Electronic Supplementary Information

Similar documents
Supporting Information

Chapter 6: Chemical Bonding

WYSE Academic Challenge 2004 Sectional Chemistry Solution Set

Solutions Solubility. Chapter 14

Supplementary Material. Synthesis of novel C-2 substituted imidazoline derivatives having the norbornene/dibenzobarrelene skeletons

AP Chemistry Review Packet # form B. How many grams of water are present in 1.00 mol of copper(ii) sulfate pentahydrate?

Hydrated nickel(ii) salts are green in colour. Give the electron configuration of a nickel(ii) ion and hence state why the ion is coloured.

SUPPLEMENTARY INFORMATION

CHEMISTRY. SCIENCE Paper 2

Supplementary information

Electronic supplementary information. Strong CIE activity, multi-stimuli-responsive fluorescence and data

Acid Base Equilibria

CHEMISTRY HIGHER LEVEL

Chapter 4. Aqueous Reactions and Solution Stoichiometry

Cyclams with ambidentate methylthiazolyl pendants for a stable, inert and selective Cu(II) coordination

Energy Intro. How do we access chemical energy? Why do combustion reactions give off energy?

Funsheet 9.1 [VSEPR] Gu 2015

,

A dynamic, luminescent and entangled MOF as a qualitative sensor for volatile. organic solvents and quantitative monitor for acetonitrile vapour

Synthesis of 1,2-glycerol carbonate from carbon dioxide: the role of methanol in fluid phase equilibrium

CHM151 Quiz Pts Fall 2013 Name: Due at time of final exam. Provide explanations for your answers.

Synthesis and characterization of a new triptycene based tripod

Multiple Choice. Multiple Choice

IB Topics 5 & 15 Multiple Choice Practice

Bistriazole-p-benzoquinone and its alkali salts: electrochemical behaviour in aqueous alkaline solutions

Stoichiometry: Chemical Calculations. Chemistry is concerned with the properties and the interchange of matter by reaction i.e. structure and change.

Chapter 4 Reactions in Aqueous Solutions. Copyright McGraw-Hill

Chemical Reaction Defn: Chemical Reaction: when starting chemical species form different chemicals.

Sectional Solutions Key

H = Hydrogen atoms O = Oxygen atoms

Mechanisms. . CCl2 F + Cl.

Supplementary Information. Two Cyclotriveratrylene Metal-Organic Frameworks as Effective Catalysts

Selective total encapsulation of the sulfate anion by neutral nano-jars

MODEL QUESTION PAPER FOR SUMMATIVE ASSESSMENT CHEMISTRY PART-A

Chemical Equilibrium. Many reactions are, i.e. they can occur in either direction. A + B AB or AB A + B

Chapter 4. Reactions in Aqueous Solution

# Ans Workings / Remarks

CHEMpossible. Final Exam Review

CHEMISTRY HIGHER LEVEL

CH 221 Chapter Four Part II Concept Guide

Supplementary Figures

Review for Chemistry Final Exam [Chapters 1-9 & 12]

Chemical Equilibrium

AP Chemistry Big Idea Review

Chapter 4 Reactions in Aqueous Solution

Chapter 7 Solution Chemistry. 7.1 The Nature of Solutions. Warm Up (p. 364) and Quick Check (p. 365)

Chapter 12: Chemical Equilibrium The Extent of Chemical Reactions

ed. Brad Collins Aqueous Chemistry Chapter 5 Some images copyright The McGraw-Hill Companies, Inc. Sunday, August 18, 13

Lecture 5. Percent Composition. etc. Professor Hicks General Chemistry II (CHE132) Percent Composition. (aka percent by mass) 100 g.

SIR MICHELANGELO REFALO SIXTH FORM Half-Yearly Exam 2016

Chemistry 104 Final Exam Content Evaluation and Preparation for General Chemistry I Material

Cambridge International Examinations Cambridge Pre-U Certificate

A Highly Active Gold(I)-Silver(I) Oxo Cluster Activating sp 3 C-H. Bonds of Methyl Ketones under Mild Conditions

Acid-Base Strength. Chapter 6. Monday, November 2, 2015

Supporting Information

Chapter 4: Types of Chemical Reactions and Solution Stoichiometry

Appendix A. Supplementary Information. Design, synthesis and photophysical properties of 8-hydroxyquinoline-functionalized

Electronic Supplementary Material

The Copper Cycle. HCl(aq) H + (aq) + Cl (aq) HCl(aq) + H 2 O(l) H 3 O + (aq) + Cl (aq)

