Recoverable and recyclable catalysts for sustainable chemical processes Anna Chrobok Silesian University of Technology, Poland.

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Presentation transcript:

Recoverable and recyclable catalysts for sustainable chemical processes Anna Chrobok Silesian University of Technology, Poland

reduce chemical waste, improve the selectivity and efficiency of synthetic processes The design and synthesis of recoverable and recyclable catalysts Ludwigshaven in Germany What are the challenges for the sustainable chemical industry today?

The need to implement green chemistry principles is a driving force towards the development of recoverable and recyclable catalysts. What are the challenges for the sustainable chemical industry today? CATALYST Recyclability can either be achieved : by bounding the catalyst to a solid phase, by modification of solubility characteristics. CATALYST e.g. acid or base is bounded to a solid phase Filtration Regeneration Recycle M. Benaglia, Recoverable and Recyclable Catalysts, 2009 John Wiley & Sons Ltd., 2009

Umweltchemie INST. FÜR ANORGANISCHE CHEMIE Green Chemistry „Green chemistry is the design, development and implementation of chemical products and processes to reduce or eliminate the use and generation of substances hazardous to human health and the environment.“ (U.S. Environmental Protection Agency)

Producttons p.a.kg waste/ kg product Oil refining ca 0.1 Bulk Chemicals < Fine Chemicals Pharmaceuticals Green Chemistry R. A. Sheldon “Consider the Environmental Quotient”, ChemTech, 1994, 38. E-factor (kg/kg) E = kg waste/kg product raw material product waste

Case studies: the recoverable and recyclable catalysts for chemical processes like: -esterification, -Diels-Alder reaction, -oxidation of alcohols and ketones. IONIC LIQUIDS as homogeneous and heterogeneous catalysts Recycling of ionic liquids prevents them from: - ending up in the aquatic environment, - release into the atmosphere (low volatility). Ionic liquids from biomass. Examples

Ionic Liquids Basic Structures

Ionic Liquids Properties

Ionic liquids as catalyst and solvent for esterification reaction Modification of solubility characteristics

H 2 SO 4 + B → [HB][HSO 4 ] χ H2SO4 = H 2 SO 4 + B → [HB][(HSO 4 )(H 2 SO 4 )] χ H2SO4 = H 2 SO 4 + B → [HB][(HSO 4 )(H 2 SO 4 ) 2 ] χ H2SO4 = 0.75 Complex hydrogen-bonded anionic clusters [(HSO 4 )(H 2 SO 4 ) χ ] - ( χ = 0, 1, or 2) K. Matuszek, A. Chrobok, F. Coleman, K. R. Seddon, M. Swadźba ‑ Kwaśny, Green Chem., 2014, 16, 3463 m. p. < 100°C RT ILs, T g < 0°C

Atoms of the hydrogensulfate anion are represented in blue, Atoms of the sulfuric acid are in red. K. Matuszek, A. Chrobok, F. Coleman, K. R. Seddon, M. Swadźba ‑ Kwaśny, Green Chem., 2014, 16, 3463 Complex hydrogen-bonded anionic clusters [(HSO 4 )(H 2 SO 4 ) χ ] - ( χ = 0, 1, or 2)

Catalyst acidity Reactants ratio 1÷ 1,5 mol Catalyst loading 1÷ 15 % mol Catalyst recycle Model esteryfication reaction K. Matuszek, A. Chrobok, F. Coleman, K. R. Seddon, M. Swadźba ‑ Kwaśny, Green Chem., 2014, 16, 3463

Catalyst loading, %mol Reactants ratio BuOH : MeCOOH = 1:1; Temp. 30 o C Temp. 30 o C [Et 3 NH][(HSO 4 )(H 2 SO 4 ) 2 ] Complex hydrogen-bonded anionic clusters

BuOH : MeCOOH = 1:1.5; IL =12% mol; t= 2h; Temp. 30 o C [Et 3 NH][(HSO 4 )(H 2 SO 4 ) 2 ] Recycling study

Summary Synthesis of a new family of protonic ionic liquids Formation of hydrogen-bonded anionic clusters [(HSO 4 )(H 2 SO 4 ) χ ]- ( χ = 1 or 2) High acidity of new ionic liquids (AN up to 121) New catalysts for esterification Key parameters effecting the reaction: miscibility of reagents, catalyst acidity Possibility to reuse catalyst without the lost of activity

Ionic liquids as catalyst and solvent for Diels-Alder reaction Designing of recyclable biocatalysts

K. Erfurt, I. Wandzik, K. Walczak, K. Matuszek, A. Chrobok, Green Chem., 2014, 16, 3508 Ionic liquids from the biomass Glucose-derived ionic liquids: exploring biodegradable, low-cost sources

Diels-Alder reaction K. Erfurt, I. Wandzik, K. Walczak, K. Matuszek, A. Chrobok, Green Chem., 2014, 16, 3508

Diels-Alder reaction

Ionic liquids as catalyst for ketones oxidation Bounding the catalyst to a solid phase

A. Chrobok, S. Baj, W. Pudlo, A. Jarzębski, Appl. Catal. A: General, 2009, 366, 22 Immobilized Catalysts Bounding ionic liquid to a solid phase Scanning Electron Microscopy micrograph of bimodal structured silica

3 recycles, 89-91% of catalyst recovery A. Chrobok, S. Baj, W. Pudlo, A. Jarzębski, Appl. Catal. A: General, 2009, 366, 22 Immobilized Catalysts Bounding the catalyst to a solid phase

Ionic liquids as catalyst and solvent for alcohols oxidation Supported Ionic Liquid Phase SILP

- materials science engineering with economic and environmental objectives A. Chrobok, S. Baj, W. Pudlo, A. Jarzębski, Appl. Cat. A: General, 2010, 389, 179

Scanning Electron Microscopy micrograph of the ionogel A_CuCl 2 /[bmim]OSO 3 Oc sup Supported Ionic Liquid Phase SILP A. Chrobok, S. Baj, W. Pudlo, A. Jarzębski, Appl. Cat. A: General, 2010, 389, 179

Supported Ionic Liquid Phase SILP A. Chrobok, S. Baj, W. Pudlo, A. Jarzębski, Appl. Cat. A: General, 2010, 389, 179 reaction conditions: alcohol (1 mmol), TEMPO (0.1 mmol), mmol of CuCl 2 included in A_CuCl 2 /[bmim]OSO 3 Oc sup, dibutyl ether as solvent, oxygen at atmospheric pressure, 65 o C

Reusability of the A_CuCl 2 /[bmim]OSO 3 Oc sup and B_CuCl 2 /[bmim]OSO 3 Oc sup catalysts reaction conditions: benzyl alcohol (5 mmol), TEMPO (0.5 mmol), 0.35g of catalyst containing mmol of CuCl 2, oxygen at atmospheric pressure, 65 o C; isolated yields after 7 h with 98% conversion of benzyl alcohol

Summary The development of recyclable catalysts represents a big challenge. It is interdisciplinary field, where pure chemistry is connected to material science, or engineering and where even business and economy-related issues play an important role in: -determining the planning, the design and the realization of a project in the area. It is a field where many technologies and opportunities are offered to successfully realize an easy recoverable and, what is more important, reusable catalytic system.

Acknowledgment Karolina Matuszek Agnieszka Drożdż Magdalena Sitko Karol Erfurt Professor Andrzej Jarzębski Dr Katarzyna Szymańska HARMONY Grant no. UMO /06/M/ST8/00030 Financing: Professor Kenneth Seddon Dr Małgorzata Śwadźba Dr Fergal Coleman