Relativistic Effects in Chemistry,

E = mc2 and the Periodic Table . . . RELATIVISTIC EFFECTS IN CHEMISTRY This century's most famous equation, Einstein's special theory of relativity, transformed our comprehension of the nature of time and matter. Today, making use of the theory in a relativistic analysis of heavy molecules, that is, computing the properties and nature of electrons, is the work of chemists intent on exploring the mysteries of minute particles. The first work of its kind, Relativistic Effects in Chemistry details the computational and analytical methods used in studying the relativistic effects in chemical bonding as well as the spectroscopic properties of molecules containing very heavy atoms. The first of two independent volumes, Part A: Theory and Techniques describes the basic techniques of relativistic quantum chemistry. Its systematic five-part format begins with a detailed exposition of Einstein's special theory of relativity, the significance of relativity in chemistry, and the nature of relativistic effects, especially with molecules containing both main group atoms and transition metal atoms. Chapter 3 discusses the fundamentals of relativistic quantum mechanics starting from the Klein-Gordon equation through such advanced constructs as the Breit-Pauli and Dirac multielectron Hamiltonian. Modern computational techniques, of importance with problems involving very heavy molecules, are outlined in Chapter 4. These include the relativistic effective core potentials, ab initio CASSCF, CI, and RCI techniques. Chapter 5 describes relativistic symmetry using the double group symmetry of molecules and the classification of relativistic electronic states and is of special importance to chemists or spectroscopists interested in computing or analyzing electronic states of molecules containing very heavy atoms. An exceptional introduction to one of chemistry's foremost analytical techniques, Relativistic Effects in Chemistry is also evidence of the still unending reverberations of Einstein's revolutionary theory.

KRISHNAN BALASUBRAMANIAN is Professor of Chemistry at Arizona State University. He has received the Alfred P. Sloan Fellowship, Camille and Henry Dreyfus teacher-scholar and Fulbright Research awards. He is an author of about 400 journal publications.

1 Relativistic Effects in Small Transition-Metal Clusters

1

(82)

1.1 Relativistic Effects in Transition-Metal Atoms

1

(2)

1.2 Relativistic Effects in Coinage-Metal Clusters

3

(43)

1.2.1 Experimental Studies on Cu(n), Ag(n), and Au(n)

4

(6)

1.2.2 Theoretical Studies on Cu(n), Ag(n), and Au(n)

10

(29)

1.2.3 Comparison of Coinage-Metal Clusters: Cu(n), Ag(n), and Au(n)

39

(7)

1.3 Electronic Structure of Palladium and Platinum Clusters

46

(15)

1.3.1 Pt(2)

46

(4)

1.3.2 Pd(2)

50

(4)

1.3.3 Pt(4) and Pd(4)

54

(7)

1.4 Electronic Structure of Rh(3) and Ir(3)

61

(22)

1.4.1 Rh(3)

61

(7)

1.4.2 Ir(3)

68

(15)

2 Relativistic Effects in Heteronuclear Diatomics of Main-Group p-Block Elements

83

(147)

2.1 Spectroscopic Properties and Potential-Energy Curves of Heavy Hydrides

84

(56)

2.1.1 GaH

84

(3)

2.1.2 GeH

87

(4)

2.1.3 AsH

91

(2)

2.1.4 SeH and SeH(+)

93

(4)

2.1.5 HBr and HBr(-)

97

(8)

2.1.6 InH

105

(1)

2.1.7 SnH

106

(4)

2.1.8 SbH

110

(4)

2.1.9 TeH

114

(1)

2.1.10 HI and HI(-)

115

(6)

2.1.11 TlH

121

(2)

2.1.12 PbH

123

(3)

2.1.13 BiH and BiH(+)

126

(14)

2.2 Spectroscopic Properties and Potential-Energy Curves of Heavy Halides

140

(41)

2.2.1 TlF

141

(4)

2.2.2 PbF

145

(1)

2.2.3 BiF

146

(9)

2.2.4 BiI

155

(1)

2.2.5 TlCl

155

(3)

2.2.6 PbCl

158

(3)

2.2.7 PbBr

161

(5)

2.2.8 PbI

166

(3)

2.2.9 SnCl

169

(2)

2.2.10 SnBr

171

(3)

2.2.11 SbF

174

(7)

2.3 Spectroscopic Properties and Potential-Energy Curves of Heavy Group IV Chalcogenides and Their Ions

181

(23)

2.3.1 SnO and SnO(+)

181

(3)

2.3.2 PbO and PbO(+)

184

(5)

2.3.3 SnS

189

(3)

2.3.4 PbS

192

(3)

