posted on 2013-07-10, 00:00authored byCarl Hägglund, Gabriel Zeltzer, Ricardo Ruiz, Isabell Thomann, Han-Bo-Ram Lee, Mark L. Brongersma, Stacey F. Bent
Achieving
complete absorption of visible light with a minimal amount
of material is highly desirable for many applications, including solar
energy conversion to fuel and electricity, where benefits in conversion
efficiency and economy can be obtained. On a fundamental level, it
is of great interest to explore whether the ultimate limits in light
absorption per unit volume can be achieved by capitalizing on the
advances in metamaterial science and nanosynthesis. Here, we combine
block copolymer lithography and atomic layer deposition to tune the
effective optical properties of a plasmonic array at the atomic scale.
Critical coupling to the resulting nanocomposite layer is accomplished
through guidance by a simple analytical model and measurements by
spectroscopic ellipsometry. Thereby, a maximized absorption of light
exceeding 99% is accomplished, of which up to about 93% occurs in
a volume-equivalent thickness of gold of only 1.6 nm. This corresponds
to a record effective absorption coefficient of 1.7 × 107 cm–1 in the visible region, far exceeding
those of solid metals, graphene, dye monolayers, and thin film solar
cell materials. It is more than a factor of 2 higher than that previously
obtained using a critically coupled dye J-aggregate, with a peak width
exceeding the latter by 1 order of magnitude. These results thereby
substantially push the limits for light harvesting in ultrathin, nanoengineered
systems.