V.2 Synthesis of nickel complexes

Similar documents
Complex Chemistry of Nickel

Chapter 25 Transition Metals and Coordination Compounds Part 2

Coordination Compounds

Electronic structure Crystal-field theory Ligand-field theory. Electronic-spectra electronic spectra of atoms

Crystal Field Theory. 2. Show the interaction between the d-orbital and the negative point charge ligands

Orbitals and energetics

RDCH 702 Lecture 4: Orbitals and energetics

Periodicity HL (answers) IB CHEMISTRY HL

Chemistry 1B. Fall Lectures Coordination Chemistry

MAJOR FIELD TEST IN CHEMISTRY SAMPLE QUESTIONS

Chemistry 1B. Fall Topics Lectures Coordination Chemistry

MULTIPLE CHOICE. Choose the one alternative that best completes the statement or answers the question.

Chapter 8. Molecular Shapes. Valence Shell Electron Pair Repulsion Theory (VSEPR) What Determines the Shape of a Molecule?

Experiment 4 Spectroscopic study of Cu(II) Complexes: Crystal Field Theory

Cr(II) or Cr 2+ Consider the octahedral complex Cr[(en) 3 ] 2+ Octahedral complex with 4 d electrons. Octahedral complex with 4 d electrons

Topics Coordination Complexes Chemistry 1B-AL, Fall 2016

Dr. Fred O. Garces Chemistry 201

Q.1 Predict what will happen when SiCl 4 is added to water.

CO-ORDINATION COMPOUNDS

Coordination Chemistry: Bonding Theories. Crystal Field Theory. Chapter 20

Crystal Field Theory

Chapter 24. Transition Metals and Coordination Compounds. Lecture Presentation. Sherril Soman Grand Valley State University

Transition Metals and Coordination Chemistry. 1. In the transition metals section chemical similarities are found within a and across a.

Chemistry 3211 Coordination Chemistry Part 3 Ligand Field and Molecular Orbital Theory

Chemistry 1B. Fall Lectures Coordination Chemistry

UNIT 9 Topic: Coordination Compounds

Q.1 Predict what will happen when SiCl 4 is added to water.

Chapter 9. Molecular Geometry and Bonding Theories

Coordination chemistry and organometallics

Page 2. Q1. Consider the reaction scheme below and answer the questions which follow.

Structure of Coordination Compounds

Inorganic Chemistry Laboratory

Coordination compounds

Experiment VI.4 - Complete Analyse

Molecular Geometry and Bonding Theories. Molecular Shapes. Molecular Shapes. Chapter 9 Part 2 November 16 th, 2004

DEFINITION. The electrostatic force of attraction between oppositely charged ions

Chemistry 1000 Lecture 26: Crystal field theory

Inorganic Chemistry Laboratory

Coordination Complexes

Coordination Complexes

Chapter 9. Molecular Geometry and Bonding Theories

Crystal Field Theory History

Transition Metals. Tuesday 09/22/15. Tuesday, September 22, 15

Other Crystal Fields

Lecture Presentation. Chapter 10 Chemical Bonding II: Molecular Shapes, Valence Bond Theory, and Molecular Orbital Theory

2 electrons 2s 2 2p 6. 8 electrons (octet rule) 3s 2 3p 6 3d 10

CHEMISTRY Topic #3: Colour in Chemistry Fall 2017 Dr. Susan Findlay See Exercises 12.1 to Fe 2 O 3 Cr 2 O 3 Co 2 O 3 TiO 2.

Topics Coordination Complexes Chemistry 1B-AL, Fall 2016

Crystal Field Theory

Chapter 21 Transition Metals and Coordination Chemistry

Chapter 21 Transition Metals and Coordination Chemistry

Test Review Unit 3_2 Chemical reactions. Fundamentals Identify the letter of the choice that best completes the statement or answers the question.

Chapter 20 d-metal complexes: electronic structures and properties

Molecular Geometry and Bonding Theories. Chapter 9

Chapter 10: Chemical Bonding II. Bonding Theories

AP CHEMISTRY CHAPTERS 5 & 6 Problem Set #4. (Questions 1-13) Choose the letter that best answers the question or completes the statement.

