Exploring the Radical Nature of a Carbon Surface by Electron Paramagnetic Resonance and a Calibrated Gas Flow

Podsumowanie

Stable radicals that are present in carbon substrates interact with paramagnetic oxygen through a Heisenberg spin exchange. This interaction can be significantly reduced under STP conditions by flowing a diamagnetic gas over the carbon system. This manuscript describes a simple method to characterize the nature of those radicals.

Streszczenie

While the first Electron Paramagnetic Resonance (EPR) studies regarding the effects of oxidation on the structure and stability of carbon radicals date back to the early 1980s the focus of these early papers primarily characterized the changes to the structures under extremely harsh conditions (pH or temperature)^1-3. It is also known that paramagnetic molecular oxygen undergoes a Heisenberg spin exchange interaction with stable radicals that extremely broadens the EPR signal^4-6. Recently, we reported interesting results where this interaction of molecular oxygen with a certain part of the existing stable radical structure can be reversibly affected simply by flowing a diamagnetic gas through the carbon samples at STP⁷. As flows of He, CO₂, and N₂ had a similar effect these interactions occur at the surface area of the macropore system.

This manuscript highlights the experimental techniques, work-up, and analysis towards affecting the existing stable radical nature in the carbon structures. It is hoped that it will help towards further development and understanding of these interactions in the community at large.

Wprowadzenie

Substrates of varying (wt%) ratios of C/H/O atoms present different types and concentrations of stable radicals that are detectable via Electron Paramagnetic Resonance (EPR)⁸. These radicals depend on the structure of the macromolecules and are highly influenced by their aromatic nature. The EPR spectrum of coal radicals is characterized by a single broad resonance. In such cases, only the g-value, the line width and the spin concentration can be obtained. The g-values of EPR spectra can be used to determine whether a radical is carbon-centered or oxygen-centered. The basic equation for the electron Zeeman interaction defines the g-value, where h is the Planck constant, v is the constant mw frequency applied in the experiment, B₀ is the resonance magnetic field and β_e is the Bohr magneton. For free electrons the g-value is 2.00232. Variations in the g-value from the 2.00232 are related to magnetic interactions involving the orbital angular momentum of the unpaired electron and its chemical environment. Organic radicals usually have g-values close to the free electron g, which depends on the location of the free radical in the organic matrix^3,8-10. Carbon-centered radicals have g-values that are close to the free electron g-value 2.0023. Carbon-centered radicals with an adjacent oxygen atom have higher g-values in the range of 2.003-2.004, while oxygen centered radicals have g-values that are >2.004. The g-value of 2.0034-2.0039 is characteristic for carbon-centered radicals in a nearby oxygen heteroatom that results in increased g-values over that of purely carbon-centered radicals^11-15. Line-width is governed by the spin-lattice relaxation process. Therefore, an interaction between adjacent radicals or between a radical and paramagnetic oxygen results in a decrease in the spin lattice relaxation time, and hence, an increase in the line-width^4-6.

Stopped flow experiments with EPR detection allow the observation of time-dependent changes in the amplitude of an EPR signal at a distinct field value during the interaction of two phases by time sweep acquisition (kinetic display). The result of such a measurement is a rate constant for the formation, decay or conversion of a paramagnetic species. The procedure is analogous to the well-established case of stopped flow operation with optical detection in which a time-dependence of the optical absorption at a distinct wavelength is observed. Typically stopped flow experiments are conducted in a liquid state as radicals that are not EPR detected in liquid state due to short relaxation time T₁, as e.g. hydroxyl (OH×) or superoxide (O₂^-) cannot be studied directly by EPR-stopped flow techniques. It is, however, possible to study the spin-adducts of these radicals with nitrones, yielding nitroxide-type radicals (spin-traps), as they are EPR-active and their kinetics can be monitored also by stopped flow EPR^16-18.

The method of measurement of rates of chemical reactions using fast-flow gaseous techniques with EPR detection has also previously been established^19-22. In essence, the method depends on the measurement, by EPR, of the concentration of a reactant as a function of distance (and thus at a constant velocity, the time) over which the reactant has been in contact with a reactive gas in the flow tube. Conditions whereby the concentration of the reactive gas is approximately constant are usually employed so that the measured decay is pseudo first order.

In the current work, a simple gas flow setup was implemented and a constant flow of gas was introduced to the surface of the solid carbon substrate.