Sect 7.1 Chemical Systems in Balance HMWK: Read pages

2. Which of the following liquids would have the highest viscosity at 25 C? A) CH 3 OCH 3 B) CH 2 Cl 2 C) C 2 H 5 OH D) CH 3 Br E) HOCH 2 CH 2 OH

REACTIONS IN AQUEOUS SOLUTIONS

For more sample papers visit : CHEMISTRY. Paper 1 (THEORY) (Three Hours)

Downloaded from ijcm.ir at 21: on Thursday March 7th 2019

CLEP Chemistry Practice Test

I Write the reference number of the correct answer in the Answer Sheet below.

Ions in Solution. Solvent and Solute

Chemical Equations. Chemical Reactions. The Hindenburg Reaction 5/25/11

Chemistry 223 Spring 2012 Oregon State University Exam 2 May 24, 2012 Drs. Nafshun, Watson, Richardson

Cambridge International Examinations Cambridge International Advanced Subsidiary and Advanced Level

Name:. Correct Questions = Wrong Questions =.. Unattempt Questions = Marks =

2.) Calculate the ph of a 0.641M solution of barium hydroxide. Assume that pk w = for the conditions under which the solution was prepared.

Chapter 6. Types of Chemical Reactions and Solution Stoichiometry

least reactive magnesium

TYPES OF CHEMICAL REACTIONS

Practice Test - Chapter 13, 14, 15

Lesson 01 and 02: Solutions, Solubility and Conductivity. 01 What is a Solution?

Assessment Schedule 2017 Scholarship Chemistry (93102)

CHAPTER 4 TYPES OF CHEMICAL EQUATIONS AND SOLUTION STOICHIOMETRY

Halogen halogen interactions in diiodo-xylenes

7/16/2012. Chapter Four: Like Dissolve Like. The Water Molecule. Ionic Compounds in Water. General Properties of Aqueous Solutions

Properties of Compounds

What is the correct name and bonding of BF 3? What is the correct name and bonding of BF 3?

1. (8 pts) Circle the formula (only one) that best fits each of the following descriptions:

Wed Sep 5, Characteristics of Water

LISTA DE EXERCÍCIOS AULA 06/10/2016

Solubility Rules See also Table 4.1 in text and Appendix G in Lab Manual

Quiz I: Thermodynamics

2.1) Name the following 4 compounds: [1 point each, 4 total] 2.2) Draw the following compounds in the box provided [1 point each, 4 total]

Chapter 4 - Types of Chemical Reactions and Solution Chemistry

Full file at Chapter 2 Water: The Solvent for Biochemical Reactions

Ch 100: Fundamentals for Chemistry

Exam 1 Chemistry 112 October 7, Part I- Multiple Choice (3 points each). Please choose the single correct answer.

Supplementary Figure S1 X-ray crystallographic structure of (C)-(-)-6. (a) ORTEP drawing of (C)-(-)-6 at probability ellipsoids of 50%: tope view.

Chemistry 1A Fall 2010 Exam 2 Key Chapters 4 (part), 5, 6, and 7 (part)

2. What is the charge of the nucleus in an atom of oxygen-17? (1) 0 (2) 2 (3) +8 (4) +17

Brass, a solid solution of Zn and Cu, is used to make musical instruments and many other objects.

General Chemistry 1 CHM201 Unit 2 Practice Test

Transcription:

This journal is The Royal Society of Chemistry 0 Electronic Supplementary Information Zinc(II) ortho-hydroxyphenylhydrazo-β-diketonate Complexes and their Catalytic Ability towards Diastereoselective Nitroaldol (Henry) Reaction Maximilian N. opylovich, a Tatiana C. O. Mac Leod, a amran T. Mahmudov, a M. Fátima C. Guedes da Silva, a,b and Armando J. L. Pombeiro *a a Centro de Química Estrutural, Complexo I, Instituto Superior Técnico, TU Lisbon, Av. Rovisco Pais, 049 00 Lisbon, Portugal b Universidade Lusófona de Humanidades e Tecnologias, ULHT Lisbon, Av. Campo Grande nº 3, 49-04, Lisbon (Portugal) Corresponding author. E-mail addresses: pombeiro@ist.utl.pt (Armando J. L. Pombeiro).

