An Efficient Bulk‐Heterojunction Photovoltaic Cell Based on Energy Transfer in Graded‐Bandgap Polymers

Abstract: It is demonstrated that the energy transfer from low‐conjugated (LC) poly[2‐methoxy‐5‐(2‐ethylhexyloxy)‐1,4‐phenylene vinylene] (MEHPPV) to high‐conjugated (HC) MEHPPV, coupled with significant electron transfer from HC‐MEHPPV to an acceptor species, offers a viable route for an efficient photodiode over a wide spectral range. An enhanced incident‐photon‐to‐current conversion efficiency (IPCE) of 19 % over a wide spectral range and a power‐conversion efficiency (ηP) of 1 % (under monochromatic illumination at … Show more

“…(1) [21]. The thickness d also determines the slope ( ¼ mt/d 2 ) of the JV curve (in the range V sat oVoV OC ) [22,23] [24][25][26][27][28] resulting in a lower PCE as compared to P3HT-PCBM (FF $68%) [7] devices which can be attributed to the lower m and consequent field-dependent exciton dissociation rate in PPV systems [28]. Solar cells based on small molecules are also capable of giving high FF (450%) [29].…”

Fill factor in organic solar cells

“…(1) [21]. The thickness d also determines the slope ( ¼ mt/d 2 ) of the JV curve (in the range V sat oVoV OC ) [22,23] [24][25][26][27][28] resulting in a lower PCE as compared to P3HT-PCBM (FF $68%) [7] devices which can be attributed to the lower m and consequent field-dependent exciton dissociation rate in PPV systems [28]. Solar cells based on small molecules are also capable of giving high FF (450%) [29].…”

Fill factor in organic solar cells

“…Leading examples include polymer organic light emitting diodes (PLEDs), field effect transistors (FETs), and organic photovoltaic devices (OPVs), among others [1][2][3][4][5][6][7][8]. The active layer of plastic bulk heterojunction OPVs is typically composed of a conjugated polymer (electron donating molecule) and fullerene derivative such as C 60 or PCBM (electron accepting molecule) [9][10][11][12]. This active layer has a complex nanostructured morphology that is created by mixing the donor and the acceptor molecules into a blend that forms a bicontinuous interpenetrating network resulting in a large interfacial area for photoinduced charge separation [13].…”

Single particle spectroscopy on composite MEH-PPV/PCBM nanoparticles

“…The induced current signal is highly sensitive to electric fields and has been used to characterize contacts in nanowire and carbon nanotube devices, [4][5][6] quantitatively determine electron and hole mobility-lifetime products in CdS nanowires, [7] identify the active region in Si nanowire p-i-n photodetectors, [8] and investigate transport in thin-film organic semiconductors. [9,10] Furthermore, SPCM data has been analyzed to obtain qualitative potential profiles of devices with Schottky contacts. [4] The evolving shape of such profiles with applied gate or source-drain bias can be used to determine the charge depletion width [5] and Schottky barrier height in devices.…”

Nonuniform Nanowire Doping Profiles Revealed by Quantitative Scanning Photocurrent Microscopy