The Interlayer Method: A Universal Tool for Energy Level Alignment Tuning at Inorganic/Organic Semiconductor Heterojunctions

• Published in: Advanced functional materials Vol. 31; no. 10
• Main Authors: Schultz, Thorsten, Lungwitz, Dominique, Longhi, Elena, Barlow, Stephen, Marder, Seth R., Koch, Norbert
• Format: Journal Article
• Language: English
• Published: Hoboken Wiley Subscription Services, Inc 01.03.2021
• Subjects: Alignment; Charge transfer; Energy; energy level alignment; Energy levels; Heterojunctions; Interlayers; Materials science; Optoelectronic devices; Organic semiconductors; photoelectron spectroscopy; Semiconductors; Stability; Tuning
• ISSN: 1616-301X; 1616-3028
• DOI: 10.1002/adfm.202010174

The combination of inorganic and organic semiconductors in a heterojunction is considered a promising approach to overcome limitations of each individual material class. However, to date only few examples of improved (opto‐)electronic functionality have been realized with such hybrid heterojunctions. The key to unraveling the full potential offered by inorganic/organic semiconductor heterojunctions is the ability to deliberately control the interfacial electronic energy levels. Here, a universal approach to adjust the offset between the energy levels at inorganic/organic semiconductor interfaces is demonstrated: the interlayer method. A monolayer‐thick interlayer comprising strong electron donor or acceptor molecules is inserted between the two semiconductors and alters the energy level alignment due to charge transfer with the inorganic semiconductor. The general applicability of this method by tuning the energy levels of hydrogenated silicon relative to those of vacuum‐processed films of a molecular semiconductor as well as solution‐processed films of a polymer semiconductor is exemplified, and is shown that the energy level offset can be changed by up to 1.8 eV. This approach can be used to adjust the energy levels at the junction of a desired material pair at will, and thus paves the way for novel functionalities of optoelectronic devices. The energy level alignment between the two materials in an inorganic/organic semiconductor heterojunction significantly influences device functionality and performance. Here, a method that allows one to change the energy level alignment at such a heterojunction almost at will is demonstrated.