The role of positron annihilation lifetime studies and nuclear sensors for characterising porous materials

E. Mume; A. Uedono; G. Mizunaga; D. E. Lynch; S. V. Smith

doi:10.1088/1742-6596/262/1/012040

The role of positron annihilation lifetime studies and nuclear sensors for characterising porous materials

E. Mume^*, A. Uedono, G. Mizunaga, D. E. Lynch, S. V. Smith

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

A series of nuclear sensors were designed to assess the chemistry within the nanopores of a porous material. The nuclear sensors of varying size, charge, and hydrophobicity were exposed to hollow silica shells (HSS) at varying pH. Uptake and release kinetics were studied over a 24 h period at room temperature. Preliminary study indicate positively charged nuclear sensors were selectively and rapidly (within 10 min) absorbed by the HSS at pH 7 to 9. PALS showed there were two types of pores (1.7 and 0.7 nm) present. The data suggest the nuclear sensors sit within the larger pore of the HSS. Both PALS and nuclear sensors are required to obtain an accurate insight into the nanoporosity of the hollow silica shells.

Original language	English
Article number	012040
Journal	Journal of Physics: Conference Series
Volume	262
Issue number	1
DOIs	https://doi.org/10.1088/1742-6596/262/1/012040
Publication status	Published - 2011

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title = "The role of positron annihilation lifetime studies and nuclear sensors for characterising porous materials",

abstract = "A series of nuclear sensors were designed to assess the chemistry within the nanopores of a porous material. The nuclear sensors of varying size, charge, and hydrophobicity were exposed to hollow silica shells (HSS) at varying pH. Uptake and release kinetics were studied over a 24 h period at room temperature. Preliminary study indicate positively charged nuclear sensors were selectively and rapidly (within 10 min) absorbed by the HSS at pH 7 to 9. PALS showed there were two types of pores (1.7 and 0.7 nm) present. The data suggest the nuclear sensors sit within the larger pore of the HSS. Both PALS and nuclear sensors are required to obtain an accurate insight into the nanoporosity of the hollow silica shells.",

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AU - Smith, S. V.

PY - 2011

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AB - A series of nuclear sensors were designed to assess the chemistry within the nanopores of a porous material. The nuclear sensors of varying size, charge, and hydrophobicity were exposed to hollow silica shells (HSS) at varying pH. Uptake and release kinetics were studied over a 24 h period at room temperature. Preliminary study indicate positively charged nuclear sensors were selectively and rapidly (within 10 min) absorbed by the HSS at pH 7 to 9. PALS showed there were two types of pores (1.7 and 0.7 nm) present. The data suggest the nuclear sensors sit within the larger pore of the HSS. Both PALS and nuclear sensors are required to obtain an accurate insight into the nanoporosity of the hollow silica shells.

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The role of positron annihilation lifetime studies and nuclear sensors for characterising porous materials

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