The Green Chemistry Centre of Excellence (GCCE) is a world leading research centre which aims to promote the development and implementation of sustainable chemistry and related technologies into new products and processes.

Recent estimates by the pharmaceutical and fine chemical industry have suggested solvents account for the majority of the waste produced in a typical batch process. Solvents are also subject to a number of regulatory controls. For these reasons there has been a large amount of interest in ways to reduce hazardous solvent use and find benign substitutes.

The “Alternative Solvents” technology platform promotes the use of more sustainable solvents - supercritical / liquid CO2, bio-based solvents and solvents made from waste - as replacements for conventional organic solvents. Here lies an opportunity to reduce the environmental impact of industrial processes as well as making them safer.

Our goal is to develop, apply and promote the implementation of safer, greener and more sustainable solvents into industry. The platform focuses on the use of alternative solvents in a wide range of applications.

Some of the applications already developed using supercritical or bio-based solvents include:

  • Extraction of waxes and botanicals (for food and beverage, cosmetic and personal care products)
  • Recovery of liquid crystals from end-of-life electronics
  • Synthesis of aroma molecules using biocatalysts in alternative solvents
  • Use of modelling tools to predict the properties and behaviour of a solvent
  • Use of bio-based solvents for conducting industrially relevant organic reactions
  • Chromatography in supercritical fluids

Contact us

Green Chemistry Centre of Excellence
+44 (0)1904 322567
Department of Chemistry, University of York, Heslington, York YO10 5DD, United Kingdom.

Focus areas

Solvents from biomass and food waste are viewed as one of the most promising types of alternative solvents. A key feature of this work is the use of modelling software to predict the properties and behaviour of a solvent.

The use of these tools allows for the prediction of solvents offering the most favourable performance for a target application. They also guide the synthesis of novel solvents designed for specific processes.

Various chemical molecule representations of alternative solvents

We prepare new bio-based solvents at lab-scale within the GCCE and at demonstrator scale using the Biorenewables Development Centre's facilities. Our discoveries include Cyrene™, a replacement for toxic polar aprotic solvents in materials science and synthesis, and tetramethyloxolane, a broad substitute for toluene.

Traditional catalytic and biocatalytic processes can be performed in supercritical CO2 and bio-based solvents, providing a number of advantages over conventional solvents including:

  • Reduced hazards
  • Lower rates of catalyst poisoning
  • Enhanced catalyst stability
  • High enantioselectivity
  • Simple product and catalyst recovery

The "Alternative Solvents" technology platform also operates a state of the art semi-preparative supercritical chromatography system. This system runs extractions, reactions and analysis all in the supercritical phase.

Carbon dioxide is a non-polar solvent once pressurised into a liquid or supercritical state. The density and polarity of CO2 is completely tuneable to selectivity separate mixtures. Supercritical CO2 has several distinct advantages over traditional organic solvents in extractions, including:

  • Tuneable for fractional separations
  • High permeability for extraction of raw biomass
  • Low surface tension
  • Low viscosity
  • High mass transfer rates
  • Simple product recovery with no solvent residue

Supercritical CO2 extractions have been successfully developed for:

  • Herbs and spices for food and beverage use
  • Waxes for cosmetics and personal care products
  • Oils (nutraceuticals)
  • Purification of active pharmaceutical ingredients
  • Recovery of liquid crystals from end-of-life electronics

The use of wastes to make low cost solvents is a highly appealing concept. The utilisation of CO2 to make carbonate functionalised solvents is well established. In recent years, organic carbonates (both cyclic and acyclic) have been highlighted as highly promising alternatives to typical VOCs.

Solvent selection guides concur that carbonates pose few environmental, health and safety hazards. Current projects within the GCCE are investigating the use of carbonates as alternative solvents in various synthetic transformations, including solid phase peptide synthesis.

The GCCE has developed the S4 (Sustainable Solvent Selection Service) programme to replace hazardous solvents and to promote benign alternatives. This service is provided to businesses that are looking to develop applications for waste streams or new bio-based products, and those who find access to their favoured solvents has become restricted due to regulations.

We have worked on projects with SMEs and international corporations, ranging from two-week exploratory studies to three-year funded PhD studentships.

A flowchart representing S4

We have expertise in the design and synthesis of new solvents, and a catalogue of applications with which to test them. Laboratory and pilot plant facilities are available to carry out extractions and fractionation in liquid or supercritical CO2. Supercritical chromatography and reactions systems are also available in addition to routine analytical equipment.

We also have a network of partner organisations who can offer additional services. To find out more about the use of these technologies in your business or research area please contact Dr James Sherwood.

Group members

Contact us

Green Chemistry Centre of Excellence
+44 (0)1904 322567
Department of Chemistry, University of York, Heslington, York YO10 5DD, United Kingdom.