Supplementary material. Ohmic heating as a new efficient process for organic synthesis in water

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CHAPTER 5 CONVECTIVE HEAT TRANSFER COEFFICIENT

Transcription:

Supplementary material Ohmic heating as a new efficient process for organic synthesis in water Joana Pinto, a Vera L. M. Silva, a* Ana M. G. Silva, b Artur M. S. Silva, a* José C. S. Costa, c Luís M. N. B. F. Santos c*, Roger Enes, a José A. S. Cavaleiro a, António A. M. O. S. Vicente d and José A. C. Teixeira d a Department of Chemistry & QOPNA, University of Aveiro, 3810-193 Aveiro, Portugal b REQUIMTE, Department of Chemistry and Biochemistry, Faculty of Sciences, University of Porto, 4169-007, Porto, Portugal c Centro de Investigação em Química, Departamento de Química e Bioquímica, Faculdade de Ciências da Universidade do Porto, Rua Campo Alegre 687, 4169-007 Porto, Portugal d IBB-Institute for Biotechnology and Bioengineering, Centre of Biological Engineering, Universidade do Minho, Campus de Gualtar, P-4710-057 Braga, Portugal Table of Contents: 1. Ohmic heating reactor Figure S1. Schematic representation of the ohmic heating reactor apparatus..3 Figure S2. Detailed representation of the ohmic heating 50 ml glass vessel reactor. The temperature sensor is located between the heating electrodes.....4 Figure S3. Detailed representation of the ohmic heating electrodes and their dimensions.....5 Figure S4. 50 ml Glass Vessel Reactor......6 2. Results of monitoring the heating power (Temperature, Power, AC Current and AC Voltage) along the reaction heating time using the ohmic heating apparatus /methodology Figure S5. Results of monitoring the heating power (Temperature, Power, AC Current and AC Voltage) along the reaction heating time: heating of a solution of 30 mg NaCl in 25 ml of water, (c=0.02 moldm -3 )...7 Figure S6- Typical results of monitoring the heating power (Temperature, Power, AC Current and AC Voltage): charts of the Diels-Alder reaction..8 Figure S7 Results of monitoring the heating power (Temperature, Power, AC Current and AC Voltage): comparison between charts obtained for the NaCl solution (c= 0.02 moldm -3 ) and those obtained for the Diels-Alder reaction...9 Figure S8- Results of monitoring the heating power (Temperature, Power, AC Current and AC Voltage): heating of a solution of 403 mg Na 2 CO 3 in 25 ml of water (c=0.15 moldm -3 )...10 Figure S9- Typical results of monitoring the heating power (Temperature, Power, AC Current and AC Voltage): charts of the Suzuki reaction 11 Figure S10 Results of monitoring the heating power (Temperature, Power, AC Current and AC Voltage): comparison between the charts of the Na 2 CO 3 solution (c=0.15 moldm -3 ) and those of the Suzuki reaction...12 This journal is The Royal Society of Chemistry [2012] [Green Chem], [2012], [vol], 00 00 1

Figure S11 Results of monitoring the heating power (Temperature, Power, AC Current and AC Voltage): ohmic heating of NaCl solutions with different concentrations (volume of water: 25mL; position 10 on the power amplifier).13 3. NMR spectra Figure S12. 1 H NMR spectrum of compound 3 (CDCl 3 ; 300.13 MHz)......14 Figure S13. 13 C NMR spectrum of compound 3 (CDCl 3 ; 75.47 MHz).....14 Figure S14. 1 H NMR spectrum of compound 6 (DMSO-d 6 ; 300.13 MHz)....15 Figure S15. 13 C NMR spectrum of compound 6 (DMSO-d 6 ; 75.47 MHz).......16 Figure S16. 1 H NMR spectrum of compound 9 (CDCl 3 ; 300.13 MHz)....... 16 Figure S17. 13 C NMR spectrum of compound 9 (CDCl 3 ; 75.47 MHz).......17 Figure S18. 1 H NMR spectrum of compound 12(CDCl 3; 300.13 MHz)... 18 Figure S19. 13 C NMR spectrum of compound 12 (CDCl 3 ; 75.47 MHz)......19 This journal is The Royal Society of Chemistry [2012] [Green Chem], [2012], [vol], 00 00 2

1. Ohmic heating reactor (10) 1- Glass vessel reactor (1a, side arm for addition of reagents; 1b, condenser; 1c thread for water outlet pipe; 1d, thread for water inlet pipe). 2- Magnetic stirring plate and cylindrical magnetic stirrer (10 mm length) and 2a, 2b, 2c: supporters. 3-Reactor cover (PEEK, Polyether ether ketone). 3a,3b,4a,4b- Stainless steel (316) rectangular electrodes (dimensions: 40 mm length x 25 mm wide; 1 mm thickness); distance between the electrodes: 23 mm). 5- Type J glass sheathed thermocouple, (glass tube with 6mm external diameter, 4mm internal diameter and thickness 1 mm, conical at the bottom) 6- MOSFET Power amplifier (Velleman model QUBIC VPA21300MB, 2600 Watts Max, bridged mode). 7- Signal function generator (Topward function generator 8110) 8- Agilent 34972A LXI Data Acquisition / Data Logger and Switch Unit (Data acquisition of temperature, voltage, frequency, electric current and power in the reactor is done using a software application developed in Agilent VEE). Figure S1 Schematic representation of the ohmic heating reactor apparatus. This journal is The Royal Society of Chemistry [2012] [Green Chem], [2012], [vol], 00 00 3