This journal is The Royal Society of Chemistry 0 Analytical data for compounds 4. : Yield: % (based on pentane-,4-dione), black powder soluble in methanol, ethanol, acetone and insoluble in water and chloroform. Anal. Calcd for C H N O 3 (M = 0): C,.00; H, 5.45; N,.3. Found: C, 58.88; H, 5.4; N,.0. IR (Br, selected bands, cm ): 348 (NH), 309 (OH), 8 (C=O), 3 (C=O H), 599 (C=N). H NMR (300.3 MHz, DMSO-d ), δ:.4 (s, 3H, CH 3 ),.48 (s, 3H, CH 3 ),.9-. (4H, Ar H), 0.5 (s, H, OH), 4.58 (s, H, NH). 3 C{ H} NMR 5.48 MHz, DMSO-d ), δ:.5 (CH 3 ), 3. (CH 3 ), 4.9, 5.8, 0., and. (C Ar-H ), 9.3 (C Ar-NH-N ), 33. (C=N), 4.3 (C Ar-OH ), 9. and 9.4 (C=O). : Yield: 85.0 % (based on pentane-,4-dione), dark brown powder, soluble in ethanol, acetone and methanol and insoluble in water and chloroform. Anal. Calcd for C H N 3 O 5 (M=5.): C, 49.8; H, 4.8; N, 5.84. Found: C, 49.85; H, 4.; N, 5.39. IR (Br, selected bands, cm ): 34 (s, br) ν(oh), 3095 (s, br) ν(nh), 38 (s) ν(c=o), (s) ν(c=o H), 598 (s) ν(c=n) cm. H NMR (300.3 MHz, DMSO-d ): δ =.45 (s, 3H, CH 3 ),.49 (s, 3H, CH 3 ),.3.8 (m, 3H, Ar H),.55 (s, H, OH), 4. (s, H, NH). 3 C{ H} (5.48 MHz, DMSO-d ): δ =.55 (CH 3 ), 3.38 (CH 3 ), 0. (Ar H), 4.3 (Ar H),.30 (Ar H), 35.38 (C=N), 3.0 (Ar NO ), 43.5 (Ar NH N), 45. (Ar OH), 9.5 (C=O), 9.44 (C=O) ppm. 3: Yield: 5 % (based on 5,5-dimethylcyclohexane-,3-dione), dark brown powder soluble in methanol, ethanol, acetone and insoluble in water and chloroform. Anal. Calcd for C 4 H N O 3 (M = ): C, 4.; H,.5; N, 0.8. Found: C, 4.09; H,.38; N,. IR (Br, selected bands, cm ): 3 (NH), 95 (OH), 50 (C=O), (C=O H), 594 (C=N). H NMR (300.3 MHz, DMSO-d ), δ:.0 (s, H, CH 3 ),.50 (s, H, CH ),.5 (s, H, CH ),.9-.4 (3H, Ar H), 0.5 (s, H, OH), 5.5 (s, H, NH). 3 C{ H} NMR 5.48 MHz, DMSO-d ), δ: 8.0 (CH 3 ), 30.4 (CH 3 ), 5.8 (CH ), 5.8 (CH ), 38.9 (C ipso ),.0, 0.3,.3 and 8.0 (C Ar-H ), 30.3 (C Ar-NH-N ), 3.0 (C=N), 4. (C Ar-OH ), 04. and 0.0 (C=O). 4: Yield: 83 % (based on 5,5-dimethylcyclohexane-,3-dione), dark brown powder soluble in methanol, ethanol, acetone and insoluble in water and chloroform. Anal. Calcd for C 4 H 5 N 3 O 5 (M = 305): C, 55.08; H, 4.9; N, 3.. Found: C, 55.00; H, 4.98; N, 3.8. IR (Br, selected bands, cm ): 3448 (NH), 300 (OH), 5 (C=O), 8 (C=O H), 59 (C=N). H NMR (0.3 MHz, DMSO-d ), δ: 0.90-.03 (s, H, CH 3 ),.50 (s, H, CH ),. (s, H, CH ),.-.4 (3H, Ar H), 0. (s, H, OH), 4.9 (s, H, NH). 3 C{ H} NMR (00. MHz, DMSO-d ), δ: 8.0 (CH 3 ), 30.3 (CH 3 ), 5.0 (CH ), 5.0 (CH ), 38. (C ipso ), 0., 4.5, and 5.3 (C Ar-H ), 3. (C Ar-NH-N ), 3. (C=N), 44.8 (C Ar-NO), 49.0 (C Ar-OH ), 03.4 and 0.3 (C=O).

