Published October 15, 2022 | Version 1.0
Dataset Open

Zeolite Templated Carbon Materials - DFTB Structural Database

  • 1. The University of British Columbia - Okanagan
  • 1. Montana State University
  • 2. ORNL
  • 3. Tohoku University

Description

Zeolite-templated carbon (ZTC) is a unique porous carbonaceous material in that its structure is ordered at the nanometre scale, enabling a representative periodic description at the atomistic level. A structural library for ZTC of varying compositions was created  using density functional tight binding (DFTB) potentials parameterized for materials science applications (matsci-0-3). We provide here  quantum chemical-refined structures of models with CH, CHO, CHON, CHOB, and CHOBN compositions with various degrees of heteroatom substitution. The "initial ZTC structure" files correspond to the initial model used in our work that was developed using molecular mechanics, empirical force fields. These structural models comprise the characteristic morphological features of highly porous carbon materials, such as open-blade surfaces, edges, saddles, and closed-strut formations, spanning a range of curvatures and characteristic sizes. The optimized structures in CIF and native DFTB file formats are organized in the "stationary structure" file based on the optimization pathways that lead to the stationary structures.

Secondly, we carried out alternating compression and expansion of the CHO model unit cell to determine the lowest energy structure as well as to obtain the bulk modulus. The file "bulk modulus" contains two data sets that describe the deformational energy landscape of pure faujasite zeolite, Na-substituted zeolite, and the ZTC model structure.

The file "analysis tools" is a representative compilation of utilities for file format conversion, fractional vs. Cartesian crystal coordinates, and structural analysis spreadsheets.

The agreement between experimental measurements and the computational model is remarkable that demonstrates the power of approximate density functional theory as a cost-effective computational tool with chemical accuracy for the investigation of structure/property relationships in real-world carbon-based solids.

Notes

Szilagyi* R.K., Stadie N.P., Irle S., Nishihara H.: Mechanical Properties of Zeolite-Templated Carbons from Approximate Density Functional Theory Calculations Carbon Reports, 2022, 1(4), 231-240 (Thematic Issue: Atomic Design of Carbon Materials)  DOI: 10.7209/carbon.010407
also reported in Carbon (meeting abstract), 2023, 203, 896 DOI: 10.1016/j.carbon.2022.11.066

Files

initial ZTC structure.png

Files (653.7 MB)

Name Size Download all
md5:34f715f8633966619c76347a85a0ce76
18.9 MB Preview Download
md5:b3a4b7877e4fca7b397f35e36d1dc9ac
403.9 MB Preview Download
md5:e9e0121d505982947cd86cf04aaea11f
40.6 kB Preview Download
md5:d66bce6e8cd9c1c07590327ba3dae314
7.3 kB Download
md5:b156ecfe81bf629220448c5c75d2c6ca
13.8 MB Download
md5:de6273878b8b38762fc692bf7bb38532
347.9 kB Download
md5:61841591124ffbb0e6cac3290c3190eb
10.4 MB Preview Download
md5:830c6d0e173c6c69c348aeaae114ef97
527.4 kB Preview Download
md5:202713259f3c6c27e0f7eda9e651851e
205.8 MB Preview Download

Additional details

Related works

Is published in
Publication: 10.7209/carbon.010407 (DOI)

References

  • DOI: 10.7209/carbon.010407