Title:Mixed-Metal MOF-Derived Carbon Sponges for Oil Absorption
Volume: 16
Issue: 2
Author(s): Cesar M. Oliva González, Ana de Monserrat Navarro Tellez, Boris I. Kharisov*, Juan Marcos Guillén Hernández, Thelma E. Serrano Quezada, Lucy T. González and Idalia Gómez de la Fuente
Affiliation:
- Universidad Autónoma de Nuevo León, Ave. Universidad s/n, San Nicolás de los Garza, N.L., C.P. 66455, México
Keywords:
Carbon sponges, hydrophobic materials, metal-organic frameworks, trimesic acid, monometallic, paraffin, lubricants, kerosene, polystyrene.
Abstract:
Aims: In this work, we propose the implementation of three carbon sponges, generated from the
carbonization of melamine-formaldehyde sponges coated with different HKUST-type metal-organic frameworks
(MOFs) in different thermal conditions.
Background: Nowadays, numerous investigations are focused on the development of new technologies for the
rapid separation of water/oil mixtures. Several of these processes use hydrophobic materials of different nature
for efficient oil capture. Despite these efforts, the water/oil separation still remains a great challenge. The main
oil absorbers that are commercially available tend to be expensive and have complex synthesis; however, they
usually have an acceptable cost/benefit ratio. Despite this, the passage of time has brought us new generations
of materials, which seek to solve the problems in a more efficient way, as in the case of metal-organic frameworks
(MOFs), which stand out for the great ease with which their morphological and surface aspects can be
controlled. MOFs are extensively investigated in the fields of adsorption and catalysis; the MOF coated sponges
do not meet the selectivity and stability standards to be applied in oil spills in water. However, this completely
changes when subjected to the pyrolysis process, giving the material an increase in its surface area,
hydrophobic and magnetic properties in addition to making the material suitable for its application.
Objective: Creation of a low-cost 3D template and the study of morphological properties of MOFs, for the
formation of carbon-based materials by a fast, simple and low-cost method, promoting the use of new generations
of materials to more effectively solve persistent environments.
Methods: The employed MOF precursors were trimesic acid (BTC), nickel and cobalt salts. The monometallic
HKUST type MOFs were synthesized using a simple method of controlled precipitation, which starts from two
precursor solutions. The first one consisted of a ligand solution, dissolving the BTC in deionized water. In the
case of mixed-metal MOFs, they were synthesized using the same procedure described for monometallic
MOFs, but in this case, a mixture of metal salts with a 1:1 molar ratio was performed. The methodology for the
production of the sponges decorated with MOF was carried out in two steps. In the first stage, the sponges were
subjected to a wash to remove dust and impurities, being rinsed with acetone in an ultrasonic bath for 30 min.
The sponges were subsequently immersed in deionized water and subjected to an ultrasonic bath for 10 min.
Finally, the sponges were dried at 60°C for 3 h. The second step was the addition of the HKUST-type MOFs to
the sponges was carried out by means of the immersion method, preparing a dispersion of the corresponding
MOFs in ethanol.
Results: It was revealed that the carbon sponges can selectively absorb oil in the water/oil mixture, possessing
magnetic and enhanced hydrophobic and superhydrophobic properties. All the pyrolyzed carbon sponges, obtained
at 500 and 700°C, were not the most optimal since they had absorption capacities of around 25 g/g and
only supported up to 4 absorption cycles. On the other hand, the carbon sponges, obtained at 300°C, had absorption
capacities greater than 40 g/g, in addition to being able to be reused up to 12 times without showing
significant changes in their absorption capacity and having acceptable hydrophobic characteristics for the removal
of oil dispersed in water. Among the three sponges obtained at 300°C, we highlight the sponges coated
with BTC-Co, which have the highest absorption capacity (54 g/g) among all fabricated sponges.
Conclusions: The sponges obtained in the present work are a promising alternative to the materials that are
traditionally used since they have great advantages such as their simple production method, low-cost starting
materials and good absorption capacities. This work sheds light on the production of carbon materials from 3D
templates decorated with MOFs, through a one-step carbonization process and we demonstrate that these materials
have characteristics that make them applicable in the removal of oil dispersed in water, giving us a practical,
economic and friendly alternative to the environment.