This journal is The Royal Society of Chemistry 0 X-ray data of 5 8 Table S. Selected bond distances (Å) and angles ( ) for compounds 5 8. 5 8 Coordinated ligand C O (coordinated carbonyl).4(3).4().55(4).9(8) C O (free carbonyl).3(4).().4(4).(8) N N.83(3).8().(3).8() Coordination sphere of Zn Zn N.09().03(5).05().05(4) (axial sites).3(8) 3.5().(0).0(4) (equatorial sites) 03.8(9).5(9) Zn(μ-O) Zn core 04.3() 33.3() 0.4(9) 39.39(9) 04.(5) 3.(5) ZnOZn 98.(8) - 0.(9) - OZnO 8.84(8) -.8(9) - Longest Zn O.09() -.08() - Shortest Zn O.98() -.9() - Zn Zn 3.0955() - 3.55() - -membered metallacycle OZnN 8.38(9) 83.8(9) 8.05(9) 85.(4) Zn O.05().04(4).08().04(9) 5-membered metallacycle OZnN.03(9).4(8) 9.4(8) 8.9(5) Zn O ortho.09().03(4).08().999(0) 3

This journal is The Royal Society of Chemistry 0 Table S. Relevant hydrogen bonding distances (Å) and angles (º) [d(d A) / (D H A)] in 5 8. Compound D H A d(d A) (D H A) Symmetry codes 5 O4 H4 O i.9(4) 8(5) i: -x,-y,-z O0 H0A O i.54() 50 i: -x,-y,-z O0 H0B O4 ii.8(8) 0 ii: -x,-y,-z O0 H0A O3 i.9(3) (3) i: -x,-y,-z O0 H0C O3 ii.95(3) 5(3) ii: -+x,y,z 8 O0 H0B O3.0() 3 O0 H0A O3 i.0() 9 i: -x,/+y,/-z O HB O0 ii.() 3 ii: -x,/+y,/-z O HA O iii.5(5) 59 iii: -x,-y,-z O HB O0 iv.9(9) 43 iv: x,/-y,/+z Figure S. Fragments of the crystal packing diagram of 5 (top) and (down) showing the relative arrangement of four zinc dimers which are assembled into D chains (5) or D layers () via hydrogen bonds (dotted lines). The H atoms not involved in relevant interactions are omitted for clarity. 4

This journal is The Royal Society of Chemistry 0 Figure S. Structural representation of (top) and 8 (down) showing the intermolecular H-bonds (dotted lines), which generate D chains () or, also with the aid of crystallization water molecules (shown as red ball), a 3D network (8). The H atoms, apart from those involved in H-bonds, are omitted for clarity. Thermodynamics of interaction of zinc(ii) nitrate and ligand in solution ph-metric titration: The apparatus, general conditions, and methods of calculation are the same as those given in previous works. [,5]. The following mixtures (i) (iii) were prepared and titrated potentiometrically against standard 8 mol L NaOH in % (v/v) ethanol-water mixture at 98 : (i) 5.00 ml 0 M HCl + 5.00 ml.00 M Cl + 3 ml ethanol; (ii) 5.00 ml 0 M HCl + 5.00 ml M Cl + 5.0 ml ethanol + 5.00 ml 0 M ligand; (iii) 5.00 ml 0 M HCl + 5.00 ml M Cl + 5.0 ml ethanol + 5.00 ml 0 M ligand + 5.00 ml 0 M zinc salt. 5