Quiz 5 R = lit-atm/mol-k 1 (25) R = J/mol-K 2 (25) 3 (25) c = X 10 8 m/s 4 (25)

TRANSITION METAL COMPLEXES OF BENZOYL ACETONE GLYCINE (L''H2)

Bonding in Octahedral and Tetrahedral Metal Complexes. Predict how the d orbitals are affected by the Metal- Ligand Bonding

Review questions CHAPTER 5. Practice exercises 5.1 F F 5.3

What Do Molecules Look Like?

Spectrochemical Series of some d-block Transition Metal Complexes


Chapter 9 Molecular Geometry and Bonding Theories

1 A. That the reaction is endothermic when proceeding in the left to right direction as written.

I. Multiple Choice Questions (Type-I) ] 2+, logk = [Cu(NH 3 ) 4 O) 4. ] 2+, logk = 8.9

Coordination Chemistry II: Bonding

Chapter 9. Molecular Geometry and Bonding Theories

Bonding in Transition Metal Compounds Oxidation States and Bonding

Chapter 9: Molecular Geometries and Bonding Theories Learning Outcomes: Predict the three-dimensional shapes of molecules using the VSEPR model.

Complexes that undergo complete ligand exchange within 1 minute at 25 C are labile. Henry Taube ( ), Nobel laureate of 1983

Topics in the November 2014 Exam Paper for CHEM1101

EXP. 10 SPECTROSCOPY OF TRANSITION METAL COMPLEXES

Q.1 Predict what will happen when SiCl 4 is added to water.

UNIT II ATOMIC STRUCTURE

COVALENT BONDING: ORBITALS

401 Unit 3 Exam Spring 2018 (Buffers, Titrations, Ksp, & Transition Metals)

Ch. 9- Molecular Geometry and Bonding Theories

IIT-JEE 2012 PAPER - 2 PART - II : CHEMISTRY. SECTION - I : Single Correct Answer Type

Chapter 9 Molecular Geometry. Lewis Theory-VSEPR Valence Bond Theory Molecular Orbital Theory

Chapter 9. Covalent Bonding: Orbitals

Chapter 9. Molecular Geometries and Bonding Theories. Lecture Presentation. John D. Bookstaver St. Charles Community College Cottleville, MO

Chapter 9: Molecular Geometry and Bonding Theories

16. NO 3, 5 + 3(6) + 1 = 24 e. 22. HCN, = 10 valence electrons

Can atomic orbitals explain these shapes or angles? What s in Chapter 9: Shapes of molecules affect: reactivity physical properties

Downloaded from

CHEM N-3 November Transition metals are often found in coordination complexes such as [NiCl 4 ] 2. What is a complex?

Lecture 11 Reaction Types and Mechanisms for Inorganic Complexes

Objective of this experiment: to study paramagnetism and colours in transition metals; optical isomerism; co-operative research.

Downloaded from

Bonding. Honors Chemistry 412 Chapter 6

Chapter 21 Coordination chemistry: reactions of complexes

Practice Final # Jim and Tim s Excellent Adventure s in Final Exam Preparation. Practice Final

Lesson Plan. Lesson: Shape of Molecules. Aim: To investigate the shapes of molecules and ions. Learning Outcomes :

Chemistry 222 Winter 2012 Oregon State University Exam 1 February 2, 2012 Drs. Nafshun, Ferguson, and Watson

NAME: SECOND EXAMINATION

Experiment 5. Studying the Spectrochemical Series: Crystal Fields of Cr(III)

PSI AP Chemistry Solutions Practice Problems

ADVANCED INORGANIC CHEMISTRY EXPERIMENT 1. Synthesis and Characterization of Hexamminechromium (III) nitrate [Cr(NH 3 ) 6 ](NO 3 ) 3

Kinetics and reaction mechanisms in coordination compounds

Transcription:

