Photovoltaics. Lecture 7 Organic Thin Film Solar Cells Photonics - Spring 2017 dr inż. Aleksander Urbaniak

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1 Photovoltaics Lecture 7 Organic Thin Film Solar Cells Photonics - Spring 2017 dr inż. Aleksander Urbaniak

3 Barcelona, Spain

4 Perpignan train station, France

5 source: pinterest

6 Why organic solar cells? 1. Low weight and flexibility of the PV modules. 2. Semitransparency. 3. Easy integration into other products. 4. New market opportunities, e.g. wearable PV. 5. Significantly lower manufacturing costs compared to conventional inorganic technologies. 6. Manufacturing of OPV in a continuous process using state of the art printing tools. 7. Short energy payback times and low environmental impact during manufacturing and operations.

7 DSSC Dye Sensitized Solar Cells Michael Graetzel 1988

8 Mechanism of operation Imitation of photosynthesis Electron hole pairs are generated in dye particles organic dye Excited electrons then diffuse into titanium dioxide TiO 2 (semiconductor)

9 Definitions RED (reduction) accepting an electron (X X - + h) ~ acceptors in semiconductors OX (oxidation) donation an electron (X X + + e - ) ~ donors in semiconductors HOMO Highest Occupied Molecular Orbital ~ valence band in semiconductors LUMO Lowest Unoccupied Molecular Orbital ~ conduction band in semiconductors

10 The mechanism 1. Photon absorption in photosensitive dye 2. Dye particles excited from the ground state (S) do the excited state (S ). Excited electrons move to the condution band in TiO2. Dye lose electrons (its particles become oxidized S + ) S + hν S S S + + e (TiO 2 ) 3. Electrons in TiO 2 conduction band diffuse to the external circuit 4. Oxidized dye particles (S+) accept electrons from the electrolyte (I ). Dye partcilees return to the ground state (S) while electrolyte is further oxidized up to I 3- S + + e S 5. Oxidized electrolyte (I 3- ), diffuse to the back electrode and is reduced to I I 3 + 2e 3I \

11 nature.com solaronix.com

13 Conjugated polymers Delocalization of p and d orbitals single bond double bond cinamone aldehyde current beta carotene

14 Conjugated polymers benzene

15 Bonds to bands H 2 molecule 1,3 butadiene

16 The idea V OC E g 1. charge excitation A 2. diffusion transfer e to acceptor material t 100 fs 3. collection 4. recombination D

17 First (reasonable) organic solar cell eff. = 0.95% CuPc copper phthalocyanine PV perylene tetracarboxylic derivcative source: C.W. Tang, Appl. Phys. Lett. 48, 183 (1986)

18 Bulk heterojunction cencept Bilayer organic cells fail due to low diffusion lengths (max. 10 nm), much lower than the thickness of the absorber (min. 100 mn) BH solar cell features a distributed junction between donor and acceptor materials polymer fullerene blend or conjugated molecules

19 Efficiencies Yokohama, source: Mitsubishi Chemicals Laboratory cells, around 1 cm 2, Modules around 3 % efficiency Roll to roll processes Mitsubishi Chemicals + 3M

20 Donor and acceptor materials are mixed together in a solution Excitons are strongly bonded (around 0.5 ev>> E Electron accepting molecules have to added Bulk heterojunction

21 Bulk heterojunction cencept A - D : potential barrier acting as a driving force for electrons carriers must be generated within the diffusion length from D-A interface a) good charge separation but poor transport a) poor charge generation b) ideal c) real

22 Donor and acceptor materials

23 Bulk heterojunction device E(H)TL electron (hole) transport layer HTLs : poly-mer like PEDOT:PSS (poly(3,4ethylenedioxythiophene)poly(styrenesulfonate)) or a thin oxide layer (e.g. MoO 3 ) ETL materials are often oxides like zinc oxide or titanium dioxide b) allows non-vacuum processing

24 Perovskite- based solar cells rapid growth in last 10 years simplicity in production efficiencies competitive with Si and thin film solar cells small areas problems with stability

A perovskite A perovskite is any material with the same type of crystal structure as calcium titanium oxide (CaTiO 3 ), known as the perovskite structure, or XII A 2+VI B 4+ X 2 3 with the oxygen in

25 A perovskite A perovskite is any material with the same type of crystal structure as calcium titanium oxide (CaTiO 3 ), known as the perovskite structure, or XII A 2+VI B 4+ X 2 3 with the oxygen in the face centers The red spheres are X atoms (usually oxygens), the blue spheres are B-atoms (a smaller metal cation, such as Ti 4+ ), and the green spheres are the A-atoms (a larger metal cation, such as Ca 2+ ) source: wikipedia

26 Perovskites in photovoltaics Crystal structure of CH 3 NH 3 PbX 3 perovskites (X=I, Br and/or Cl). The methylammonium cation (CH 3 NH 3+ ) is surrounded by PbX 6 octahedra optical bandgap between 1.5 and 2.3 ev depending on halide content source: wikipedia

27 A perovskite solar cell

28 Tandem cells source:

29 Tandem cells source: Nature Energy 2, Article number: (2017)

Mesoporous titanium dioxide electrolyte bulk heterojunction

Mesoporous titanium dioxide electrolyte bulk heterojunction The term "bulk heterojunction" is used to describe a heterojunction composed of two different materials acting as electron- and a hole- transporters,