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High open-circuit voltage bulk-heterojunction solar cells by using new dendritic acceptor material. / Mabrook, M.F.; Alshahrani, T.M.; Alshahrani, T. et al.
2014. Paper presented at Nanotech, Washington DC, May 12-16, 2013.

Research output: Contribution to conferencePaper

HarvardHarvard

Mabrook, MF, Alshahrani, TM, Alshahrani, T, EL-Betany, A, Mabrook, M, Tai, H & McKeown, NB 2014, 'High open-circuit voltage bulk-heterojunction solar cells by using new dendritic acceptor material', Paper presented at Nanotech, Washington DC, May 12-16, 2013, 3/01/01.

APA

Mabrook, M. F., Alshahrani, T. M., Alshahrani, T., EL-Betany, A., Mabrook, M., Tai, H., & McKeown, N. B. (2014). High open-circuit voltage bulk-heterojunction solar cells by using new dendritic acceptor material. Paper presented at Nanotech, Washington DC, May 12-16, 2013.

CBE

Mabrook MF, Alshahrani TM, Alshahrani T, EL-Betany A, Mabrook M, Tai H, McKeown NB. 2014. High open-circuit voltage bulk-heterojunction solar cells by using new dendritic acceptor material. Paper presented at Nanotech, Washington DC, May 12-16, 2013.

MLA

Mabrook, M.F. et al. High open-circuit voltage bulk-heterojunction solar cells by using new dendritic acceptor material. Nanotech, Washington DC, May 12-16, 2013, 03 Jan 0001, Paper, 2014.

VancouverVancouver

Mabrook MF, Alshahrani TM, Alshahrani T, EL-Betany A, Mabrook M, Tai H et al.. High open-circuit voltage bulk-heterojunction solar cells by using new dendritic acceptor material. 2014. Paper presented at Nanotech, Washington DC, May 12-16, 2013.

Author

Mabrook, M.F. ; Alshahrani, T.M. ; Alshahrani, T. et al. / High open-circuit voltage bulk-heterojunction solar cells by using new dendritic acceptor material. Paper presented at Nanotech, Washington DC, May 12-16, 2013.

RIS

TY - CONF

T1 - High open-circuit voltage bulk-heterojunction solar cells by using new dendritic acceptor material

AU - Mabrook, M.F.

AU - Alshahrani, T.M.

AU - Alshahrani, T.

AU - EL-Betany, A.

AU - Mabrook, M.

AU - Tai, H.

AU - McKeown, N.B.

PY - 2014/5/13

Y1 - 2014/5/13

N2 - Light harvesting solar cells and energy transfer are currently of great challenges for the 21st century in the field of solar cells energy. Academic and industrial scientists are searching for a detailed understanding of light harvesting and find tools to control the electron transfer between donor and acceptor molecules. Due to their electronic properties and the ability to tune their absorption ranges, conjugated dendrimers combined with polymers are used extensively in the formation of the active layer (donor- acceptor) in organic photovoltaic [1]. Dendrimers and hyperbranched polymers are considered to be the leading materials used in the application of organic solar cells. They are low viscosity with high molecular weights, good solubility and mutifunctionality. Dendrimers are perfect monodisperse macromelcular (tree-like structures) with high branched three-dimensional structures: core, branches, and end groups [1, 2]. Organic bulk-heterojunction structure (OBHJ) consist of donor and acceptor (active layer) blend together deposited between two electrodes in order to gain a large interface area between donor and acceptor [3]. However, charge mobility through the OBHJ active layer strongly depends on the morphology of surface of the active layer. thus, dendrimers materials with their small size and monodisperse nature leads to a high degree of ordering in organic solar cell devices and thus high carrier mobilities [2, 3]. Many reports indicate derivatives of 1,8-naphthalimide based on PAMAM dendron have highly efficient as an acceptor in light harvesting dendrimers [4, 5] while the Poly (3- hexylthiophene) (P3HT) possess brilliant efficiency as donor material due to its low band-gap in photovoltaic applications.

AB - Light harvesting solar cells and energy transfer are currently of great challenges for the 21st century in the field of solar cells energy. Academic and industrial scientists are searching for a detailed understanding of light harvesting and find tools to control the electron transfer between donor and acceptor molecules. Due to their electronic properties and the ability to tune their absorption ranges, conjugated dendrimers combined with polymers are used extensively in the formation of the active layer (donor- acceptor) in organic photovoltaic [1]. Dendrimers and hyperbranched polymers are considered to be the leading materials used in the application of organic solar cells. They are low viscosity with high molecular weights, good solubility and mutifunctionality. Dendrimers are perfect monodisperse macromelcular (tree-like structures) with high branched three-dimensional structures: core, branches, and end groups [1, 2]. Organic bulk-heterojunction structure (OBHJ) consist of donor and acceptor (active layer) blend together deposited between two electrodes in order to gain a large interface area between donor and acceptor [3]. However, charge mobility through the OBHJ active layer strongly depends on the morphology of surface of the active layer. thus, dendrimers materials with their small size and monodisperse nature leads to a high degree of ordering in organic solar cell devices and thus high carrier mobilities [2, 3]. Many reports indicate derivatives of 1,8-naphthalimide based on PAMAM dendron have highly efficient as an acceptor in light harvesting dendrimers [4, 5] while the Poly (3- hexylthiophene) (P3HT) possess brilliant efficiency as donor material due to its low band-gap in photovoltaic applications.

UR - http://www.techconnectworld.com/Nanotech2013/a.html?i=1672

M3 - Paper

T2 - Nanotech, Washington DC, May 12-16, 2013

Y2 - 3 January 0001

ER -