A. OTHER JUNCTIONS B. SEMICONDUCTOR HETEROJUNCTIONS -- MOLECULES AT INTERFACES: ORGANIC PHOTOVOLTAIC BULK HETEROJUNCTION DYE-SENSITIZED SOLAR CELL

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A. OTHER JUNCTIONS B. SEMICONDUCTOR HETEROJUNCTIONS -- MOLECULES AT INTERFACES: ORGANIC PHOTOVOLTAIC BULK HETEROJUNCTION DYE-SENSITIZED SOLAR CELL

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A. OTHER JUNCTIONS B. SEMICONDUCTOR HETEROJUNCTIONS -- MOLECULES AT INTERFACES: ORGANIC PHOTOVOLTAIC BULK HETEROJUNCTION DYE-SENSITIZED SOLAR CELL March 24, 2015 The University of Toledo, Department of Physics and Astronomy SSARE, PVIC Principles and Varieties of Solar Energy (PHYS 4400)

p-n junction and semiconductor physics review A note on units: looking at the Continuity equation(s) units for dn/dt are cm -3 s -1. Units for (1/q)(dJ/dx) work out to be: (C -1 )(C s -1 cm -2 )(cm -1 ) = cm -3 s -1.

p-n junction and semiconductor physics review Poisson s Equation deˆ dx q ( p n N D N A ) Straightforward definitions: E is the electric field is the charge density q is the magnitude of the electron charge p is the concentration of free holes n is the concentration of free electrons N D + is the concentration of ionized donor atoms (recall that donors donate electrons, leaving them positively charged) N A - is the concentration of ionized acceptor atoms (recall that acceptors accept electrons, leaving them negatively charged)

Semiconductor physics review Density of States in Conduction and Valence Band (parabolic band approximation) N N C V E E mn 2 m 3/ 2 3 3/ 2 p 2 3 2 2 E E E V C E Look at units: (note that 1 J = 1 kg-m 2 -s -2, and [h] = m 2 kg s -1 ) kg 3/ 2 J 1/ 2 6 3 m kg s 3 kg 3/ 2 kg 1/ 2 6 3 m kg s s 3 m kg 1 s 2 m 5 J 1 m 3 Fermi function (state occupation probability) f E 1 E E 1 exp kt F

Junctions Reading assignments: Work Function: http://en.wikipedia.org/wiki/work_function Electron Affinity (solid state physics): http://en.wikipedia.org/wiki/electron_affinity Vacuum Level: http://en.wikipedia.org/wiki/vacuum_level Fermi Energy: http://en.wikipedia.org/wiki/fermi_energy Fermi Level: http://en.wikipedia.org/wiki/fermi_level Work Function: potential required to remove the least tightlybound electron: w E vac E F Work function equals the electron affinity in metals.

Bases for effective fields at junctions Charge-separation mechanisms gradient in the vacuum level or work function electrostatic field (e.g., doping level) gradient in electron affinity effective field gradient in the band gap effective field gradient in the band DOS effective field

Metal-semiconductor junctions: Schottky-barrier m n In contact: electrons flow from semiconductor to metal, resulting in a layer of positive fixed charge in the semiconductor, near the surface (and a negative image charge on the metal); Fermi levels equilibrate; Potential difference drops in the semiconductor (space charge, and/or depletion, region); Result is a lower resistance pathway for holes than for electrons

Metal-semiconductor junctions: Schottky-barrier (cont.) Under illumination, holes flow to the right, and electrons accumulate in the semiconductor; Fermi level shifts up in the semiconductor (accumulation of electrons); Result is a photovoltage

Metal-semiconductor junctions: Schottky-barrier (cont.)

Metal-semiconductor junctions: Schottky-barrier (cont.) m p In contact: holes flow from the semiconductor to the metal, resulting in a layer of negative fixed charge in the semiconductor near the surface (and a positive image charge on the metal); Fermi levels equilibrate; Potential difference drops in the semiconductor (space charge, and/or depletion, region); Result is a lower resistance pathway for electrons (to the metal) than for holes Under illumination, electrons flow into the metal from the semiconductor

Metal-semiconductor junctions: Ohmic contact m n m p Note that at Ohmic contact provides a low resistance pathway for majority carrier from the semiconductor to the metal

Organic PV: Bulk heterojunction http://depts.washington.edu/cmditr/mediawiki/inde x.php?title=organic_heterojunctions_in_solar_cells http://www-ssrl.slac.stanford.edu/sites/default/files/sciencehighlights/images/2011/january/verploegen--fig1_0.png

Organic PV: simplified BH structure http://www.light.t.utokyo.ac.jp/english/photovoltaic/introduction.html http://www.cfn.uni-karlsruhe.de/?id=221 M. Al-Ibrahima et al., Solar Energy Materials & Solar Cells 85 (2005) 13 20

Organic PV: interface energetics http://depts.washington.edu/cmditr/mediawiki/images/8/84/or ganicheterojunctions.jpg http://www.physik.uniwuerzburg.de/ep6/research-oe.html

Dye-sensitized TiO 2 solar cell ~25 nm nano-porous TiO 2 electrode HOMO-LUMO transition Reaction : S + h S * S + + e - M. Grätzel / Journal of Photochemistry and Photobiology C: Photochemistry Reviews 4 (2003) 145 153

Dye-sensitized TiO 2 solar cell Binding of dye (monolayer) to TiO 2 through carboxylate groups; photon absorption results in metal-to-ligand charge transfer (MLCT) and rapid injection (<20 fs) of the e - into the TiO 2 CB. M. Grätzel / Journal of Photochemistry and Photobiology C: Photochemistry Reviews 4 (2003) 145 153

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