes of hydroxyl-rich Schiff base ligands
  97. Characterization of mono- and binuclear manganese(II) Schiff base complexes with metal-disulfide ligation
  98. The acid promoted disproportionation of a vanadium(IV) phenolate: implications for vanadium uptake in tunicates