Quantum scale biomimicry of low dimensional growth : an unusual complex amorphous precursor route to TiO2 band confinement by shape adaptive biopolymer-like flexibility for energy applications
Crystallization via an amorphous pathway is often preferred by biologically driven processes enabling living species to better regulate activation energies to crystal formation that are intrinsically linked to shape and size of dynamically evolving morphologies. Templated ordering of 3-dimensional s...
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sg-ntu-dr.10356-1426152023-02-28T17:07:51Z Quantum scale biomimicry of low dimensional growth : an unusual complex amorphous precursor route to TiO2 band confinement by shape adaptive biopolymer-like flexibility for energy applications Choi, Dahyun Sonkaria, Sanjiv Fox, Stephen John Poudel, Shivraj Kim, Sung-yong Kang, Suhee Kim, Seheon Verma, Chandra Ahn, Sung Hoon Lee, Caroline Sunyong Khare, Varsha School of Biological Sciences Bioinformatics Institute, A*STAR Science::Biological sciences Biomimicry TiO2 Crystallization via an amorphous pathway is often preferred by biologically driven processes enabling living species to better regulate activation energies to crystal formation that are intrinsically linked to shape and size of dynamically evolving morphologies. Templated ordering of 3-dimensional space around amorphous embedded non-equilibrium phases at heterogeneous polymer─metal interfaces signify important routes for the genesis of low-dimensional materials under stress-induced polymer confinement. We report the surface induced catalytic loss of P=O ligands to bond activated aromatization of C-C C=C and Ti=N resulting in confinement of porphyrin-TiO2 within polymer nanocages via particle attachment. Restricted growth nucleation of TiO2 to the quantum scale (≤2 nm) is synthetically assisted by nitrogen, phosphine and hydrocarbon polymer chemistry via self-assembly. Here, the amorphous arrest phase of TiO2 is reminiscent of biogenic amorphous crystal growth patterns and polymer coordination has both a chemical and biomimetic significance arising from quantum scale confinement which is atomically challenging. The relative ease in adaptability of non-equilibrium phases renders host structures more shape compliant to congruent guests increasing the possibility of geometrical confinement. Here, we provide evidence for synthetic biomimicry akin to bio-polymerization mechanisms to steer disorder-to-order transitions via solvent plasticization-like behaviour. This challenges the rationale of quantum driven confinement processes by conventional processes. Further, we show the change in optoelectronic properties under quantum confinement is intrinsically related to size that affects their optical absorption band energy range in DSSC. NRF (Natl Research Foundation, S’pore) ASTAR (Agency for Sci., Tech. and Research, S’pore) EDB (Economic Devt. Board, S’pore) Published version 2020-06-25T08:11:29Z 2020-06-25T08:11:29Z 2019 Journal Article Choi, D., Sonkaria, S., Fox, S. J., Poudel, S., Kim, S., Kang, S., . . . Khare, V. (2019). Quantum scale biomimicry of low dimensional growth : an unusual complex amorphous precursor route to TiO2 band confinement by shape adaptive biopolymer-like flexibility for energy applications. Scientific Reports, 9(1), 18721-. doi:10.1038/s41598-019-55103-z 2045-2322 https://hdl.handle.net/10356/142615 10.1038/s41598-019-55103-z 31822722 2-s2.0-85076413240 1 9 en Scientific Reports © 2019 The Author(s). This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. Te images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/. application/pdf |
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Science::Biological sciences Biomimicry TiO2 Choi, Dahyun Sonkaria, Sanjiv Fox, Stephen John Poudel, Shivraj Kim, Sung-yong Kang, Suhee Kim, Seheon Verma, Chandra Ahn, Sung Hoon Lee, Caroline Sunyong Khare, Varsha Quantum scale biomimicry of low dimensional growth : an unusual complex amorphous precursor route to TiO2 band confinement by shape adaptive biopolymer-like flexibility for energy applications |
| description |
Crystallization via an amorphous pathway is often preferred by biologically driven processes enabling living species to better regulate activation energies to crystal formation that are intrinsically linked to shape and size of dynamically evolving morphologies. Templated ordering of 3-dimensional space around amorphous embedded non-equilibrium phases at heterogeneous polymer─metal interfaces signify important routes for the genesis of low-dimensional materials under stress-induced polymer confinement. We report the surface induced catalytic loss of P=O ligands to bond activated aromatization of C-C C=C and Ti=N resulting in confinement of porphyrin-TiO2 within polymer nanocages via particle attachment. Restricted growth nucleation of TiO2 to the quantum scale (≤2 nm) is synthetically assisted by nitrogen, phosphine and hydrocarbon polymer chemistry via self-assembly. Here, the amorphous arrest phase of TiO2 is reminiscent of biogenic amorphous crystal growth patterns and polymer coordination has both a chemical and biomimetic significance arising from quantum scale confinement which is atomically challenging. The relative ease in adaptability of non-equilibrium phases renders host structures more shape compliant to congruent guests increasing the possibility of geometrical confinement. Here, we provide evidence for synthetic biomimicry akin to bio-polymerization mechanisms to steer disorder-to-order transitions via solvent plasticization-like behaviour. This challenges the rationale of quantum driven confinement processes by conventional processes. Further, we show the change in optoelectronic properties under quantum confinement is intrinsically related to size that affects their optical absorption band energy range in DSSC. |
| author2 |
School of Biological Sciences |
| author_facet |
School of Biological Sciences Choi, Dahyun Sonkaria, Sanjiv Fox, Stephen John Poudel, Shivraj Kim, Sung-yong Kang, Suhee Kim, Seheon Verma, Chandra Ahn, Sung Hoon Lee, Caroline Sunyong Khare, Varsha |
| format |
Article |
| author |
Choi, Dahyun Sonkaria, Sanjiv Fox, Stephen John Poudel, Shivraj Kim, Sung-yong Kang, Suhee Kim, Seheon Verma, Chandra Ahn, Sung Hoon Lee, Caroline Sunyong Khare, Varsha |
| author_sort |
Choi, Dahyun |
| title |
Quantum scale biomimicry of low dimensional growth : an unusual complex amorphous precursor route to TiO2 band confinement by shape adaptive biopolymer-like flexibility for energy applications |
| title_short |
Quantum scale biomimicry of low dimensional growth : an unusual complex amorphous precursor route to TiO2 band confinement by shape adaptive biopolymer-like flexibility for energy applications |
| title_full |
Quantum scale biomimicry of low dimensional growth : an unusual complex amorphous precursor route to TiO2 band confinement by shape adaptive biopolymer-like flexibility for energy applications |
| title_fullStr |
Quantum scale biomimicry of low dimensional growth : an unusual complex amorphous precursor route to TiO2 band confinement by shape adaptive biopolymer-like flexibility for energy applications |
| title_full_unstemmed |
Quantum scale biomimicry of low dimensional growth : an unusual complex amorphous precursor route to TiO2 band confinement by shape adaptive biopolymer-like flexibility for energy applications |
| title_sort |
quantum scale biomimicry of low dimensional growth : an unusual complex amorphous precursor route to tio2 band confinement by shape adaptive biopolymer-like flexibility for energy applications |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/142615 |
| _version_ |
1759858188736266240 |