Welcome to the blog of the project entitled "Asymmetric organocatalysts for remote functionalization strategies" (REMOTEcat).
The aim of this blog is to disseminate the basic principles of asymmetric catalysis and its relevance in chemistry to non-specialists.
This blog reflects only the author's view. EU is not liable for any use that may be made of the information contained herein.
This research is supported by a Marie Curie Action
This research has received funding from the People Programme (Marie Curie Actions) of the EU (FP7/2007-2013) under REA grant agreement nº PIEF-GA-2013-622413
REMOTEcat is the acronym for the project entitled
"Asymmetric organocatalysts for remote functionalization strategies" funded
by the People Programme (Marie Curie Actions) of the EU. Currently, I am
carrying out this project at the Center for Catalysis (Department of Chemistry, Aarhus University,
Denmark) under the supervision of Prof. Karl Anker Jørgensen.
In line with EU research & innovation policy, REMOTEcat assumes
that responsible research implies an effort to the scientific promotion of
science encouraging public participation and understanding of science. The goal
is to create awareness among the public about the research work performed in
the Marie Curie Action and their implications in society.
About the project REMOTEcat is a chemistry project. In particular,
organic chemistry, and in more detail, asymmetric organocatalysis.
Many chemical processes would not occur (at least, not at a rate that has any practical application) without catalysts. Catalysts (i.e. a substance that modifies the rate of a chemical reaction) have thus become indispensable in a wide range of industrial reactions. But the study of these systems can offer much more: it can change our understanding of fundamental chemical concepts and challenge us to rethink the “rules” of the chemical world.
In general, enantioselective catalysis (usually known as asymmetric catalysis) mostly refers to the use of chiral metal catalysts. It is very commonly encountered, as it is effective for a broader range of transformations than any other synthetic methods. Small organic molecules without metals can also exhibit catalytic properties, In the early 2000s, these organocatalysts were considered "new generation" and are competitive to traditional metal-containing catalysts.
Research in the area of organocatalysis moves at breathtaking speed: many catalytic reactions now considered to be “standard issue” by organic chemists were almost unthinkable just 10 years ago. The ability to synthesize and selectively modify small organic molecules is crucial for many applications, including drug discovery and the search for new materials. The development of new organocatalysts often makes it possible to generate previously unattainable compounds, which could have unique physical, chemical or biological properties.
Why am I launching this blog?
Probably, there are too many weird words in just only a few lines above. However, do not be concerned
about this. The idea of launching this blog is to build bridges between the
research I am doing and non-specialists. It is science for non-scientists.
What I would like to do is
to introduce the basic concepts of organic chemistry involved in the project through
case examples and situations of our daily lives. Gradually, and later on, going
into more details about the research carried out in the project in the most entertaining manner possible
and understandable to everyone.
Hope you find interesting and understandable the contents of the blog. Any comments or suggestions for their improvement are welcome.