Boroles   –   five-­‐membered   heterocycles   with   a  boron   atom   –   are   one   of   the   more   curious  families  of  molecule.  They  have  four  π-­‐electrons,  making   them   “antiaromatic”   and,   at   least   on  paper,   unlikely   to   be   stable.   Yet,   synthetic  chemists   prepared   them   by   bulking   up   the  groups   around   the   ring,   creating   a   shield   of  aromatic   groups   that   stops   them   from  decomposing.   If   you   add   two  electrons  to  a  borole  you   increase  the   π-­‐electron   count   to   six   –  making   them   “aromatic”,   and  chemists  have  isolated  this  form  as  well.   The   group   of   Prof.   Holger   Braunschweig  wondered:   what   about   the  missing   borole  with  five  π-­‐electrons?     By  pushing  the  protection  of  the  boron  atom  to   the   extreme  and   adding   just   one  electron   to  the  molecule,  doctoral  student  Johannes  Wahler  isolated  the  5-­‐electron  borole,  a  radical  anion.  In  his   words:   “Boroles   are   real   multi-­‐talents   in  terms   of   reactivity,   which   is   governed   by   the  antiaromatic  nature  of  this  class  of  molecules.  By  the   synthesis   of   a   borole   radical   anion   we  intended   to   create   a   junction   between   the   two  

fundamental   concepts   of   aromaticity   and  antiaromaticity.”     Using   Electron   Paramagnetic   Resonance  spectroscopy,   they   showed   that   the   unpaired  electron   is   located   on   the   boron,   confirmed   by  its   reactivity   as   a   boron-­‐centred   radical.  According   to   Mr.   Wahler,   there   is   still   a   lot   of  work   to   be   done:   “Future   work   will   include  

synthesis   of   related   borole   radical   anions   and  other   fancy   borole   derivatives   -­‐   a   job   that   is  challenging   but   rewarding.”   The   results   were  published   recently   in   Angewandte   Chemie,  International  Edition.    Link  to  article:  http://onlinelibrary.wiley.com/doi/10.1002/anie.201108632/abstract    Braunschweig  Research  Group:    http://www-­‐anorganik.chemie.uni-­‐wuerzburg.de/Braunschweig/  

 

Supramolecular   interactions   –   the   way   a  molecule   interacts   with   other   molecules   –   can  have   a   huge   effect   on   the   properties   of  functional   materials.   Squaraines,   promising  molecules   for   applications   as   fluorescent   dyes,  have  both   large   flat   pi-­‐systems   ideally   suited   to  intermolecular   pi-­‐pi   stacking   and   the   possibility  for  hydrogen  bonding.       These   structural   traits   result   in   the   well-­‐known,   property-­‐altering   aggregation   of  Squaraines.  Despite   their  potential  as  molecular  materials,   no   studies   of   the   aggregation   of  squaraines  have  been  performed  in  the  absence  of  water,  which  can   interfere  with  non-­‐covalent  interactions.  Recognising  this,  the  group  of  Prof.  Dr.   Frank   Würthner   set   out   to   study   the  aggregation   of   squaraines   in   exclusively   non-­‐polar   solvents   –   conditions   where   the   weak  intermolecular  interactions  can  truly  shine.     In  a  publication  in  the  new  journal  Chemical  Science,   Dipl.   Chem.   Ulrich   Mayerhöffer   and  Prof.  Würthner  use  UV-­‐visible   spectroscopy  and  atomic   force   microscopy   (AFM)   to   study   and  visualise   the   long   fibres   of   pi-­‐pi-­‐stacked  

squaraines  that  form  in  non-­‐polar  solvents.  They  found   that   this   organisation   begins   with   the  coupling   of   two   squaraines   to   form   a   dimer,  followed  by  stacking  of   the  dimers   to   form   long  chains   about   three   nanometres   in  width,  which  eventually  clump  together  in  bundles  about  nine  nanometres  wide.    Link  to  article:  http://pubs.rsc.org/en/content/articlelanding/2012/sc/c2sc00996j  Würthner  Research  Group:  http://www-­‐organik.chemie.uni-­‐wuerzburg.de/lehrstuehlearbeitskreise/wuerthner/

 

Defects  in  polymeric  materials  like  graphene  are  unavoidable,   and   often   annoying.   But   in  graphene,   defects   can   change   the   way   the  material   responds   to   external   stimulus   –  sometimes  in  desirable  ways.       These   defects   occur   in   graphene   when   the  usual   honeycomb-­‐like   pattern   of   hexagons   is  interrupted   by   pentagons   or   heptagons.   As   we  all  learn  as  children,  there’s  no  way  to  make  flat  networks   of   pentagons   or   heptagons,   so   these  defects  create  blisters   in  an  otherwise  dead-­‐flat  sheet  of  carbon  atoms.     To   study   how   such   a   defect   disturbs   the  electronic  and  magnetic  properties  of  graphene,  the   group   of   Prof.   Dr.   Anke   Krueger   has  targetted   an   isolated,   molecular   version   of   the  irregularity,   a   “defective   graphite   flake”   with   a  tribenzotriquinacene  core.  But  while  the  defects  occur   naturally   in   graphene,   synthesising   a  molecular  version  is  very  tricky  indeed.  

  The   first   hurdle   to   overcome   was   the  synthesis   of   a   tribenzotriquinacene   with   six  substituents   at   para-­‐positions   (i.e.   the   portion  shown   in   black   in   the   figure).   After   much  tribulation,   two   variations   of   the   desired  structure   were   isolated,   and   their   progress   has  recently  been  published   in   the   journal  Chemical  Communications.   The   next   step   in   the   process,  connecting  the  three  arene  rings  to  create  three  more  rings,  beckons.    Link  to  article:  http://pubs.rsc.org/en/content/articlelanding/2012/cc/c1cc14703j  Krueger  Research  Group:  http://www-­‐organik.chemie.uni-­‐wuerzburg.de/lehrstuehlearbeitskreise/krueger/startseite/  

 

Even  high-­‐school  students  will  tell  you  that  four-­‐coordinate   carbon   is   tetrahedral,   and   this  concept  holds  too  for  carbon’s  neighbours  boron  and   nitrogen.   However,   a   new   report   in  Angewandte  Chemie,   International   Edition   from  the   research   group   of   Prof.   Dr.   Holger  Braunschweig   suggests   otherwise.   By   attaching  four   transition   metals   to   a   boron   atom,   they  have   prepared   two   complexes   in   which   the  boron  is  essentially  flat.       The  students  who  performed  the  syntheses,  Dr.   Katharina   Kraft   and   Dipl.   Chem.   Sebastian  Östreicher,   spent   over   a   year   trying   to   add   the  crucial  fourth  metal  fragment  to  the  boron  atom,  but   did   not   expect   that   both   complexes   would  turn  out  to  be  planar.       As   Mr.   Östreicher  explains,  “The  sheer  fact  that  coordination   of   four   metal  atoms   to   boron   was   even  possible   came   as   a   big  surprise   to   us.”   Since   forcing   boron   to   contort  and   form   unsual   geometries   is   a   founding  principle   of   the   Braunschweig   research   group,  

what   is   next   on   the   list?   “I   really  would   love   to  see   someone   trying   to   add   a   fifth  metal   to   the  boron”,  said  Mr.  Östreicher.    Link  to  article:  http://onlinelibrary.wiley.com/doi/  10.1002/anie.201107248/abstract  Braunschweig  Research  Group:  http://www-­‐anorganik.chemie.uni-­‐wuerzburg.de/Braunschweig/