This journal is The Royal Society of Chemistry 0 For each mixture, the volume was made up to 5 ml with bidistilled water before the titration process. These titrations were also repeated at temperatures of 308 and 38. Calculation of the stability constant (logk) of the Zn(II)-L complex formation by the Martell- Chaberek method: 8a To determine the stability constant, the following relationships were used: 8a ( a) c [H ] + [OH ] [L ] = +, [H ] + H L + + [H ] + + α = + [H ] + [H ], L( H ) k = c H L [L [L ] α ] α L(H) L(H) where c Zn =.00 0 M, c H L =.00 0 M, and and HL ( = / and = / ) and a is the neutralization point. Dissociation constants: a p =.35 = 4.4 0 M and p = 0. =.03 0 M. Protonation constants: 0 = / = /. 03 0 =. 0 M and are the protonation constants of L = / = / 4. 4 0 =. 3 0 M. We titrated 5 ml of a solution with.00 0 M of H L and.00 0 M of Zn +, with a 8.00 0 M solution of NaOH. i) After addition of 0.50 ml of 8.00 0 M solution of NaOH to 5 ml of.00 0 M solution of Zn + +H L, we observed that ph 4.54 [H + ] = 3.4 0 and [OH ] =.88 0 0 M. Total concentration of NaOH: 0.50 ml 8.00 0 M = 50.5 ml x M Total concentration of Zn + +H L: 5 ml.00 0 M = 50.5 ml x M x 0 4 =.9 M. x 0 4 x. 9 0 Neutralization point: a = = = 0. x. 98 0 α L( H ) k = [L ] = {( a) c H L =.98 M. + + + [H ] + [OH ]}/{[H ] + [H ] -3 0 {( - 0.4) 0 3.4 0 +.88 0 } = 0 0 3.4 0. 0 + (3.4 0 ). 0.3 0 } = = 3.53 0 + = + [H ] + 0 0 + [H ] = + 3.4 0. 0 + (3.4 0 ). 0.3 0 = 4.50 0 -.00 0 3.53 0 4.50 0 - (3.53 0 ) 4.50 0 =.4 0 9 logk = 9.8. M.

This journal is The Royal Society of Chemistry 0 (See Table S3). ii) After addition of.00 ml of 8.00 0 M solution of NaOH to 5 ml of.00 0 M solution of Zn + +H L we observed that ph 4.3 [H + ] =.8 0 and [OH ] = 5.3 0 0 M. Total concentration of NaOH:.00 ml 8.00 0 M = 5.0 ml x M Total concentration of Zn + +H L: 5 ml.00 0 M = 5.0 ml x M x 0 =.5 M. x 0 x. 5 0 Neutralization point: a = = = 0. x. 9 0 α L( H ) k = = [L ] = {( a) c H L =.9 M. + + + [H ] + [OH ]}/{[H ] + [H ] -3 0 {( - 0.8) 0.8 0 + 5.3 0 } = 0 0.8 0. 0 + (.8 0 ). 0.3 0 } = = 9.9 0 + + 0 0 + [H ] + [H ] = +.8 0. 0 + (.8 0 ). 0.3 0 =.3 -.00 0 9.9 0.3 0 - (9.9 0 ).3 0 (See Table S3). iii) etc. =.4 0 9 logk = 9.8. M. 0 Table S3. Calculation of the stability constant of the zinc(ii) complex with L at 5 o C, in aqueous ethanol solution. V OH, ml a ph [H + ], M [OH ], M [L ], M α L( H ) logk 0.50 0. 4.54 3.4 0.88 0 0 3.53 0 4.50 0 9.8.00 0. 4.3.8 0 5.38 0 0 9.9 0.3 0 9.8.50.0 5.0 9. 0.0 0 9.0 0 0 3.9 0 9.8.00. 5.34 4.5 0.9 0 9 4.9 0 0 8.49 0 5 9.89.50.00 5.9.04 0 4.90 0 9 logk = 9.8 ± 4 For determination of the thermodynamic functions of the complexation reaction, the following well known relationships were used: 8b G o ο =.303RTlogk; ΔH = {R(logk (T ) logk(t ) )}/{(/T3 ) (/T )}; S o = ( H o G o )/T. 3

This journal is The Royal Society of Chemistry 0 Table S4. Thermodynamic characteristics of the formation of the complex of Zn(II) with L in aqueous ethanol solution. T, logk G o, kj mol H o, kj mol S o, J mol 98±0.5 9.8±4.±0.4 8.05±.8 308±0.5 9.8± 3.8±.8 38±0.5 9.5± Thermal decomposition of 8 00 TG -.0 0-4.0 0 00 00 300 0 500 0 Deriv. Weight (mg/min) 00 TG 0 0 00 00 300 0 500 0 5-0. -0.4 Deriv. Weight (mg/min) 00 0 TG 0.4-0.4-0.8 00 00 300 0 500 0 Derivative Weight (mg/min) 00 TG 0 00 00 300 0 500 0 0.4-0.4-0.8 Derivative Weight (mg/min) 00 0 TG -0.4-0.8 -. 00 00 300 0 500 0 Derivative Weight (mg/min) 00 TG 0 00 00 300 0 500 0 3 0.4-0.4-0.8 Derivative Weight (mg/min) 8

