Post on 01-Aug-2020
Electrocatalytic Oxidation of Organic Pollutants:
Kinetic Considerations for Environmental Applications
Dr. Ronald Vargas
Electrochemistry LaboratoryChemistry Department
Universidad Simón BolívarCaracas - Venezuela
UNIVERSIDAD SIMÓN BOLÍVAR
INTRODUCTION
ENVIRONMENTAL ELECTROCHEMISTRY
ELECTROCHEMISTRY OF OXYGEN TRANSFER
NEW DEVELOPMENTS
CONCLUSIONS
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ELECTROCHEMISTRY
… Electrochemistry is about reducing tensions, as the French callthe voltage, and being aware of current events …
Thermodynamics
Kinetics:
dn/dt = i / (nF)
1 molecule is around 0.1 nm, and
under 1 V implies:
100 MV/cm of potential gradient!Fig 1. Electrochemical cell
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Fig 2. Key steps forenvironmental goal usingEOTR.
ELECTROCHEMICAL OXYGEN TRANSFER REACTION (EOTR)
Vargas. R., et al. J. Solid. Stated. Electrochem. 20(4) (2016) 875
is any pollutant molecule
How does affect the molecularstructure of the organic compound?
THE CHARGE TRANSFER INTERMEDIATE!
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Fig 3. Spectroelectrochemical observation of the charge transfer intermediate.
Case: p-metoxiphenol on PbO2-Bi
From the temperaturedependence we obtained the free energy of activation! Δ‡G200 300 400 500 600
0
/ nm
R/R = 0,02
to=0s
tf=1s
Vargas. R., et al. J. Solid. Stated. Electrochem. 20(4) (2016) 875
account the driven force!
MATHEMATHICAL MODEL OF THE ELECTROCHEMICAL PROCESS
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Vargas. R., et al. Electrochim. Acta. 80 (2012) 326
Current equation (new reaction rate model)
Langmuir – Hinshelwood equation Levich diffusion length
Convective - diffusive equation
kKc
1 + Kc
From appropiate kinetic experiments thecharacteristic constants (k and K) can be evaluated!
VOLCANO PLOT AND LINEAR FREE ENERGY CORRELATIONS
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Fig 5. Volcano plot on PbO2-Bi
Vargas. R., et al. J. Solid. Stated. Electrochem. 20(4) (2016) 875
The stability conditionsat the interface can beredefined!
kinetics thermodynamics
Fig 6. Structure – reactivity relationships on PbO2-Bi
Phenolic family:
p-nitrophenol, p-cyanophenol,
Phenol,p-methylphenol, p-methoxyphenol
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1) A new structure – reactivity relationships have been envisaged.
2) The charge transfer reaction rate and the adsorption propertiesat the electrode are decoupled using a new kinetic model.The transport phenomena with surface reaction model.
3) The chemical kinetic of an organic compound family caninvolves a volcano plot in the EOTR.
CONCLUSIONS
THANK YOU
Dr. Ronald Vargas
Electrochemistry LaboratoryChemical DepartmentUniversidad Simón BolívarOfc. QYP-215Correo: ronaldvargas@usb.ve
Research interests:
Fundamental ElectrochemistryPhysical ChemistryEnergy and EnvironmentChemical Sciences
@labequsbhttp://www.labeq.usb.ve/
Acknowledgments:
TWAS-TYAN / ICSU ROLAC / TWAS ROLAC
Patricia Zancan and the organizing committee
Satisfactory results in many water polluted systems:
- Insecticides, pesticides, herbicides
- Phenols, poly aromatic heterocyclic compounds, chlorinated compounds
- Municipal wastewaters: urea, surfactant, e-coli
- Highly polluted biphasic media (oil from petroleum wastes / water)
ELECTROLYSIS TIMEFig A1. Petroleum residual dissolve with surfactant in water media
OBSERVATIONS AND POSIBILITIES
Fig A2. Spectral signal decay as a function of experimental parameters
Potential and temperature increment
EXPERIMENTAL VALIDATION FOR PHENOLIC COMPOUNDS
EXPERIMENTAL VALIDATION FOR PHENOLIC COMPOUNDS
Vargas. R., et al. Electrochim. Acta. 80 (2012) 326
Méndez. D., et al. App. Catal. B:Environ. 166-167 (2015) 529
Fig A3. (A) (reaction rate) -1 vs. (matter flux) -1/2 plot for two electrodes. (B) Reaction rate results envisage the structure – reactivity relationships
Phenolic family:p-nitrophenol, p-cyanophenol, phenolp-methylphenol, p-methoxyphenol
(matter flux) -1/2 (rad/s) -1/2
(re
ac
tio
n r
ate
) -1
(m
ol / s
) -1
no
rma
lize
d r
ea
cti
on
ra
te
concentration (M)
(A) (B)
x
K and k accounts the chemical effects
1,2 1,4 1,6 1,8 2,00
1
2
3
4
E / V vs. ECS
kobs / s
-1
1,2 1,4 1,60
2
4
6
8
10
12
14
E / V vs. ECS
kobs / s
-1
a) b)
Fig A4. Potential effect.
PMF
PNF
PMF
PNF
a) PbO2-Bi b) SnO2-Sb
EXPERIMENTAL VALIDATION FOR PHENOLIC COMPOUNDS