V.2 Synthesis of nickel complexes Introduction: The nickel ion in nickel(ii)-complexes exists in the coordination number of 4, 5 and 6. Its octahedral, trigonal-bipyramidal, quadratic-pyramidal and tetrahedral complexes are paramagnetic and have in the majority of cases a green or blue colour. The quadratic-planar nickel complexes are diamagnetic and mostly have a yellow, red or brown colour. The synthesis of nickel(ii)-complexes passes over ligand substitution reactions where one or several ligands are replaced by other ones. These reactions are equilibrium reactions. Essential for the building of a new complex is the complex building constant (stability constant). In all the following reactions a more basic ligand is removed by a lower basic one or a less dentate one by a more dentate one. The whole experiment is done in a single botton. At the end of the experiment a very stable Ni-EDTA complex will be built. It will also be discussed how to get the used NiCl 2 back (recycling). Execution: 1.1 2,00g (8,4 mmol) NiCl 2 *6H 2 O are solved into 20ml water in a round bottom flask. Concentrated NH 3 is dropped in until a temporary appearing precipitate is completely solved. The solution is no clear and has a deep blue colour caused by the built hexaamminnickel complex. The passing reactions are the followings: NiCl 2 + 6 H 2 O [Ni(H 2 O) 6 ]Cl 2 [Ni(H 2 O) 6 ]Cl 2 + 2 NH 3 Ni(OH) 2 + 2NH 4 + + 4 H 2 O Ni(OH)2 + 4 NH 3 + 2 NH 4 + [Ni(NH3)6] 2+ + 6 H2O 1.2 The solution is heated until boiling and a solution of 1,66 g (10 mmol) K 2 C 2 O 4 *H 2 O is added. Afterwards the solution is cooled down for two hours in the fridge. Turquoise crystals of a oxalatenickel complex are precipitating. [Ni(NH3) 6 ] 2+ + 2 C 2 O 4 2- [Ni(C 2 O 4 ) 2 ] 2- + 6 NH 3 1.3 The solution is again warmed up on room temperature and a solution of 1,85 g (24,6 mmol) glycin H 2 NCH 2 COOH (Hgly) and a few drops of concentrated ammoniac are added. The colour of the solution is turning into a clear light blue of nickel glycinate. [Ni(C 2 O 4 ) 2 ] 2- + 2 Hgly [Ni(gly) 2 ] + 2 C 2 O 4 2- + 2 H + 1.4 2,36 ml (25,2 mmol) of acetylacetone are dropped into the solution. During 10 minutes the solutions is stirred while a complex of light blue nickel acetylacetonate is precipitating. [Ni(gly) 2 ] + 2 Hacac [Ni(acac) 2 ] + 2 gly - + 2 H + Date: 29.01.2009 Page 1

1.5 A solution of 2,92 g (25,2 mmol) dimethylglyoxime (H 2 dmg) HON=C(CH 3 )- C(CH 3 )=NOH in diluted NaOH is added to the suspension. Thereby the Ni(acac)2 precipitate is converted into a raspberry red precipitate of bis(dimethylglyoximato)nickel(ii). [Ni(acac) 2 ] + 2 H 2 dmg [Ni(Hdmg) 2 ] + 2 acac - + 2 H + 1.6 By an addition of 30% NaOH the ph is raised onto 12. A solution of 6,26 g (16,8 mmol) Na 2 H 2 EDTA in water is added and cooked on reflux until a clear blue solution of NiEDTA appears. [Ni(Hdmg)2] + Na 2 H 2 EDTA [Ni(EDTA)] 2- + 2 Hdmg + 2 Na + + 2 H + Recycling: The NiEDTA complex synthesized in the last step is dangerous for the environment even if it is a very stable one. When the EDTA is broke down by micro organisms toxic Ni 2+ gets free. To avoid this case NiEDTA undergoes a recycling process. First of all the NiEDTA solution is made highly acidic (ph<1) by adding concentrated H 2 SO 4 until a green colour of the fluid phase and a precipitation of the organic ligand molecules is observed. [Ni(EDTA)] 2- + 2 H 2 SO 4 + 6 H 2 O [Ni(H 2 O) 6 ] 2+ + H 4 EDTA + 2 SO 4 2- The solution is filtered and to the fluid phase are added 5 g of an activated carbon powder. Subsequently the suspension is boiled and filtered hot. After the filtration another 5 g of activated carbon are added. 35 ml of 30% H 2 O 2 are added to the solution and the whole thing is stirred for an hour. Then the solution is heated until boiling and filtered hotly. NaOH is added to the filtrate until the ph has reached a value of 11-12. Light green Ni(OH) 2 is precipitating. [Ni(H 2 O) 6 ] 2+ + 2 NaOH Ni(OH) 2 + 2 Na + + 6 H 2 O The precipitate is separated, washed sulphate free and solved in HCl. The resulting solution is evaporated so only the yellow NiCl 2 is remaining. After a few day on air the colour of the salt turns into green because the [Ni(H 2 O) 6 ]Cl 2 complex is built. Ni(OH) 2 + 2 HCl Ni 2+ + 2 H 2 O + 2Cl - Ni 2+ + 2 H 2 O + 2Cl - NiCl 2 + 2 H 2 O Date: 29.01.2009 Page 2

