Research Highlights

Ghost-Template Synthesis of Amorphous Hollow Silica Nanostructures

2022-03-16 59

[POSTECH research team led by Professor In Su Lee develops a new synthesis procedure for amorphous hollow silica nanostructure using metal salts.]

One of the core strategies of nanotechnology is nanostructures, which can be described as a container – smaller than a few hundred thousand the size of a hair strand – that can carry or transport materials. They are widely used as a drug-delivery device or catalyst and can carry more materials if they have a hollow interior, which increases their efficiency. The challenge has been synthesizing these nanostructures – they were usually synthesized by making a template and removing it. A Korean research team has recently proposed a new synthesis technique to fabricate a “ghost template” with metal salts that dissolve.

이인수교수팀(en)_뷰페이지A POSTECH research team led by Professor In Su Lee, Research Professor Nitee Kumari and Ph.D. candidate Jeong Hun Choi (Department of Chemistry) has developed a new synthesis procedure for hollow silica nanostructures using metal salts to dissolve the template. These findings were recently published in the international academic journal Nano Letters. The metal salt is a metal compound that is formed as a result of neutralization, and the common table salt is one of them.

220316_[그림1] POSTECH 이인수 교수 연구 관련 그림_영문01
Hollow octahedral nanostructures have wide applicability since materials freely flow through and easily combine with other materials. These structures had to be synthesized into a template and the template had to be removed again.

220316_[그림2] POSTECH 이인수 교수 연구 관련 그림_영문01
Taking a hint from metal salts that dissolve and disappear depending on the acidity of the solution, the researchers developed a simple synthetic method of making a template with metal salt and dissolving it. With this new method, hollow nanostructures, as well as unconventional nanostructures like polygonal or spherical structures, can be synthesized by controlling the reaction rate of the silica precursor.*1

220316_[그림3] POSTECH 이인수 교수 연구 관련 그림_영문01
The researchers also confirmed that these hollow nanostructures can assemble into a large octahedral structure through self-assembly. The hollow interior is a porous material in which chemical reactions occur actively and can be applicable in catalysis, gas storage, and others

Professor In Su Lee explained, “The hollow nanostructures synthesized with this new method use the biocompatible silica and have the structural advantage of hollow interior space and large surface area, making it highly applicable as a catalyst or drug delivery device.”

This study was conducted with the support of the Leader Researcher Program of the National Research Foundation of Korea.


1. Precursor
A substance in a stage before becoming the final substance from a certain metabolic or chemical reaction.