Please use this identifier to cite or link to this item: https://hdl.handle.net/10321/4876
Title: Extraction of caffeine from spent coffee grounds using ionic liquids
Authors: Singh, Nikita 
Keywords: Sustainability Research;Waste coffee grounds;Recycling;Caffeine extraction;Ionic liquids;Green engineering
Issue Date: May-2023
Abstract: 
Coffee is the most popular beverage consumed and the second-highest commodity in the
world, after crude oil. In 2018, a total of 9,5 million metric tons of coffee were produced
globally. This in turn generated 6 million tons of waste coffee grounds. In South Africa alone,
it is estimated that approximately 100 million cups of coffee are brewed a year, resulting in
3000 tonnes of waste produced, of which 93% ends up in landfill sites (Lombard, 2021). This
abundant waste source has shown promising potential for reusing, recycling, or converting
the waste into valuable products like biofuels, fertilizers, animal feed, high-value chemicals,
cosmetics and pharmaceutical products such as caffeine for medicinal purposes. Besides
coffee being one of the most important agricultural commodities in the world, coffee is also
one of the most valuable primary products in world trade. Coffee is also the central and
popular activity of many cultures. The most popular reason for the consumption of coffee is
its refreshing properties. Large quantities of this waste pose threats to the environment as it is
a source of severe contamination and serious health problems. To avoid this catastrophe of
the coffee waste, spent coffee grounds can be utilised to generate valuable products. The
long-term usage of fossil fuels depletes the finite supply and contributes to greenhouse gas
(GHG) and exhaust emissions. The global economic and environmental crisis related to the
usage of fossil fuels and the fast depletion of natural resources has raised much awareness
and need to find alternate strategies for cleaner and greener energy and chemical products
needed for recycling waste has risen drastically. The use of biomass and other lignocellulosic
material to produce bio-fuels and other high value products show promising results. Using
lignocellulosic material has attracted considerable amounts of attention due its renewable
nature and being abundantly available. Lignocellulosic material is used for sustainable
development in the world. In this study caffeine extraction is a promising solution for
sustainable development, where biomass is valorised. The characterisation of spent coffee
grounds (SCGs) using Technical Association of the Pulp and Paper (TAPPI) methods was
carried out. The effect of temperature, reaction time and solid-to-liquid loading ratio on the
yield of caffeine extracted from spent coffee grounds was investigated. Simultaneously, the
best extraction solvent between the (i) ionic liquid (IL) 1-ethyl-3-methylimidazodium
chloride (98%), (ii) dichloromethane and (iii) water was determined. Variation of the
parameters were established using the Box-Behnken design of experiment (DOE)
methodology which varied the (i) temperature (88-120 degrees Celsius), (ii) reaction time
(15-35 minutes) and (iii) solid-to-liquid loading ratio (20 g/10-25 mL). For the extraction process, both the conventional method and green method (IL and water) were investigated.
The conventional method includes using dichloromethane as the extraction solvent, whereas
the green method makes use of the ionic liquid 1-ethyl-3-methylimidazolim chloride and
water as the extraction solvents. Extraction was carried out in a Parr pressure reactor where
solid-liquid extraction occurs. High performance liquid chromatography (HPLC) was used to
quantify the yield of extracted caffeine. Recrystallization of the highest caffeine yield was
carried out and thereafter analysed using Scanning Electron Microscopy (SEM), Transition
Electron Microscopy (TEM), Energy Dispersive Spectroscopy (EDS) and Differential
Scanning Calorimetry (DSC). The maximum yield of caffeine was obtained at the optimum
conditions of 120 °C for 25 minutes using 25 mL volume of extracting solvent. The caffeine
extracted from 1-ethyl-3-methylimidazolium, water and dichloromethane was 726.22mg/L,
646.33mg/L and 566.12mg/L respectively. Alternatively stated as 1-ethyl-3-
methylimidazolium chloride, water and dichloromethane extracted 0.00363 g caffeine / 1 g
SCG, 0.00323 g caffeine / 1 g SCG and 0.00283 g caffeine / 1 g SCG respectively.
SEM images of the spent coffee grounds prior to extraction displayed a dense morphological
chain-like structure, with large lumps present. The structure was tightly bonded together and
appeared rough. After extraction using each solvent, the SEM micrographs were analysed.
Extractions done with the IL demonstrated full degradation. The structure was loose, multiple
open pores on the surface with a smooth and thin appearance. The water extractions appeared
almost same to that of the IL, but slightly thicker. Lastly, extractions using DCM appeared to
be unsuccessful as the SCG attempted to be broken but were still together. The surface had
no open pores, rather an oil coated layer covering the spent coffee grounds.
EDS results from 99% pure caffeine standard was compared against the caffeine extracted by
all three extraction solvents. Pure caffeine appeared clean, properly formed, big separate
particles and distinctive shapes. The caffeine extracted using IL was similar to the structure,
crystallinity and appearance of the pure caffeine. Caffeine extracted by water were in long
shards, but not fully individual/separated. The caffeine extracted by DCM appeared less
crystalline, much smaller in size and more compact. DSC compared the melting points of the
pure caffeine standard to those caffeine samples extracted by different solvents, thus
providing the purity of the extracted caffeine. The standard caffeine sample had a melting
point of 233. 55 ºC equalling 99 % pure. The melting points of 226. 52 ºC; 212. 28 ºC and
200 ºC were obtained for IL, water and DCM respectively. Purity obtained were 96 %, 90 %
and 85 % per respective extraction solvent.
Description: 
Submitted in fulfillment of the requirements for the degree of Master of Engineering: Chemical Engineering, Durban University of Technology, Durban, South Africa, 2022.
URI: https://hdl.handle.net/10321/4876
DOI: https://doi.org/10.51415/10321/4876
Appears in Collections:Theses and dissertations (Engineering and Built Environment)

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