9.1 Catalyst characterization using thermal conductivity detector (Page 4/4)

Page 4 / 4

V_{adsorbed} = \frac{{ΔArea}_{n} {×F}_{c}}{SW}

Includes the volume adsorbed per pulse and the cumulative volume adsorbed.

Pulse n	area _n	Δarea _n	V _adsorbed (cm ³ /g STP)	Cumulative quantity (cm ³ /g STP)
1	0	0.0105809790	0.2800256	0.2800256
2	0.000471772	0.0105338018	0.2787771	0.5588027
3	0.00247767	0.0081033090	0.2144541	0.7732567
4	0.009846683	0.0007342960	0.0194331	0.7926899
5	0.010348201	0.0002327780	0.0061605	0.7988504
6	0.010030243	0.0005507360	0.0145752	0.8134256
7	0.009967717	0.0006132620	0.0162300	0.8296556
8	0.010580979	0	0.0000000	0.8296556

Gram molecular weight

Gram molecular weight is the weighted average of the number of moles of each active metal in the catalyst. Since this is a monometallic catalyst, the gram molecular weight is equal to the molecular weight of palladium (106.42 [g/mol]). The GMC _Calc is calculated using [link] , where F is the fraction of sample weight for metal N and W _atomicN is the gram molecular weight of metal N (g/g-mole). [link] shows the calculation for this experiment.

{GMW}_{Calc} = \frac{1}{(\frac{F_{1}}{W_{atomic1}}) + (\frac{F_{2}}{W_{atomic2}}) + ... + (\frac{F_{N}}{W_{atomicN}})}

{GMW}_{Calc} = \frac{1}{(\frac{F_{1}}{W_{atomicPd}})} = \frac{W_{atomicPd}}{F_{1}} = \frac{106 .42 \frac{g}{g-mole}}{1} =106 .42 \frac{g}{g-mole}

Metal dispersion

The metal dispersion is calculated using [link] , where PD is the percent metal dispersion, V _s is the volume adsorbed (cm ³ at STP), SF _Calc is the calculated stoichiometry factor (equal to 2 for a palladium-hydrogen system), SW is the sample weight and GMW _Calc is the calculated gram molecular weight of the sample [g/g-mole]. Therefore, in [link] we obtain a metal dispersion of 6.03%.

PD \underset{}{} = 100 \times (\frac{V_{s} \times {SF}_{Calc}}{SW \times 22414}) \times {GMW}_{Calc}

PD=100× (\frac{0 .8296556 [{cm}^{3}] ×2}{0 .1289 [g] ×22414 [\frac{{cm}^{3}}{mol}]}) ×106 .42 [\frac{g}{g-mol}] = 6.03 %

Metallic surface area per gram of metal

The metallic surface area per gram of metal is calculated using [link] , where SA _Metallic is the metallic surface area (m ² /g of metal), SW _Metal is the active metal weight, SF _Calc is the calculated stoichiometric factor and SA _Pd is the cross sectional area of one palladium atom (nm ² ). Thus, in [link] we obtain a metallic surface area of 2420.99 m ² /g-metal.

{SA}_{Metallic} = (\frac{V_{S}}{{SW}_{Metal} ×22414}) × ({SF}_{Calc}) × (6 {.022×10}^{23}) {×SA}_{Pd}

{SA}_{Metallic} = (\frac{0 .8296556 [{cm}^{3}]}{0 .001289 [g_{metal}] ×22414 [\frac{{cm}^{3}}{mol}]}) × (2) × (6 {.022×10}^{23} [\frac{atoms}{mol}]) ×0 .07 [\frac{{nm}^{2}}{atom}] =2420 .99 [\frac{m^{2}}{g-metal}]

Active particle size

The active particle size is estimated using [link] , where D _Calc is palladium metal density (g/cm ³ ), SW _Metal is the active metal weight, GMW _Calc is the calculated gram molecular weight (g/g-mole), and SA _Pd is the cross sectional area of one palladium atom (nm ² ). As seen in [link] we obtain an optical particle size of 2.88 nm.

APS= \frac{6}{D_{Calc} × (\frac{W_{s}}{{GMW}_{Calc}}) × (6 {.022×10}^{23}) {×SA}_{Metallic}}

APS= \frac{600}{(1 {.202×10}^{-20} [\frac{g_{Pd}}{{nm}^{3}}]) × (\frac{0 .001289 [g]}{106 .42 [\frac{g_{Pd}}{mol}]}) × (6 {.022×10}^{23} [\frac{atoms}{mol}]) × (2420 .99 [\frac{m^{2}}{g_{Pd}}])} =2 .88nm

In a commercial instrument, a summary report will be provided which summarizes the properties of our catalytic material. All the equations used during this example were extracted from the AutoChem 2920-User's Manual.

Summary report provided by Micromeritics AuthoChem 2920.

Properties	Value
Palladium atomic weight	106.4 g/mol
Atomic cross-sectional area	0.0787 nm²
Metal density	12.02 g/cm³
Palladium loading	1 wt%
Metal dispersion	6.03%
Metallic surface area	2420.99 m²/g-metal
Active particle diameter (hemisphere)	2.88 nm

References

A. J. Canty, Accounts Chem. Res. , 1992, 25 , 83.
H. S. Fogler, Elements of Chemical Reaction Engineering , Prentice-Hall, New York (1992).
Micromeritics Instrument Corporation, AutoChem 2920 – Automated catalyst characterization system – Operators Manual , V4.01 (2009).
M. O. Nutt, K. N. Heck, P. Alvarez, and M. S. Wong, Appl. Catal. B-Environ. , 2006, 69 , 115.
M. O. Nutt, J. B. Hughes, and M. S. Wong, Environ. Sci. Technol. , 2005, 39 , 1346.
P. A. Webb and C. Orr, Analytical Methods in Fine Particle Technology , Micromeritics Instrument Corp, 1997.
R. Zhang, J. A. Schwarz, A. Datye, and J. P. Baltrus, J. Catal. , 1992, 138 , 55.

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Source: OpenStax, Physical methods in chemistry and nano science. OpenStax CNX. May 05, 2015 Download for free at http://legacy.cnx.org/content/col10699/1.21

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