With the method detailed in the current work we succeeded in achieving interesting results where this interaction of molecular oxygen with a certain part of the existing stable radical structure can be reversibly affected simply by flowing a diamagnetic gas through the carbon samples at STP. As a result of this method the removal of the interacting paramagnetic gas uncovers a new radical surface with a g value, which is closer to that of a free electron.

Protokół

1. Preparing Carbon Samples

1. Grind the carbon samples to the desired fraction size (here, coal samples were ground to a fraction size of between 74-250 mm).
2. During the grinding process the grinder should be held in a regulated environment (AC cooled to 20 °C). Additionally, purging the grinder chamber with a flow of nitrogen gas prior to grinding minimizes oxidation at this stage.
3. Transfer the carbon samples to sealable canisters and replace the air atmosphere with nitrogen. Keep the samples in a temperature regulated room (AC cooled to 20 °C). 
4. Prepare the carbon samples for EPR measurements by heating the carbon samples under an inert environment in the vacuum oven. (In order to remove the adsorbed water in the system.)
5. Place each of the samples in an open glass vial inside the vacuum oven (Figure 1A).
6. Close the vacuum oven door and replace atmosphere in the chamber with nitrogen or argon, then heat to 60 ºC.
7. Hold these conditions for 24 hr.
8. Turn off the oven and allow the temperature to reach room temperature. Then, open the oven and remove the sample vials.
9. Stopper the sample vials with rubber septa and an aluminum cap (Figure 1B).
10. Use a vacuum system (Figure 1C) to remove all traces of oxygen.
11. Connect the vial to the system and seal valves 1-5.
12. Turn on the vacuum pump and pressure gauges.
13. Open valve 1 and wait till the monitors show a vacuum of ~0.1 mbar.
14. Make sure leakage is minimal by closing valve 1 and counting to 30. If the increase in pressure is not more than 3 mbar than the seal of the system is sufficient.
15. Open valve 2 and remove the atmosphere in the vial – wait till the pressure returns to the initial pressure value determined in step 1.14 and again test for leakage.
16. If multiple vials are being done at the same time (valves 2-4) then repeat step 1.15 for each valve.
17. After achieving a vacuum and effectively purging the vials of the remaining atmosphere, replace the atmosphere with a desired gas.
18. Close valve 1 and immediately open valve 5 and allow the pressure to reach 0.5 atm.
19. Close valve 5 and open valve 1 to remove the gas, and wait until return to the starting vacuum valve (purge 1).
20. Close valve 1 and immediately open valve 5 and allow the pressure to reach 0.5 atm.
21. Close valve 5, open valve 1 to remove the gas and wait until return to the starting vacuum valve (purge 2).
22. Close valve 1 and immediately open valve 5, and allow the pressure to reach 1.0 atm, then close valve 5.
23. Close valve 2 and remove the vial by gently pulling downward and removing the needle.
24. After removing the vial open valve 1 and purge the gas from the vacuum system.
25. Before turning off the vacuum pump open valve 2 to allow air into the system and simultaneously turn off the pump (this prevents a backflow of the oil).

2. Loading EPR 3 mm Quartz Tubes

1. Rinse the EPR tube with ethanol and dry with N₂.
2. Remove the aluminum seal from the desired coal sample.
3. Gently turn the open end of the EPR tube into the vial filled with the carbon sample.
4. Depress and turn the EPR tube, then gently tap until the sample has evenly dispersed at the bottom.
5. Fill the tube in this manner up to a length of at least 1.5 cm.
6. Seal the tip of the tube with rubber Teflon putty of about 0.5-1.0 cm length of putty (Figure 2A).

3. Setting Up the Flow System

1. Insert the quartz tube into the EPR resonator, make sure that the section of the EPR tube filled with the coal is filling the entire resonator cavity.
2. The EPR measurements reported here were conducted at room temperature 292-297 K.
3. Set up a tank with the desired flow gas (N₂, CO₂, He) make sure there are 2 operation valves in order to control the flow (Figure 2B).
4. Connect a rubber tubing to the tank. Ensure that the length reaches the tip of the EPR quartz tube with enough pull so as not to put strain on the quartz tube.
5. Connect a flow controller to the rubber tubing to monitor gas flow.
6. Insert the tube through the rubber Teflon putty by using a small gauge needle.
7. Insert the needle until it is in close proximity (about 3-4 cm above the coal surface) to the sample but far enough away from the sample so as not to affect the magnetic field (Figure 2C).
8. Leave flow off  (turn on flow ONLY after tuning).
9. Poke a hole in the rubber putty to release the outflow gas.

