柔性石墨烯-/a-Si:H多光谱光电探测器

2016 74th Annual Device Research Conference (DRC) Pub Date : 2016-06-19 DOI:10.1109/DRC.2016.7548481

D. Schneider, A. Bablich, M. Lemme

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引用次数: 0

摘要

透明导电电极(tce)在太阳能电池、触摸屏和光电探测器等光子器件中无处不在，也是必不可少的。石墨烯可以满足对tce日益增长的需求，它承诺低生产成本和丰富的原材料，并可能实现柔性光电器件。我们报道了非晶硅(a- si:H)多光谱光电探测器，其在石墨烯TCEs的刚性和柔性衬底上具有可调偏的最大光谱响应。电学和光学测量与具有透明导电氧化物(TCO) TCEs(这里:ZnO:Al，[3])的传统器件相比相当好，达到其响应率的50%以上。与脆弱的ZnO:Al相比，石墨烯可以实现灵活的多光谱光电二极管。石墨烯TCEs的另一个决定性优势是在UV区域具有更宽的光谱响应，否则会受到ZnO:Al吸收的限制。由于在220 nm厚的ZnO:Al中折射的伪影在原子薄的石墨烯TCEs中被抑制。双层石墨烯(BLG)电极显著提高了响应性。

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Flexible graphene-/a-Si:H multispectral photodetectors

Transparent conductive electrodes (TCEs) are ubiquitous and essential for photonic devices like solar cells, touchscreens and photodetectors. An increasing demand for TCEs may be met with graphene, which promises low production cost and an abundance of raw material and may enable flexible optoelectronic devices. We report amorphous silicon (a-Si:H) multispectral photodetectors with a bias-tunable maximum spectral response on rigid and flexible substrates with graphene TCEs. Electrical and optical measurements compare reasonably well to conventional devices with transparent conductive oxide (TCO) TCEs (here: ZnO:Al, [3]), reaching over 50% of their responsivity. Graphene enables flexible multispectral photodiodes, in contrast to the brittle ZnO:Al. A further decisive advantage of the graphene TCEs is a broader spectral response into the UV region, which is otherwise limited by the absorption in the ZnO:Al. Artifacts due to refraction in the 220 nm thick ZnO:Al are suppressed in the atomically thin graphene TCEs. Bilayer graphene (BLG) electrodes improve the responsivity considerably.

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2016 74th Annual Device Research Conference (DRC)

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