We directly configured double-walled carbon nanotubes as energy conversion materials to fabricate thin-film solar cells, with nanotubes serving as both photogeneration sites and a charge carriers collecting/transport layer. The solar cells consist of a semitransparent thin film of nanotubes conformally coated on a n-type crystalline silicon substrate to create high-density p-n heterojunctions between nanotubes and n-Si to favor charge separation and extract electrons (through n-Si) and holes (through nanotubes). Initial tests have shown a power conversion efficiency of >1%, proving that DWNTs-on-Si is a potentially suitable configuration for making solar cells. Our devices are distinct from previously reported organic solar cells based on blends of polymers and nanomaterials, where conjugate polymers generate excitons and nanotubes only serve as a transport path.
Various approaches to improve the efficiency of solar cells have followed the integration of nanomaterials into Si-based photovoltaic devices. Here, we achieve 13.8% efficiency solar cells by combining carbon nanotubes and Si and doping with dilute HNO(3). Acid infiltration of nanotube networks significantly boost the cell efficiency by reducing the internal resistance that improves fill factor and by forming photoelectrochemical units that enhance charge separation and transport. Compared to conventional Si cells, the fabrication process is greatly simplified, simply involving the transfer of a porous semiconductor-rich nanotube film onto an n-type crystalline Si wafer followed by acid infiltration.
Nanotube–Si heterojunction solar cells are fabricated by coating a thin film of double‐walled carbon nanotubes on n‐type silicon wafers. These solar cells show power‐conversion efficiencies in the range of 5–7%. The nanotubes perform multiple functions in the cells, including charge separation, charge transport, and charge collection.
a b s t r a c tCarbon-based photovoltaic cells (PVCs) have attracted a great deal of interest for both scientific fundamentals and potential applications. In this paper, applications of various carbon materials in PVCs, especially in silicon-based solar cells, organic solar cells and dye-sensitized solar cells, are reviewed. The roles carbon materials played in the PVCs are discussed. Further research on solar cells comprised solely of carbon is prospected.
Ultra-broad
spectral detection is critical for several technological
applications in imaging, sensing, spectroscopy, and communication.
Carbon nanotube (CNT) films are a promising material for ultra-broadband
photodetectors because their absorption spectra cover the entire ultraviolet
to the terahertz range. However, because of the high binding energy
of excitons, photodetectors based on CNT films always require a strong
electric field, asymmetric electrical contacts, or hybrid structures
with other materials. Here, we report an ultra-broadband bolometric
photodetector based on a suspended CNT film. With an abundant distribution
of tube diameters and an appropriate morphology (spider web-like),
the CNT films display a strong absorption spectrum from the ultraviolet
up to the terahertz region. Under illumination, heat generated from
the electron–photon interaction dominates the photoresponse
of our devices. For small changes in temperature, the photocurrent
shows a convincing linear dependence with the absorbed light’s
power across 3 orders of magnitude. When the channel length is reduced
to 100 μm, the device demonstrates a high performance with an
ultraviolet responsivity of up to 0.58 A/W with a bias voltage of
0.2 V and a short response time of ∼150 μs in vacuum,
which is better than that of many other photodetectors based on CNTs.
Moreover, this performance could be further enhanced by optimization.
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