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Jun.-Prof. Alex Plajer

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Jun.-Prof. Alex Plajer Jun.-Prof. Alex Plajer
Jun.-Prof. Alex Plajer


Universität Bayreuth


Berufserfahrung

seit 12/2023

Universität Bayreuth
Juniorprofessor (W1 tenure track W3) 

2021 – 2023

Freie Universität Berlin
Liebig Fellow in the environment of C. Müller and R. Haag 

2020 – 2021

University of Oxford
1851 fellow in the group of C. K. Williams 

2016 – 2020 

University of Cambridge
Ph.D. in the group of D. S. Wright and J. R. Nitschke supported by a “Cambridge trust vice chancellor scholarship” 


Ausbildung

2015  – 2016 

University of Cambridge 
M.Phil. in the group of D. S. Wright 

2012 – 2015

Ruprecht-Karls-University Heidelberg
B.Sc. chemistry (grade: 1.1; 1st/79) 


Auszeichnungen und andere Verantwortlichkeiten

  • DFG Individual Grant
  • Daimler and Benz Foundation Scholarship
  • START initiative funding from the FUB senate
  • Project leader in the CRC 1349
  • Liebig fellowship of the association of the chemical industry
  • Royal commission for the exhibition of 1851 research fellowship
  • Cambridge trust vice-chancellor Ph.D. scholarship
  • Karl-Ziegler and Selwyn college travel grants; RSC Dalton talk award
  • Goetz Durand B.Sc. award; GDCH, DPG and BASF Abitur award
Jun.-Prof. Alex Plajer


Universität Bayreuth


  • Sulfur containing polymers:
    Sulfur-containing polymers can exhibit improved semi-crystallinity, recyclability and degradability in comparison to their all-oxygen-containing counterparts, as well as unique properties such as high refractive indices rendering them, for example, as useful components in optical applications. In this regard the work in our group concerns ring-opening copolymerization of a strained heterocycle such as epoxides and oxetanes with sulfur containing comonomers such as carbon disulfide, thioanhydrides and even elemental sulfur itself, a waste product of the petrochemical industry. Other than completely turning catalysis upside down compared to traditional ring-opening polymerisation the resulting materials allow for exciting materials applications such as in dynamic covalent networks or crystallisation driven self-assembly.
  • Fluorine containing polymers:
    Fluorinated polymers are not only popular materials in a wide range of consumer applications but are currently irreplaceable in many industries. The low polarizability of the fluorine groups, for example, renders these polymers more hydrophobic and less adhesive than their non-fluorinated counterparts, making them useful as water repellents and low-friction surface coatings. Unfortunately, these materials have come under much scrutiny for being “forever chemicals,” meaning they do not appreciably degrade in the environment over time. As part of the CRC 1349, we succeeded in synthesizing degradable fluorinated polyesters that exhibit the classic benefits of fluorinated polymers but remain degradable. Furthermore, they enable chemical recycling methods to extract and recover the fluorine into a useful form once again.
  • Transition metal containing polymers:
    Non-covalent interactions, such as hydrogen bonding or π-π interactions, confer the most extraordinary properties to polymer materials. However, a scarcely explored interaction in macromolecular chemistry is the metallophilic interaction. Here, complexes of late transition metals (mostly Pt, Au, or Hg) are attracted to each other by relativistically enhanced van der Waals forces. A new line of research in our group will hence focus on exploiting metallophilic interactions to construct organic-inorganic hybrid materials in which metal chains interconnect polymer chains. Employing intrinsically chiral polymers might    allow for the self-assembly of chiral superstructures for the next generation of chiral electronics,  biological sensors, or target-specific photodynamic therapeutics. Furthermore, dynamic covalent ligand sets might enable their deconstruction to aid chemical recyclability.
Jun.-Prof. Alex Plajer


Universität Bayreuth


10 ausgewählte Publikationen



Jun.-Prof. Alex Plajer


Universität Bayreuth


Jun.-Prof. Alex Plajer
Universität Bayreuth

Makromolekulare Chemie I
Universitätsstraße 30
95440 Bayreuth Germany

E-Mail: alex.plajer@uni-bayreuth.de
Homepage: Plajer Group

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