posted on 2016-10-26, 00:00authored byTejas
A. Shastry, Itamar Balla, Hadallia Bergeron, Samuel H. Amsterdam, Tobin J. Marks, Mark C. Hersam
Two-dimensional
transition metal dichalcogenides (TMDCs) have recently
attracted attention due to their superlative optical and electronic
properties. In particular, their extraordinary optical absorption
and semiconducting band gap have enabled demonstrations of photovoltaic
response from heterostructures composed of TMDCs and other organic
or inorganic materials. However, these early studies were limited
to devices at the micrometer scale and/or failed to exploit the unique
optical absorption properties of single-layer TMDCs. Here we present
an experimental realization of a large-area type-II photovoltaic heterojunction
using single-layer molybdenum disulfide (MoS2) as the primary
absorber, by coupling it to the organic π-donor polymer PTB7.
This TMDC–polymer heterojunction exhibits photoluminescence
intensity that is tunable as a function of the thickness of the polymer
layer, ultimately enabling complete quenching of the TMDC photoluminescence.
The strong optical absorption in the TMDC–polymer heterojunction
produces an internal quantum efficiency exceeding 40% for an overall
cell thickness of less than 20 nm, resulting in exceptional current
density per absorbing thickness in comparison to other organic and
inorganic solar cells. Furthermore, this work provides insight into
the recombination processes in type-II TMDC–polymer heterojunctions
and thus provides quantitative guidance to ongoing efforts to realize
efficient TMDC-based solar cells.