Structure and colour The bonding between the centred atom and the ligand in metal complexes are the result of electron donor and acceptor interactions. The centred metal atom represents a Lewis acid and the ligand a Lewis base. From the negative charged ligand acts a repulsing force on the electron orbitals of the centred atom. On the other hand the positive charge of the centred atom affects an attracting force on the ligand. As well as the repulsing force of the negative charged ligand has no energetic effect on the spherical-symmetrical s-orbital of the centred metal ion, it has an energetic effect on the d-orbitals. Depending on the structure, diameter and charge of the ligand the energy of some d-orbitals is raised and of some others it is abased, means the orbitals are heavier or easier to fill up with electrons. According to the Hund rule the orbitals with the lowest energy are filled firstly. If the spin matching energy is higher than the single occupying one for the orbital with the highest energy, all orbitals firstly are filled with a single electron. The resulting complex has high spin. The octahedral and tetrahedral complexes in fig. 2.0 are examples for high spin complexes. All orbitals are firstly filled single. If the spin matching energy is lower than the double occupying one for the orbital with the lowest energy, some orbitals will already been filled double while some orbitals are not yet singly occupied and the complex has low spin. The quadratic-planar complex in fig. 2.0 is an example for such a low spin complex. The high and low spin model also explains magnetic behaviour of metal complexes. The tetrahedral and octahedral complexes in fig. 2.0 both are paramagnetic, means have no magnetic effect. This is caused by the homogenous distribution of the electrons over the whole complex. The quadratic-planar complex is diamagnetic. Its electrons are not homogenously distributed over the complex. The double occupancy of some orbitals while others are still unoccupied results in majority of electrons on one side. The complex this way gets a negative charge on one side while the other side appears positively charged. This division of charge gives the complex two poles of different charge what makes him diamagnetic. fig. 2.0 Date: 29.01.2009 Page 3

With the ligand field theory also the colour of complexes can be explained. The electrons in a complex can be transferred form a low energy orbital into a higher energetic one. Therefore a specific amount of energy is needed. This energy is calculated as d = h*λ where h is the Plank constant and λ the wave length of an electromagnetic ray. The energy of d depends on the mass of the ligand field splitting which is dependent on the structure, charge and diameter of the ligand. This means that a strong ligand for example splits the ligand field more than a weak one and the activating energy to move an electron from a lower energy state into a higher is bigger. The energy for transferring an electron into a higher energetic orbital is taken from electromagnetic waves. If a complex absorbs a wavelength within the visible spectrum the complex appears coloured. Important is to notice that the observed colour of a complex is the complementary colour to the colour of wavelength by the complex. The NiEDTA complex for example absorbs red light so it appears green. Complex stability The reactions in this experiment are all ordered the way every next complex is more stable than the previous. The hexaaquanickel complex is the least stable one, NiEDTA is the most stable one. This means that the complex stability constant for every next synthesized complex is higher than for the previous. A higher complex stability is either reached by a stronger ligand substituting a weaker one like it is the case when hexaamminnickel is synthesized from hexaaquanickel or by a higher dentate ligand replacing a lower dentate one. The strength of a ligand is given from its acidity as Lewis acid. A less basic ligand is a more acidic ligand and as this a stronger one. Multiple dentate ligands, so called chelat ligands, form more stable complexe because of the entropy effect. This is explained as following: When a few single ligands are substituted by a chelat ligand the entropy of the system arises because the number of products is higher than the number of educts. A back reaction is more improbable because therefore a few ligands have to replace one chelat ligand at the same time where the chelat ligand himself can replace a few ligands at any time. The substituting reaction from single ligands by a chelat ligand happens then more often than the back reaction what makes the complex stable. Below, there are demonstrated the structures of the synthesized complexes in this experiment. 2+ [Ni(H 2 O) 6 ] 2+ Octahedral [Ni(NH 3 ) 6 ] 2+ Octahedral Date: 29.01.2009 Page 4

[Ni(C 2 O 4 ) 2 ] 2- Quadratic-planar [Ni(acac) 2 ] Tetrahedral [Ni(Hdmg) 2 ] Quadratic-planar [Ni(EDTA)] 2- Octahedral [Ni(gly) 2 ] Quadratic-planar Date: 29.01.2009 Page 5

Date: 29.01.2009 Page 6

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback