TY - JOUR
T1 - Improving the hydrostability of zeolitic imidazolate framework coatings using a facile silk fibroin protein modification method
AU - Wei, Xiuming
AU - Chen, Ting
AU - Chen, Siyu
AU - Jia, Qian
AU - Mazlan, Nurul Ain
AU - Lewis, Allana
AU - Radacsi, Norbert
AU - Huang, Yi
N1 - This work was supported by start-up funding from the School of Engineering, at the University of Edinburgh. X. M. W. thanks the University of Edinburgh for Principal\u2019s Career Development Ph.D. Scholarships and the School of Engineering for Edinburgh Global Research Scholarship. The authors would like to thank Fergus Dingwall for his laboratory assistance.
PY - 2024/7
Y1 - 2024/7
N2 - Zeolitic imidazolate frameworks (ZIFs) are an important subclass of
metal-organic frameworks (MOFs) with zeolite-type topology, which can be
fabricated under ambient synthesis conditions. However, the
applications of ZIFs are commonly limited due to the weak hydrostability
of their metal–ligand coordination bonds, particularly under humid and
aqueous conditions. In this work, as an example, the hydrolysis
behaviours of ZIF-L with a special focus on ZIF-L coatings were tested
at aqueous conditions with a wide range of pHs to systematically study
and fundamentally understand their structural stability and degradation
mechanism. Pristine ZIF-L powder and ZIF-L coatings were severely
damaged after only 24 h in aqueous media. Interestingly, the ZIF-L
coatings showed two distinct hydrolyzation pathways regardless of pH
conditions, exhibiting either a ring-shaped etching or unfolding
behaviours. While the ZIF-L powders were hydrolyzed almost identically
across all pH conditions. With this new understanding, a facile silk
fibroin (SF) protein modification method was developed to enhance the
hydrostability of ZIF-L coatings in aqueous media. The effect of protein
concentration on surface coating was systemically studied. ZIF-L
coating retained its surface morphology after soaking in water and
demonstrated switchable super wetting properties and superior separation
performance for oil/water mixture. As a result, the quick SF protein
modification significantly enhanced the stability of ZIF-L coatings
under various pHs, while retaining their switchable wetting property and
excellent separation performance.
AB - Zeolitic imidazolate frameworks (ZIFs) are an important subclass of
metal-organic frameworks (MOFs) with zeolite-type topology, which can be
fabricated under ambient synthesis conditions. However, the
applications of ZIFs are commonly limited due to the weak hydrostability
of their metal–ligand coordination bonds, particularly under humid and
aqueous conditions. In this work, as an example, the hydrolysis
behaviours of ZIF-L with a special focus on ZIF-L coatings were tested
at aqueous conditions with a wide range of pHs to systematically study
and fundamentally understand their structural stability and degradation
mechanism. Pristine ZIF-L powder and ZIF-L coatings were severely
damaged after only 24 h in aqueous media. Interestingly, the ZIF-L
coatings showed two distinct hydrolyzation pathways regardless of pH
conditions, exhibiting either a ring-shaped etching or unfolding
behaviours. While the ZIF-L powders were hydrolyzed almost identically
across all pH conditions. With this new understanding, a facile silk
fibroin (SF) protein modification method was developed to enhance the
hydrostability of ZIF-L coatings in aqueous media. The effect of protein
concentration on surface coating was systemically studied. ZIF-L
coating retained its surface morphology after soaking in water and
demonstrated switchable super wetting properties and superior separation
performance for oil/water mixture. As a result, the quick SF protein
modification significantly enhanced the stability of ZIF-L coatings
under various pHs, while retaining their switchable wetting property and
excellent separation performance.
KW - hydrostability enhancement
KW - oil/water separation
KW - silk fibroin protein
KW - zeolitic imidazole framework-L (ZIF-L)
KW - ZIF-L coatings
UR - http://www.scopus.com/inward/record.url?scp=85190385249&partnerID=8YFLogxK
U2 - 10.1007/s12274-024-6586-5
DO - 10.1007/s12274-024-6586-5
M3 - Article
AN - SCOPUS:85190385249
SN - 1998-0124
VL - 17
SP - 6247
EP - 6257
JO - Nano Research
JF - Nano Research
IS - 7
ER -