Anomalous reduction in surface area during mechanical activation of boehmite synthesized by thermal decomposition of gibbsite

Mechanical activation of boehmite (γ-AlOOH), synthesized by thermal decomposition of gibbsite, has been carried out in a planetary mill up to 240 min. After an initial decrease in particle size up to 15 min, the particle size shows an increase with further milling; the median size (d 50) has increas...

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Bibliographic Details
Published in:Powder technology 2011-03, Vol.208 (1), p.128-136
Main Authors: Alex, T.C., Kumar, Rakesh, Roy, S.K., Mehrotra, S.P.
Format: Article
Language:English
Subjects:
Adsorption
Agglomeration
Aluminum base alloys
Amorphisation
Applied sciences
Bayer process
Boehmite
Chemical engineering
desorption
Exact sciences and technology
Fourier transform infrared spectroscopy
gibbsite
Grinding
Mechanical activation
Microstrain
milling
Miscellaneous
nitrogen
particle size
Pore size distribution
Porosity
Reactivity
scanning electron microscopy
Sintering, pelletization, granulation
sodium hydroxide
Solid-solid systems
Surface area
temperature
Thermal decomposition
thermal degradation
X-radiation
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Summary:Mechanical activation of boehmite (γ-AlOOH), synthesized by thermal decomposition of gibbsite, has been carried out in a planetary mill up to 240 min. After an initial decrease in particle size up to 15 min, the particle size shows an increase with further milling; the median size (d 50) has increased from 1.8 to 5 μm during 15 to 240 min of milling. Quite unexpectedly, the BET specific surface area of the sample (N 2 adsorption method) decreases continuously from 264 m 2/g to 67 m 2/g with milling. A detailed analysis of N 2 adsorption/desorption isotherms has indicated that the decrease in surface area is associated with: (a) change in narrow slit like pores with microporosity to slit shaped pores originating from loose aggregate of platelet type particles; and (b) shift of maxima in pore size distribution plot at ~ 2 nm and ~ 4 nm to dominantly ~ 23 nm size pores. Scanning electron microscopy (SEM) studies have revealed that during milling, initial breakage is followed by agglomeration/fusion of particles with consequent loss in porosity. Amorphisation, decrease in microcrystallite dimension (MCD) and increase in microstrain (ε) are indicated from a detailed analysis of X-ray powder diffraction patterns and Fourier Transform Infrared (FTIR) spectra. Reactivity of samples, expressed in terms of increase in dissolution in alkali (in 8 M NaOH at 90 °C) and decrease in boehmite to γ-Al 2O 3 transformation temperature, increases with milling time. The nature of correlations between reactivity and physico-chemical changes during milling has been analyzed and discussed. The specific surface area of boehmite synthesized by thermal decomposition of gibbsite has been observed to decrease with mechanical activation as a result of aggregation/fusion of particles and changes in pore structure. However, the reactivity of samples increased and has been attributed to pore size modification and generation of increased high energy regions resulting from the decreasing microcrystallite dimension and increasing microstrain. [Display omitted] ► Planetary milling of boehmite synthesised by thermal decomposition of gibbsite. ► BET surface area of the boehmite sample anomalously decreased with milling time. ► Particle aggregation and changes in nature of pore structure caused the decrease. ► Structural changes: decrease in microcrystallite size and increase in microstrain. ► Energy stored during milling enhanced the reactivity despite surface area decrease.
ISSN:0032-5910
1873-328X
DOI:10.1016/j.powtec.2010.12.010