TY  - CONF
AU  - Filipović, Ana
AU  - Džambaski, Zdravko
AU  - Bondžić, Bojan
PY  - 2022
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/7082
AB  - In recent years, the application of microfluidic devices demonstrated significant promise as a novel method in organic chemistry. One of the research fields in which microfluidics have shown a great potential is visible light photoredox catalysis. The implementation of microreactors offers considerable advantages over the batch reactor as follows: a more predictable reaction scale-up, ecreased safety hazards, preserves atom economy, improved reproducibility and yields, and decreased energy consumption. The high surface-area-to-volume ratios provide more efficient irradiation of a reaction mixture, reduction of irradiation times, and hence prevention of undesired side reactions. As a result, enhanced selectivity, product purity, and lower catalyst loading are achieved, which leads to overall more sustainable and greener processes. Even though significant rogress has been achieved, greener alternatives to many common industrial processes still remain elusive, especially in the fine chemicals industry. To perform rocesses greener and cheaper, catalysis is a key tool to reduce energy consumption and develop more atom-economical transformations. To show the potential use of 
microdevices in organic synthesis, we have applied microfluidic chemistry in mutual photoredox and organocatalytic synthesis of the functionalized tetrahydroisoquinoline, a biologically active compound with interesting pharmaceutical properties. The results obtained in microreactor devices were compared with those obtained in batch reactions and it was demonstrated that microreactors can achieve superb yields and decreased waste generation. Thus, microflow photochemistry unambiguously has demonstrated its superiority over conventional reactor systems and its potential as green technology in synthesis processes.
PB  - Zagreb, Croatia : Faculty of Food Technology and Biotechnology,  University of Zagreb
C3  - Book of abstracts - Natural resources, green technology and sustainable development - 4-GREEN2022, 14-16 September 2022, Zagreb, Croatia
T1  - Microreactor technology for green and sustainable photo– and organo– catalytic synthesis
SP  - 129
EP  - 129
UR  - https://hdl.handle.net/21.15107/rcub_cer_7082
ER  - 

@conference{
author = "Filipović, Ana and Džambaski, Zdravko and Bondžić, Bojan",
year = "2022",
abstract = "In recent years, the application of microfluidic devices demonstrated significant promise as a novel method in organic chemistry. One of the research fields in which microfluidics have shown a great potential is visible light photoredox catalysis. The implementation of microreactors offers considerable advantages over the batch reactor as follows: a more predictable reaction scale-up, ecreased safety hazards, preserves atom economy, improved reproducibility and yields, and decreased energy consumption. The high surface-area-to-volume ratios provide more efficient irradiation of a reaction mixture, reduction of irradiation times, and hence prevention of undesired side reactions. As a result, enhanced selectivity, product purity, and lower catalyst loading are achieved, which leads to overall more sustainable and greener processes. Even though significant rogress has been achieved, greener alternatives to many common industrial processes still remain elusive, especially in the fine chemicals industry. To perform rocesses greener and cheaper, catalysis is a key tool to reduce energy consumption and develop more atom-economical transformations. To show the potential use of 
microdevices in organic synthesis, we have applied microfluidic chemistry in mutual photoredox and organocatalytic synthesis of the functionalized tetrahydroisoquinoline, a biologically active compound with interesting pharmaceutical properties. The results obtained in microreactor devices were compared with those obtained in batch reactions and it was demonstrated that microreactors can achieve superb yields and decreased waste generation. Thus, microflow photochemistry unambiguously has demonstrated its superiority over conventional reactor systems and its potential as green technology in synthesis processes.",
publisher = "Zagreb, Croatia : Faculty of Food Technology and Biotechnology,  University of Zagreb",
journal = "Book of abstracts - Natural resources, green technology and sustainable development - 4-GREEN2022, 14-16 September 2022, Zagreb, Croatia",
title = "Microreactor technology for green and sustainable photo– and organo– catalytic synthesis",
pages = "129-129",
url = "https://hdl.handle.net/21.15107/rcub_cer_7082"
}

Filipović, A., Džambaski, Z.,& Bondžić, B.. (2022). Microreactor technology for green and sustainable photo– and organo– catalytic synthesis. in Book of abstracts - Natural resources, green technology and sustainable development - 4-GREEN2022, 14-16 September 2022, Zagreb, Croatia
Zagreb, Croatia : Faculty of Food Technology and Biotechnology,  University of Zagreb., 129-129.
https://hdl.handle.net/21.15107/rcub_cer_7082

Filipović A, Džambaski Z, Bondžić B. Microreactor technology for green and sustainable photo– and organo– catalytic synthesis. in Book of abstracts - Natural resources, green technology and sustainable development - 4-GREEN2022, 14-16 September 2022, Zagreb, Croatia. 2022;:129-129.
https://hdl.handle.net/21.15107/rcub_cer_7082 .

Filipović, Ana, Džambaski, Zdravko, Bondžić, Bojan, "Microreactor technology for green and sustainable photo– and organo– catalytic synthesis" in Book of abstracts - Natural resources, green technology and sustainable development - 4-GREEN2022, 14-16 September 2022, Zagreb, Croatia (2022):129-129,
https://hdl.handle.net/21.15107/rcub_cer_7082 .