1 / 38

OUTLINE: Short review of theory Experimental methods and machinery at the lab Case studies

N 2 – ADSORPTION theory, experiment and application. OUTLINE: Short review of theory Experimental methods and machinery at the lab Case studies. ADSORPTION. theory. adsorbent. adsorbate. adsorptive. some properties of adsorption (physisorpion):

caroled
Download Presentation

OUTLINE: Short review of theory Experimental methods and machinery at the lab Case studies

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. N2 – ADSORPTION theory, experiment and application • OUTLINE: • Short review of theory • Experimental methods and machinery at the lab • Case studies

  2. ADSORPTION theory adsorbent adsorbate adsorptive • some properties of adsorption (physisorpion): • exothermic, non-specific, adsorption energy low, • not activated, multilayer, no dissociation/electron transfer

  3. ADSORPTION INTERACTIONS theory • Adsorption interactions: • adsorbent and adsorptive are important • Examples:

  4. ADSORPTION ISOTHERM theory • amount of N2 adsorbed versus relative pressure at constant temperature • temperature: 77 K: boiling/condensation point of N2 at patm=p° • Amount adsorbed • per unit adsorbent mass: • n mol/g • Vads, liq ml/g = cm3/g • Vads, STP ml/g • … • STP = 0 °C, 1 bar

  5. ADSORPTION ISOTHERMS: TYPES theory • IUPAC classification:

  6. gas vacuum P Liq. N2 • EXPERIMENTAL • how is an adsorption isotherm recorded? • Total volume of system determined: • - “manifold” volume known • - sample volume determined with He • System is evacuated • Start of adsorption: • - amount of gas dosed in manifold • - p measured  qty known • - gas expanded into sample volume • - equilibrium p measured; compared to calcd p • - difference  amount adsorbed at p • p° measured to account for temp changes in liq. N2 • Lower p/p° limit: determined by • pump and pressure measurement manifold sample

  7. MACHINERY AT COK experimental Micromeritics Tristar 2 x Coulter Omnisorp • continuous method: • dosing: constant low flow • quasi-equilibrium • measure pressure • infinite amount of points • long measurements • p/p°min: 10-4 – 10-3 (“left” omnisorp) • p/p°min: 10-5 – 10-4 (“right” omnisorp) • discontinuous method: • amounts of gas dosed • wait until equilibration • measure pressure • limited amount of points • short measurement possible • three samples simultaneously • p/p°min: 10-4 – 10-3

  8. SPECIFIC SURFACE AREA theory • 2 frequently used methods: • BET • Comparative methods: t-plot or aS-plot • general remark on concept of determination of the specific surface area : • - surface roughness – probe molecule size • - measured area dependent on size of probe molecule: fractal property

  9. SPECIFIC SURFACE AREA SPECIFIC SURFACE AREA: BET theory • Two steps: • 1. Evaluation of the monolayer capacity Vm • 2. N2 cross-sectional area aN2: Vm x aN2 = S • Not very accurate (20 % error) because: • BET model assumptions usually not valid • homogeneous surface, no lateral interactions, infinite number of layers possible, n+1: liquefaction energy • 2. value of cross-sectional area not determined accurately/ dependent on adsorbent surface (usually: 0.162 nm2) • 3. Pore size/shape may change interpretation • Mesoporous silica: overestimation Small cilindrical pores: 10 % underestimation

  10. SPECIFIC SURFACE AREA SPECIFIC SURFACE AREA: COMPARATIVE theory • compare adsorption behaviour of unknown with behaviour of • macroporous material with similar surface properties • standard silica reference: hydroxylated silica • you can always make a reference yourself • t-plot, as plot

  11. SPECIFIC SURFACE AREA SPECIFIC SURFACE AREA: COMPARATIVE theory sample isotherm comparative plot Vads t or as ~Vads, ref p/p° p/p° reference isotherm • adsorption behaviour (isotherm) of reference is plotted on x-axis as t or as

  12. SPECIFIC SURFACE AREA SPECIFIC SURFACE AREA: COMPARATIVE theory • reference adsorption scaled as t or as: t-plot: SBET of reference incorporated!

  13. SPECIFIC SURFACE AREA SPECIFIC SURFACE AREA: COMPARATIVE theory • evaluation of the surface area from slopes Vads st or sas ~Sext • fit linear portion with straight line • linear = same adsorption behaviour as ref st or sas ~Smeso+Sext t or as • dependent on SBET reference!

  14. Vads Vmeso t or as PORE VOLUMES FROM COMPARATIVE METHOD theory Vtotal Vmicro • independent of SBET reference!

  15. MICROPORE SIZE theory • micropore size determination: Horvath-Kawazoe model • estimated p/p° at which micropores of diameter d fill • (slit shape, carbon black): • p/p° < 10-5 necessary to investigate first stages of micropore filling • at the lab: only Right Omnisorp machine (p/p° min ~ 10-5)

  16. MICROPORE SIZE theory Artefact! 0.63 nm • Zeolites: • MFI (pore size ~ 5.5 Angstrom); right Omnisorp • FAU (window size ~ 7.4 Angstrom); left Omnisorp • Look at results with criticism!

