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@ARTICLE{Radovsky:201766,
author = {Radovsky, Gal and Popovitz-Biro, Ronit and Stroppa, Daniel
G. and Houben, Lothar and Tenne, Reshef},
title = {{N}anotubes from {C}halcogenide {M}isfit {C}ompounds:
{S}n–{S} and {N}b–{P}b–{S}},
journal = {Accounts of chemical research},
volume = {47},
number = {2},
issn = {1520-4898},
address = {Columbus, Ohio},
publisher = {American Chemical Soc.},
reportid = {FZJ-2015-04060},
pages = {406 - 416},
year = {2014},
abstract = {Carbon fullerenes and nanotubes revolutionized
understandingof the reactivity of nanoscale compounds.
Subsequently, our group and others discovered analogous
inorganic compounds with hollow, closed nanostructures. Such
inorganic nanostructures offer many applications,
particularly in the energy and electronics industries.One
way to create inorganic nanostructures is via misfit
layer-ed compounds (MLC), which are stacks of alternating
two-dimensional molecular slabs, typically held together via
weak van der Waals forces. They contain “misfits” in
their a–b plane structures that can make them unstable,
leading to collapse of the slabs into tubular
nanostructures. For example, metal chalcogenide MLCs of the
general formula (MX)1+y/TX2 (M = Sn, Pb, Bi, Sb, and other
rare earths; T = Sn, Ti, V, Cr, Nb, Ta, etc.; X = S or Se)
consist of a superstructure of alternating layers where the
MX unit belongs to a (distorted NaCl) orthorhombic symmetry
group (O), the TX2 layer possesses trigonal (T) or
octahedral symmetry, and the two layers are held together
via both van der Waals and polar forces. A misfit in the a
axis or both a and b axes of the two sublattices may lead to
the formation of nanostructures as the lattices relax via
scrolling. Previous research has also shown that the
abundance of atoms with dangling bonds in the rims makes
nanoparticles of compounds with layered structure unstable
in the planar form, and they tend to fold into hollow closed
structures such as nanotubes.This Account shows that
combining these two triggers, misfits and dangling bond
annihilation in the slab rims, leads to new kinds of
nanotubes from MLCs. In particular, we report the structure
of two new types of nanotubes from misfits, namely, the
SnS/SnS2 and PbS/NbS2 series. To decipher the complex
structures of these nanotubes, we use a range of methods:
high-resolution transmission electron microscopy (HRTEM),
energy-dispersive X-ray spectroscopy (EDS), selected area
electron diffraction (SAED) analyses, scanning electron
microscopy (SEM), and Cs-corrected scanning transmission
electron microscopy (STEM) in the high-angle annular
dark-field mode (HAADF). In both new types, the lattice
mismatch between the two alternating sublayers dictates the
relative layer-stacking order and leads to a variety of
chiral tubular structures. In particular, the
incommensuration (a type of misfit) of the SnS2/SnS system
in both the (in plane) a and b directions leads to a variety
of relative in-plane orientation and stacking orders along
the common c-axis. Thus the SnS/SnS2 nanotubes form
superstructures with the sequence O–T and O–T–T, and
mixtures thereof. We also report nanotubes of the misfit
layered compound (PbS)1.14NbS2, and of NbS2 intercalated
with Pb atoms, with the chemical formula PbNbS2. Thus, the
possibility to use two kinds of folding mechanisms jointly
offers a new apparatus for the synthesis of unique 1-D
nanostructures of great complexity and a potentially large
diversity of physicochemical properties.},
cin = {PGI-5},
ddc = {540},
cid = {I:(DE-Juel1)PGI-5-20110106},
pnm = {42G - Peter Grünberg-Centre (PG-C) (POF2-42G41)},
pid = {G:(DE-HGF)POF2-42G41},
typ = {PUB:(DE-HGF)16},
UT = {WOS:000331775200012},
doi = {10.1021/ar400138h},
url = {https://juser.fz-juelich.de/record/201766},
}
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