4. EPR Measurement

1. Turn on the EPR spectrometer.
2. Tune with no gas flow. Open the microwave tuning panel, locate the dip at 33.0 dB power, and use auto tune for obtaining the best tuning conditions..
3. Set the microwave power to 2.0 mW, at this power there is no saturation.
4. Open 2D experiment, as a function of magnetic field and time.
5. Set the parameters of the experiment as follows:
   Microwave power = 2.0 mW
   Modulation amplitude = 1.0 G
   Time constant = 60 msec
   Sweep width = 100 G
   Delay = 120 sec
   No. of points for a field sweep scan = 1024
   No. of points as a function of time = 50
6. Start measurement cycle.
7. Turn on gas flow.
8. After the sample has reached equilibrium and there is no further change in the EPR line shape, at these parameters after about 25 CW-EPR spectra that were measured with 120 sec delay between them, stop the gas flow. Expose the sample to an air atmosphere and continue with the measurements until 50 spectra are obtained, or until equilibrium is reached. There is no need to tune again after stopping the gas flow. The measurement is continuing automatically, with 120 sec delay between each CW-EPR spectrum.
9. If equilibrium is reached at a slower rate, increase the number of points as a function of time.
10. If equilibrium is reached at much faster rate, decrease the delay time between each scan.

5. Data Analysis

1. Simulate each EPR field sweep spectrum using the easyspin toolbox implemented on MATLAB²³. Take two species into account, where for each species the g-value, the line width, and the extent of contribution to the EPR spectrum is fitted by writing the program file as follows:
   clear, clf, clc
   % Load experimental file
   expdata= load('t0s.txt');
   %Define spin system of species one
   SysC.g = 2.004;
   SysC.lwpp =0.62;
   %Define experiment parameters for species one
   Exp.mwFreq = 9.85764;   %in GHz
   Exp.Range=[347 357];      %in mT
   Exp.Harmonic=1;
   %calculate CW EPR spectrum for species one
   [Bx,specX] = pepper(SysC,Exp);
   %Define spin system of species two
   SysC2.g = 2.0028;
   SysC2.lwpp =0.145;
   %Define experimental parameters for species two
   Exp2.mwFreq = 9.85764;
   Exp2.Range=[347 357];
   Exp2.Harmonic=1;
   %calculate CW EPR spectrum for species two
   [Bx2,specX2] = pepper(SysC2,Exp2);
   x=0:0.1:1;
   % combine the spectrum of the two species.
   spectot=1.0*specX+0.0*specX2;
   %plotting the experimental and simulated spectra.
   Bx*10,spectot,expdata(:,1),expdata(:,2));

Wyniki

When preforming the EPR experiments on various coal samples, as a function of the exposure time to a diamagnetic gas flow it was noted that during the gas flow, a second species at g~2.0028 appeared. This g-value is close to the value of a free electron and consistent with unsubstituted aliphatic carbon centered radicals. However, the total spin concentration for each sample remained constant within our experimental error (±10%). Figure 3A presents two scans: 0 sec and 1,900 sec after the coal sampl...

Dyskusje

Surface oxidation of carbon materials is of significant industrial and academic interest. The effects of carbon substrate oxidation have been characterized with a wide range of analytical techniques including EPR. When investigating the interaction of molecular oxygen with carbon substrate such as coal which has a propensity to undergo oxidation (hence its main utilization as an energy resource) sample preparation and storage is extremely important.

Our samples are coal substrates that have be...

Materiały

Name	Company	Catalog Number	Comments
EPR spectrometer	Bruker	Elexsys E500
EPR quartz tube	Wilmad-Lab Glass
vacuum oven	Heraeus	VT6060
Balance	Denver Instrument	100A
High Vacuum Silicone Grease	VWR international	59344-055
Teflon putty
Laboratory (Rubber) Stoppers	Sigma-Aldrich	Z114111
Aluminum Crimp seals	Sigma-Aldrich	Z114146
Hand Crimper	Sigma-Aldrich	Z114243
Borosilicate vials	Sigma-Aldrich	Z11938
Rubber tubing
Aluminum hose clamps
Screwdriver
Custom made vacuum system
glass storage cylinders
BD Regular Bevel Needles	BD	305122
Helium	oxar LTD
Argon	oxar LTD
CO2       99.99%	Maxima
N2       99.999%	oxar LTD
O2	Maxima
Air	Maxima