  17. MESOPORE SIZE DISTRIBUTION theory • BJH model: mesopore filling is due to • Pressure dependant film formation on mesopore walls • Classical t-curves: • Condensation pressure – pore width • Kelvin equation • Use desorption isotherm with hemispherical meniscus (rm) • rp = rk + t (Halsey: usually not preferable)

  18. Vads 0.4 p/p° MESOPORE SIZE DISTRIBUTION theory • BJH model: problems with ordered mesoporous materials • Adsorbed layer thickness underestimated (wall curvature) • Use of desorption branch: • Instability of condensate at p/p° ~ 0.4 (4 – 5.5 nm) during desorption: • tensile strength effect • Desorption branch more prone to material imperfections (network effects)

  19. MESOPORE SIZE DISTRIBUTION theory • improved BJH model: KJS (Kruk – Jaroniec – Sayari) • widely used to determine mesopore size OMM • Corrected t-curve based on standard adsorption isotherm • 2. Correction for increased film thickness due to mesopore curvature • 3. Use of ADsorption isotherm (Kelvin for hemispherical meniscus) • Application between 2 – 10 nm; above 6 nm accuracy decreases • Application for cilindical pores (MCM-41) or cilinder-like pores (MCM-48)

  20. MESOPORE SIZE: OTHER METHODS theory • methods for hexagonal mesoporous materials (e.g. MCM-41, SBA-15) • the “4V/S” method • from mesopore volume and XRD • Void fraction via • geometry • density • d100 = first reflection in XRD pattern • = 2.2 g/cm3 for amorphous silica

  21. 1 µm CASE STUDY I: nano Silicalite-1 • synthesis: • TPA + silica  nano Silicalite-1 particles  porous nano S1 particles • structure calcination HT Micropore diameter: ~ 5.5 Angstrom Particle size ~ 100 nm

  22. CASE STUDY I: nano Silicalite-1 • adsorption isotherms (Right Coulter) • fresh: ~ type III : TPA in pores/on surface: apolar surface • calcined: type I: microporous • p/p° > 0.9: interparticle capillary condensation

  23. CASE STUDY I: nano Silicalite-1 • adsorption isotherms: logarithmic plot • fresh: very low uptake at low p/p°: apolar surface • calcined: micropores give high uptake below p/p°= 10-3

  24. DETERMINATION OF THE SURFACE AREA nano Silicalite-1 1. BET method fresh calcined washed fitted p/p° range: 0.05 – 0.3 • good linearity for the washed sample, difficult for calcined • calcined sample: negative intercept

  25. DETERMINATION OF THE SURFACE AREA nano Silicalite-1 • BET method • analysis results (fitted range: 0.05 – 0.3): • validity check of BET model: 50 < C < 200 • washed sample: too low C value •  low adsorbent-adsorbate interaction (TPA on surface) • gives only indication of surface area • calcined: negative C: BET model not valid • Overlap micropore filling – monolayer formation BET not applicable on organic surfaces and microporous solids

  26. DETERMINATION OF THE SURFACE AREA nano Silicalite-1 2. Comparative method t-plot; SBET, REF = 25 m2/g fresh • intercept < 0 • no linear regions: adsorption behaviour ≠ reference (organic surface) • t-plot not applicable: bad reference

  27. DETERMINATION OF THE SURFACE AREA nano Silicalite-1 2. Comparative method t-plot; SBET, REF = 25 m2/g calcined • t<0.2: highly nonlinear: micropore filling • good linearity in region t= 0.4 – 1 : reference behaviour • intercept: 0.12 mL/g=micropore volume • slope: 140 m2/g

  28. DETERMINATION OF THE SURFACE AREA nano Silicalite-1 • Conclusions: • fresh sample: BET better method (40 m2/g) • calcined sample: comparative method preferable (140 m2/g) • although this method relies indirecly on the BET method, • via the BET determination of the reference surface area) • comparative method gives also micropore volume

  29. 10 nm 100 nm CASE STUDY II: Mesopore size of Zeotile-6 • Ordered mesoporous material prepared from MFI nanoslabs • 2D hexagonal P6m XRD TEM 100 100 intensity 110 110 200 200 210 210 300 300 220 220 310 310 0 0 2 2 4 4 6 6 8 8 10 10 2 theta / 2 theta / ° °

  30. ISOTHERM Zeotile-6 calcined • type IV with small hysteresis loop

  31. COMPARATIVE – as Zeotile-6 *BET area = 1100 m2/g: probably overestimated

  32. MESOPORE SIZE Zeotile-6 • the “4V/S” method • From SBET: From Sas: • Highly dependent on S! • from mesopore volume and XRD • ramorphous silica (2.2 g/ml): rSilicalite-1 (1.8 g/ml): • Only slightly dependent on r

  33. MESOPORE SIZE DISTRIBUTION Zeotile-6 • Classical: 3.2 nm • Modified: 3.9 nm

  34. MESOPORE SIZE: SUMMARY Zeotile-6 • Best methods for hexagonal mesoporous materials: • Vmeso and XRD: size • KJS: size distribution

  35. CONCLUSIONS • surface area : better with comparative method than BET • IF good reference • pore volumes: easily determinable with comparative methods • micropore size: limited possibilities in the lab • mesopore size: know that • - traditional BJH underestimates pore size of • mesoporous silicas, especially in the range of 2 – 6 nm • - alternative/improved methods • if detailed analysis needed, verify software settings

  36. SPECIFIC SURFACE AREA SPECIFIC SURFACE AREA: COMPARATIVE theory sample isotherm comparative plot Vads t or as ~Vads, ref p/p° p/p° reference isotherm • adsorption behaviour (isotherm) of reference is plotted on x-axis as t or as

  37. SURFACE AREA – BET Zeotile-6 Nicely linear

  38. بزرگترین بانک پاورپوینت ایرانwww.txtzoom.comبانک هوشمند اسناد متنی

More Related