2.3.5 SbO

195

(6)

2.3.6 BiO

201

(3)

2.4 Comparison of the Spectroscopic Properties of Heavy Hydrides

204

(8)

2.5 Comparison of the Spectroscopic Properties of Heavy Halides

212

(3)

2.6 Comparison of Heavy Chalcogenides

215

(15)

3 Relativistic Effects in Main-Group Clusters

230

(160)

3.1 Introduction

230

(1)

3.2 Methods of Investigation

231

(3)

3.2.1 Experimental Techniques

231

(2)

3.2.2 Theoretical Techniques of Calculation

233

(1)

3.3 Spectroscopic Properties and Potential-Energy Curves of Heavy Homonuclear Dimers (Ga(2) to Bi(2))

234

(96)

3.3.1 Ga(2)

234

(5)

3.3.2 Ge(2)

239

(7)

3.3.3 As(2)

246

(4)

3.3.4 Se(2)

250

(7)

3.3.5 Br(2) and Br(2)(+)

257

(11)

3.3.6 In(2)

268

(9)

3.3.7 Sn(2)

277

(3)

3.3.8 Sb(2)

280

(13)

3.3.9 Te(2)

293

(5)

3.3.10 I(2) and I(2)(+)

298

(16)

3.3.11 Tl(2) and Tl(2)(+)

314

(1)

3.3.12 Pb(2)

314

(7)

3.3.13 Bi(2)

321

(9)

3.4 Electronic Structure of Mixed Clusters

330

(4)

3.5 Spectroscopic Properties and Potential-Energy Surfaces of Trimers

334

(33)

3.5.1 Ga(3)

334

(4)

3.5.2 In(3)

338

(3)

3.5.3 Ge(3)

341

(4)

3.5.4 Sn(3)

345

(3)

3.5.5 Group V Trimers P(3)-Bi(3)

348

(7)

3.5.6 Se(3), Te(3), and Po(3)

355

(12)

3.6 Comparison of the Properties and Periodic Trends Among Dimers

367

(23)

4 Relativistic Effects on Molecules Containing Lanthanides and Actinides

390

(121)

4.1 Relativity and the Lanthanide Contraction

391

(6)

4.2 Ab Initio Theoretical Techniques for Lanthanide- and Actinide-Containing Molecules

397

(1)

4.3 Approximate Methods for Lanthanide and Actinide Molecules

398

(3)

4.3.1 Ligand Field Theory

398

(1)

4.3.2 Local Density Functional (LDF) Method

398

(2)

4.3.3 Neglect of Differential Overlap/ Spin-Orbit CI Method (INDO/S-CI)

400

(1)

4.4 Electronic Structure of Lanthanide Hydrides

401

4.4.1 YH and ScH

401

(6)

4.4.2 YH(2) and ScH(2)

407

(5)

4.4.3 Electronic States of LaH

412

(4)

4.4.4 LaH(+)

416

(5)

4.4.5 LaH(2)(+)

421

(5)

4.4.6 LaH(2)

426

(5)

4.4.7 HfH, ZrH, and TiH

431

(10)

4.4.8 HfH(2) and ZrH(2)

441

(7)

4.4.9 UH, UH(+), and UH(-)

448

(1)

4.4.10 AcH, TmH, LuH, and LrH

449

(2)

4.4.11 Ground-State Properties of Lanthanide Hydrides

451

(1)

4.5 Electronic States of Diatomic Lanthanide and Actinide Halides

452

(8)

4.5.1 LaF

453

(2)

4.5.2 YF and YCl

455

(1)

4.5.3 UF and UF(-)

456

(1)

4.5.4 Ground States of LaF-LuF

457

(3)

4.6 Lanthanide Oxides

460

(25)

4.6.1 LaO

460

(2)

4.6.2 CeO

462

(4)

4.6.3 PrO

466

(3)

4.6.4 SmO

469

(2)

4.6.5 EuO

471

(5)

4.6.6 GdO

476

(3)

4.6.7 DyO

479

(1)

4.6.8 HoO

480

(2)

4.6.9 TmO

482

(1)

4.6.10 YbO

482

(3)

4.7 Electronic Structure of Selected Lanthanide and Actinide Polyatomics

485

(18)

4.7.1 Polyatomic Oxides and Complexes

486

(3)

4.7.2 Uranocene and Actinocenes

489

(7)

4.7.3 Lanthanides and Actinides inside Carbon Cages (M@C(n), M@C(n)(+))

496

(7)

4.8 Conclusion

503

(8)

Index

511

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Relativistic Effects in Chemistry, Applications

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Author Biography

Table of Contents

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