• Title of article

    Pathways for the degradation of organic photovoltaic P3HT:PCBM based devices

  • Author/Authors

    Reese، نويسنده , , Matthew O. and Morfa، نويسنده , , Anthony J. and White، نويسنده , , Matthew S. and Kopidakis، نويسنده , , Nikos and Shaheen، نويسنده , , Sean E. and Rumbles، نويسنده , , Garry and Ginley، نويسنده , , David S.، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2008
  • Pages
    7
  • From page
    746
  • To page
    752
  • Abstract
    We report on studies of device degradation in organic photovoltaic devices based on blends of poly(3-hexylthiophene) (P3HT) and [6,6]-phenyl C61-butyric acid methyl ester (PCBM). Since delamination, oxidation, and chemical interactions at the metal electrode/organic interface have long been posited as degradation pathways in organic electronic devices, we first investigated the stability of a variety of electrodes for devices stored in an inert, dark environment. Second, a set of experiments was designed to separate the effects at the metal/organic interface from the degradation of the active layer or the hole extraction interface. To do this, Ca/Al electrodes were deposited to complete half of a substrateʹs devices, and samples were left both under constant illumination and 10% illumination (10% duty cycle of 1 sun illumination) in a glovebox environment. After more than 200 h of measurement, additional electrodes were deposited and device performance of each set was compared. Third, to assess the degree of degradation caused by photo-induced processes, device stability in an inert atmosphere under constant illumination, and 10% illumination conditions was also investigated. Last, various degradation mitigation strategies in air under constant illumination were explored. The results showed that the active layer itself is not inherently unstable on the timescales studied here. Choosing the appropriate electrode (Ca/Al) reduced interfacial degradation, storing the active layer in an inert, dark environment did not cause significant degradation, and storing the active layer under constant illumination caused only a limited reduction in performance. Our results indicate that the metal/organic interface can be a significant source of degradation in the devices, and we discuss approaches that could reduce this instability.
  • Keywords
    Organic photovoltaic , Metal organic surface , Degradation , stability , Electrode
  • Journal title
    Solar Energy Materials and Solar Cells
  • Serial Year
    2008
  • Journal title
    Solar Energy Materials and Solar Cells
  • Record number

    1481895