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Molecular heterojunctions

Xue JG, Rand BP, Uchida S, Eorrest SR (2005) A hybrid planar-mixed molecular heterojunction photovoltaic cell. Adv Mater 17 66... [Pg.204]

Xue JG, Uchida S, Rand BP, Forrest SR (2004) Asymmetric tandem organic photovoltaic cells with hybrid planar-mixed molecular heterojunctions. Appl Phys Lett 85 5757... [Pg.205]

Device physics of molecular heterojunction solar cells... [Pg.473]

XueJ. G., Rand B. P., Uchida S. and Forrest S. R. (2005), Mixed donor-acceptor molecular heterojunctions for photovoltaic applications. 11. Device performance , J. Appl. Phys. 98, 124903-1-124903-9. [Pg.500]

Rand, B. R, Xue, J., Uchida, S., and Forrest, S. R. 2005. Mixed donor-acceptor molecular heterojunctions for photovoltaic applications. I. Material properties. Journal of Applied Physics 98 (12) 124902. [Pg.390]

Linear-conjugated systems (mainly, poly- and oligothiophenes) deriva-tized with C6o-fullerene as molecular heterojunctions for organic photovoltaics 05CSR483. [Pg.24]

Y.H. Geerts, O. Debever, C. Amato, S. Sergeyev, Synthesis of mesogenic phthalocyanine-C60 donor-acceptor dyads designed for molecular heterojunction photovoltaic devices. Beilstein J. Oig. Chem. 5, 1-9 (2009)... [Pg.280]

LB technique has been used by Isoda to produce molecular heterojunctions (MHJ) using porphyrins and flavin monolayers, as depicted in Figure 13.87a . These heterojunctions were studied for transient photocurrent generation, and the experimental setup is described in Figure 13.87b, as a typical instrumentation example. In the absence of bias, the performance of the MHJs strongly depends on the number of layers involved, with a maximum value of 0.18 /zA for MHJ with three porphyrin layers and four flavin layers. [Pg.703]

J. Roncali, Linear Jt-conjugated systems derivatized with Cgo-fullerene as molecular heterojunctions for organic photovoltaics, Chem. Soc. Rev., 34, 483-495 (2005). [Pg.133]

Wu, J. and McCreery, R. L. 2009 Solid-state electrochemistry in molecule/TiOj molecular heterojunctions as the basis of the TiOj Memristor . J. Electrochem. Soc. 156 P29—P37. [Pg.236]

Bonifas, A. P. and McCieety, R. L. 2012 Solid state spectroelectrochemistry of redox reactions in polypyrrole/oxide molecular heterojunctions. Anal. Chem. 84 2459-2465. [Pg.239]

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See also in sourсe #XX -- [ Pg.703 ]



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