Figure S2 Detailed representation of the ohmic heating 50 ml glass vessel reactor. The temperature sensor is located between the heating electrodes. This journal is The Royal Society of Chemistry [2012] [Green Chem], [2012], [vol], 00 00 4

60 mm 60 mm 20mm 75 mm 23mm 4 mm 40 mm 44 mm Side view 25 mm Front view 3- Reactor cover (PEEK, Polyether ether ketone). 3a,3b- Stainless steel (316) rectangular electrodes (dimensions: 40 mm length x 25 mm wide; 1 mm thickness) (for a volume of 25 ml the length of the electrode inside the solution/ reaction media is 20 mm). 4a,4b- Stainless steel rod with the electrodes. Figure S3 Detailed representation of the ohmic heating electrodes and their dimensions. This journal is The Royal Society of Chemistry [2012] [Green Chem], [2012], [vol], 00 00 5

43.8 mm 122 mm 38.8 mm Figure S4 50 ml Glass Vessel Reactor. This journal is The Royal Society of Chemistry [2012] [Green Chem], [2012], [vol], 00 00 6

2. Results of monitoring the heating power (Temperature, Power, AC Current and AC Voltage) along the reaction heating time using the ohmic heating apparatus /methodology Figure S5- Results of monitoring the heating power (Temperature, Power, AC Current and AC Voltage) along the reaction heating time: heating of a solution of 30 mg NaCl in 25 ml of water (c=0.02 moldm -3 ). This journal is The Royal Society of Chemistry [2012] [Green Chem], [2012], [vol], 00 00 7

Figure S6- Typical results of monitoring the heating power (Temperature, Power, AC Current and AC Voltage) of the Diels-Alder reaction. This journal is The Royal Society of Chemistry [2012] [Green Chem], [2012], [vol], 00 00 8

Figure S7 Results of monitoring the heating power (Temperature, Power, AC Current and AC Voltage): comparison between the results obtained for the NaCl solution (c= 0.02 moldm -3 ) and those obtained for the Diels-Alder reaction. This journal is The Royal Society of Chemistry [2012] [Green Chem], [2012], [vol], 00 00 9

Figure S8- Results of monitoring the heating power (Temperature, Power, AC Current and AC Voltage): heating of a solution of 403 mg Na 2 CO 3 in 25 ml of water (c=0.15 moldm -3 ). This journal is The Royal Society of Chemistry [2012] [Green Chem], [2012], [vol], 00 00 10

Figure S9- Typical results of monitoring the heating power (Temperature, Power, AC Current and AC Voltage) of the Suzuki reaction. This journal is The Royal Society of Chemistry [2012] [Green Chem], [2012], [vol], 00 00 11

Figure S10 Results of monitoring the heating power (Temperature, Power, AC Current and AC Voltage): comparison between the results of the Na 2 CO 3 solution (c=0.15 moldm -3 ) and those of the Suzuki reaction. This journal is The Royal Society of Chemistry [2012] [Green Chem], [2012], [vol], 00 00 12

Figure S11 Results of monitoring the heating power (Temperature, Power, AC Current and AC Voltage): ohmic heating of NaCl solutions with different concentrations (volume of water: 25 ml; position 10 on the power amplifier to reach the reflux, then the power was reduced manually to maintain the reflux). This journal is The Royal Society of Chemistry [2012] [Green Chem], [2012], [vol], 00 00 13

3. NMR Spectra 3 Figure S12. 1 H NMR spectrum of compound 3 (CDCl 3 ; 300.13 MHz). 3 Figure S13. 13 C NMR spectrum of compound 3 (CDCl 3 ; 75.47 MHz). This journal is The Royal Society of Chemistry [2012] [Green Chem], [2012], [vol], 00 00 14

6 6 6 Figure S14. 1 H NMR spectra of compound 6 (DMSO-d 6 ; 300.13 MHz). This journal is The Royal Society of Chemistry [2012] [Green Chem], [2012], [vol], 00 00 15

6 Figure S15. 13 C NMR spectrum of compound 6 (DMSO-d 6 ; 125.27 MHz). 9 Figure S16. 1 H NMR spectrum of compound 9 (CDCl 3 ; 300.13 MHz) This journal is The Royal Society of Chemistry [2012] [Green Chem], [2012], [vol], 00 00 16

9 Figure S17. 13 C NMR spectrum of compound 9 (CDCl 3 ; 75.47 MHz). This journal is The Royal Society of Chemistry [2012] [Green Chem], [2012], [vol], 00 00 17

12 22 12 Figure S18. 1 H NMR spectra of compound 12 (CDCl 3 ; 300.13 MHz). This journal is The Royal Society of Chemistry [2012] [Green Chem], [2012], [vol], 00 00 18

12 Figure S19. 13 C NMR spectrum of compound 12 (CDCl 3 ; 75.47 MHz). This journal is The Royal Society of Chemistry [2012] [Green Chem], [2012], [vol], 00 00 19

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