This journal is The Royal Society of Chemistry 0 00 0 TG 4.0-4.0-8.0 00 00 300 0 500 0 Derivative Weight (mg/min) 00 TG 0 00 00 300 0 500 0 4 8 Figure S3. TG and curves of 8. 0. -0. -0. Derivative Weight (mg/min) Table S5. Thermal behaviour of 8. Compound Temperature range, o C Weight loss, % peak temperature ( o C) 9 5 54 94 3 33 940 8.0 30 3 08 3 3 4 940 50 30 90.0 5 045.0 3 333 45 0 348 39 5 44 34584 30 83 5.0 3 388 4 3 399.0 88 8 3 3.0 8 384 0 33 9

This journal is The Royal Society of Chemistry 0 Catalytic studies 00 Yield (%) 0 0 complex ligand 0 0 0 30 50 Time (h) Figure S4. Accumulation of β-nitroalkanol (along the initial 48 h) in the Henry reaction of benzaldehyde and nitroethane, catalyzed by complex ( ) and ligand ( ). Table S. Variation of benzaldehyde concentration with time Time, h 3 5 0 4 [benzaldehyde], mol L - 0.5 0.5 0.45 0.3 0. ln[benzaldehyde], mol L - -0.5-0.5-0. -.4 -. ln[benzaldehyde], mol L - 0-0. -0.4-0. -0.8 -.0 -. -.4 -. -.8 5 0 5 0 5 30 y = -454x 0.54 R = 0.993 Time, h Figure S5. Plot of ln[benzaldehyde] vs. time. 0

This journal is The Royal Society of Chemistry 0 A 0.8 0. 3 4 5 + benzaldehyde + nitroethane 5 + benzaldehyde 0.4 0. 5 + nitroethane 0 35 85 30 335 3 385 435 4 λ, nm Figure S. UV-vis spectra of starting materials and products for the Henry reaction: benzaldehyde (), nitroethane (), benzaldehyde + nitroethane (3), (4), benzaldehyde + nitroethane + (5), 5 (), benzaldehyde + nitroethane + 5 (); [benzaldehyde] = [nitroethane] = 4.00 0 M, [5] = [] =.00 0 M in methanol. A.3. 0.9 4 h h 30 min 0 min 0. 0.5 0.3 0. 0 5 45 45 435 λ, nm Figure S. UV-vis monitoring of Henry reaction: [benzaldehyde] = [nitroethane] = 4.00 0 M; [] =.00 0 M in methanol.

This journal is The Royal Society of Chemistry 0 Calculation of the yield and selectivity for complex in the Henry reaction Total amount of compounds (see Fig. S): Bezaldehyde + erythro + threo = 0.3 +. +.8 = 9. Percentage of the unreacted bezaldehyde: 9. ----------------------- 00 % x =.4 % 0.3 ----------------------x Conversion of benzaldehyde = yield of β-nitroalkanols = 00.4 = 9. %. Yield of erythro: 9. ----------------------- 00 %. ----------------------x x = 3. % Yield of threo: 9. ----------------------- 00 %.8 ----------------------x x = 4.5 %. See Table, Entry 9. Selectivity: Sum of erythro + threo = 3. + 4.5 = 9.. Selectivity of erythro: 9. ----------------------- 00 % 3. ----------------------x x = 4 %. Selectivity of threo: 9. ----------------------- 00 % 4.5 ----------------------x x = %.

This journal is The Royal Society of Chemistry 0 Figure S8. Example of integration in the H NMR spectrum for the determination of Henry reaction products (Table, Entry 9). Table S. Compositon of some catalysts from Table Reference f Lanthanum (La(O i Pr) 3 )/sodium source/amide ligand heterobimetallic catalyst f Neodymium (Nd(O i Pr) 3 )/sodium source/amide ligand heterobimetallic catalyst g Rh complex in the presence of a silyl ketene acetal 3

This journal is The Royal Society of Chemistry 0 n Chiral binuclear Cu(II) Schiff base complexes o,,3,3-tetramethyl guanidine (TMG)-based ionic liquid m Zn Brucine-derived aminoalcohol p Ferrocenyl-substituted aziridinylmethanol (Fam) as a catalyst with Zn c Phenoxide substituted Cu complex r Mono ethylenediamine Zn complex 4

This journal is The Royal Society of Chemistry 0 s Zn(II) complexes with chiral guanidine ligands RHN t N NH O HN O HN O NHR R= O CH 3CH3 C C O CH 3 RHN NHR 3 Tertiary amines dendritically encapsulated within a flexible peptidic shell 5

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