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The Role of Catalysis in Chemical Energy Storage MTA EK, 2015.05.04. József Sándor Pap Surface Chemistry and Catalysis Department.

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Presentation on theme: "The Role of Catalysis in Chemical Energy Storage MTA EK, 2015.05.04. József Sándor Pap Surface Chemistry and Catalysis Department."— Presentation transcript:

1 The Role of Catalysis in Chemical Energy Storage MTA EK, 2015.05.04. József Sándor Pap Surface Chemistry and Catalysis Department

2 Renewable energy sources –how to store the produced energy? Israel – 10 MW solar thermal pp. (with backup biomass facility) Wind turbines – low energy density Japan – 30 MW offshore solar pp. Renewables are either INTERMITTENT DIFFUSE or LOW DENSITY! Renewables are either INTERMITTENT DIFFUSE or LOW DENSITY!

3 Renewable energy sources –how to store the produced energy? "Getting battery cost down is key, but on the stationary storage side there is a lot of questions about which chemistry will dominate long term. It might not be lithium…” - Colin Langan at UBS on Tesla’s announcement of Powerwall Li batteries

4 Energy density becomes decisive when it comes to applications G. Centi, et al. in Catalysis for Alternative Energy Generation, Eds. L. Guczi and A. Erd ő helyi, Springer (2012) ESSENTIALS… 1.Appropriate volumetric AND gravimetric energy density. 2.Ease of storage (C-based). 3.Less toxic, safety of precesses. 4.Can be used with the existing technologies for fossils. 5.Low environmental impact (both production and use). ESSENTIALS… 1.Appropriate volumetric AND gravimetric energy density. 2.Ease of storage (C-based). 3.Less toxic, safety of precesses. 4.Can be used with the existing technologies for fossils. 5.Low environmental impact (both production and use).

5 Hydrogen economy (an attractive way to store and distribute energy)

6 Analogy to fossil fuels – long ago stored energy of sunlight Hydrocarbons  H r ° = -890 kJ/mol Cons: - CO 2 emission - Finite sources - efficiency limits (power plants and engines) - Air pollution  H r ° = -286 kJ/mol Hydrogen Pros: - Cheap access - Cheap storage, process and distribution - Optimal energy density - Established technologies (power plants and internal combustion engines) - Accepted by society 43 % percent of current energy usage comes from fossils!

7 Steam reforming of nat. gas or naphta Partial oxidation of heavy oil Benzine reforming Coal gasification Synthesis of ethene Chlor-alkali industry Other Water electrolysis Synthesis of ammonia Process heat generation Processing of mineral oil Benzine reforming Fisher-Tropsch synthesis Other (oxo synth., hydrogenation, reductions) Role of H 2 today – production and use 10 9 m 3 N 190 120 90 50 33 10 7 1,3 10 9 m 3 N 200 150 25 15 10 Encyclopedia of Electrochemistry, Vol. 5: Electrochemical Engineering, Wiley (2007) Production Consumption 100 H YD R O G EN Only 0.25% of hydrogen is produced by electrolysis. …because it is profitable only when electric power is cheap. Privileged attention to water electrolysis comes with the hydrogen economy concept. Only 0.25% of hydrogen is produced by electrolysis. …because it is profitable only when electric power is cheap. Privileged attention to water electrolysis comes with the hydrogen economy concept.

8 Use of H2 (or derived products) as energy carrier -Fuel cells -Methanol fuel cells -liquid H 2 carriers Surya Prakash & Oláh György (1990) The key to efficiency and to pay-off is CATALYSIS!

9 Brown-H 2 Brown-H 2 example: reforming - net carbon reduction of 30%. Green-H 2 Green-H 2 example: electrolysis renewable - emissions-free. - 20152015-20202020-2030 Natural Gas Reforming Water Electrolysis (grid) Bio-Derived Liquids Reforming Coal Gasification (no carbon capture) Ethanol Reforming Biomass Gasification Coal Gasification (carbon capture) Water Electrolysis (wind) Water Electrolysis (solar) Distributed Central Photo- Electro- chemical Biological Thermo- Chemical* High-Temp. Water Electrolysis* 10 1,000 10,000 50,000 100,000 100,000,000 Capacity (kg/day) Target: 0.15 € / kWh *either solar or nuclear Production of H2 (or derived products) as energy carrier

10 A considerable advantage of H 2 over CHs Electrochemistry! Water electrolysis can be directly connected with renewable power plants! Electrochemistry! Water electrolysis can be directly connected with renewable power plants!

11 What is water oxidation and why is it important? WOC: water oxidation catalyst, a compound that can accelerate the evolution of O 2 from water and can be attached to electrode surface. WOC: water oxidation catalyst, a compound that can accelerate the evolution of O 2 from water and can be attached to electrode surface.

12 Self-organized metal oxides and hydroxides

13 Photosensitized supramolecular systems

14 Homogeneous catalysts: stability (10 4 >TON), sensitivity (anions, contaminants) Heterogeneous catalysts: rate (small TOF), deactivation (nano) Electrocatalysts: overpotential homogeneous: 0,6-0,9 V heterogeneous: 0,2-0,4 V Photocatalysts: small quantum efficiency in the visible range of activation Homogeneous catalysts: stability (10 4 >TON), sensitivity (anions, contaminants) Heterogeneous catalysts: rate (small TOF), deactivation (nano) Electrocatalysts: overpotential homogeneous: 0,6-0,9 V heterogeneous: 0,2-0,4 V Photocatalysts: small quantum efficiency in the visible range of activation There is plenty of space for further research, because…

15 …and studies in our laboratory

16 ScTiVCrMnFeCoNiCuZn YZrNbMoTcRuRhPdAgCd LaHfTaWReOsIrPtAuHg Transition metals that are cheap, abundant, have more available oxidation states. AIM: studying supramolecular systems that in part exploit molecular catalysts and carry potential to merge advantages of the different approaches. Three directions: (1) Ru-based catalysts and related metal-organic frameworks, (2) Cu complexes for electrocatalysis (3) Photosensitized layered double hydroxides (LDHs) for photo(electro)catalysis. Considerations

17

18 MOFs Molecular catalysts Ru-based MOFs Problem: ligand dissociation leads to rapid deactivation Advantage: complexes with no open sites are the most active catalysts Problem: the lack of open sites bottlenecks catalytic applications Advantage: porous materials, existing options for surface anchoring (SURMOF)

19 Layered double hydroxides (LDH) [M’(II) 1-x M(III) x (OH) 2 ] x+ [A m- x/mnH 2 O] x- - M’(II) and M(III) are variable - r M’(II) ≈ r M(III) - Surface adsorbed water - Weakly bound water - Strogly bound water - Intercalation options -Heat induces reversible changes (memory effect) Photosensitized LDHs with abundant metals Small molecule photosensitizer Small molecule photosensitizer

20 Thank you for attention! Köszönöm a figyelmet!

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