Publication detail
Mechanism and kinetics of wollastonite fibre dissolution in the aqueous solution of acetic acid
PTÁČEK, P. BRANDŠTETR, J. KŘEČKOVÁ, M. ŠOUKAL, F. OPRAVIL, T.
Original Title
Mechanism and kinetics of wollastonite fibre dissolution in the aqueous solution of acetic acid
English Title
Mechanism and kinetics of wollastonite fibre dissolution in the aqueous solution of acetic acid
Type
journal article in Web of Science
Language
en
Original Abstract
The dissolution of fibrous wollastonite in the aqueous solution of acetic acid was investigated in the temperature interval from 25 to 50 C using mixed batch type reactor. The process is handled by the rate of the stationary two-dimensional diffusion (D2). The apparent activation energy and pre-exponential factor are 47 kJ per mol.
English abstract
The dissolution of fibrous wollastonite in the aqueous solution of acetic acid was investigated in the temperature interval from 25 to 50 C using mixed batch type reactor. The process is handled by the rate of the stationary two-dimensional diffusion (D2). The apparent activation energy and pre-exponential factor are 47 kJ per mol.
Keywords
Wollastonite CaSiO3 Acetic acid Dissolution of silicates Dissolution mechanism Dissolution kinetics
RIV year
2011
Released
30.01.2011
Publisher
Elsevier
Location
ELSEVIER SCIENCE SA, PO BOX 564, 1001 LAUSANNE, SWITZERLAND
ISBN
0032-5910
Periodical
POWDER TECHNOLOGY
Year of study
206
Number
3
State
CH
Pages from
338
Pages to
344
Pages count
7
Documents
BibTex
@article{BUT41769,
author="Petr {Ptáček} and Jiří {Brandštetr} and Magdaléna {Křečková} and František {Šoukal} and Tomáš {Opravil}",
title="Mechanism and kinetics of wollastonite fibre dissolution in the aqueous solution of acetic acid",
annote="The dissolution of fibrous wollastonite in the aqueous solution of acetic acid was investigated in the temperature interval from 25 to 50 C using mixed batch type reactor. The process is handled by the rate of the stationary two-dimensional diffusion (D2). The apparent activation energy and pre-exponential factor are 47 kJ per mol.",
address="Elsevier",
chapter="41769",
institution="Elsevier",
number="3",
volume="206",
year="2011",
month="january",
pages="338--344",
publisher="Elsevier",
type="journal article in Web of Science"
}