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High-Brightness Perovskite Light-Emitting Diodes Using a Printable Silver Microflake Contact.

Masoud PayandehVahid AhmadiFarzaneh Arabpour RoghabadiPariya NazariFatemeh AnsariPhilipp BrennerRainer BäuerleMarius JakobyUli LemmerIan A HowardBryce S RichardsUlrich Wilhelm PaetzoldBahram Abdollahi Nejand
Published in: ACS applied materials & interfaces (2020)
Achieving efficient devices while maintaining a high fabrication yield is a key challenge in the fabrication of solution-processed, perovskite-based light-emitting diodes (PeLEDs). In this respect, pinholes in the solution-processed perovskite layers are a major obstacle. These are usually mitigated using organic electron-conducting planarization layers. However, these organic interlayers are unstable under applied bias in air and suffer from limited charge carrier mobility. In this work, we present a high brightness p-i-n PeLED based on a novel blade-coated silver microflake (SMF) rear electrode, which allows for a low-cost nanocrystalline ZnO inorganic electron-transporting layer to be used. This novel SMF contact is crucial for achieving high performance as it prevents the electrical shorting suffered when standard thermally evaporated silver rear contacts are used. The fabricated PeLEDs exhibit an excellent maximum luminance of 98,000 cd/m2, a maximum current efficiency of 22.3 cd/A, and a high external quantum efficiency of 4.6% under 5.9 V forward bias. The SMF rear contact can be printed and scaled at low cost to large areas and applied to flexible devices.
Keyphrases
  • low cost
  • solar cells
  • gold nanoparticles
  • room temperature
  • water soluble
  • quantum dots
  • solid state
  • energy transfer