German Edition: DOI: 10.1002/ange.201905724Supramolecular Polymers
International Edition: DOI: 10.1002/anie.201905724

Revising Complex Supramolecular Polymerization
under Kinetic and Thermodynamic Control
Jonas Matern, Yeray Dorca, Luis S#nchez,* and Gustavo Fern#ndez*

Angewandte
Chemie

Keywords:
hierarchy ·
out-of-equilibrium systems ·
pathway complexity ·
self-assembly ·
supramolecular
polymers

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http://dx.doi.org/10.1002/ange.201905724
http://dx.doi.org/10.1002/anie.201905724
http://orcid.org/0000-0001-7586-1444
http://orcid.org/0000-0001-7586-1444
http://orcid.org/0000-0001-7867-8522
http://orcid.org/0000-0001-7867-8522
http://orcid.org/0000-0001-6155-8671


1. General Aspects of Supramolecular
Polymerization

Inspired by the complexity and functionality of supra-
molecular systems in nature,[1] supramolecular polymers have
emerged as promising smart nanomaterials with multiple
potential applications ranging from optoelectronics to life
sciences.[2] In contrast to classical polymers, the presence of
reversible noncovalent interactions[3–5] provides access to
outstanding functionalities, such as responsiveness to subtle
stimuli or self-healing.[6] Supramolecular polymerization (SP)
can be classified according to three different growth mech-
anisms into ring-chain, isodesmic, and cooperative polymer-
ization, as previously reported in various excellent re-
views.[3, 4, 7, 8] Whereas ring-chain polymerization is limited to
ditopic monomers, most examples of supramolecular poly-
mers are described by either the (anti-)cooperative or
isodesmic mechanisms.

The isodesmic or “equal K” model is characterized by an
invariant value of the equilibrium constant of each association
step during the monomer-to-aggregate transformation.[4, 9]

Cooperative (or “nucleated”) SP occurs in two stages: initially
a nucleus is formed with an association constant Kn, followed
by an elongation process described by a new association
constant Ke.

[10] As a result of these two stages in cooperative
SP, a critical concentration, temperature, or solvent compo-
sition has to be surpassed to initiate elongation. Both
isodesmic and cooperative models have been used extensively
to describe the SP of multiple compounds into a single,
thermodynamically controlled aggregate.[7, 8, 11] However, self-
assembled systems, particularly those governed by a cooper-
ative mechanism, often exist as more than one single
structure, which suggests that kinetic contributions should
also be considered when analyzing self-assembly process-
es.[12–14] Thus, the parameter time also contributes drastically
to the final outcome of the corresponding SP. Herein, we aim
to classify, summarize, and relate existing concepts to
promote a uniform terminology that is suitable to be
generalized for all types of advanced supramolecular poly-

mers. An in-depth comprehension of
these terms and concepts should con-
tribute to developing increasingly
more advanced functional materials.

2. Competition of Thermody-
namics versus Kinetics in SP

2.1. Early Manifestations of Multiple
Aggregates from the Same Building
Block

The existence of more than one
final outcome in the self-assembly of
a single molecule was a previously
known phenomenon for various p-
systems. As early as 1995, Boumann
and Meijer reported on the stereomu-
tation of thin films of a polythiophene

derivative upon variation of the cooling rate.[15] Fast cooling
yielded CD spectra with an opposite dichroic response
compared to the slowly cooled samples. This stereomutation
was attributed to the formation of kinetic structures (fast
cooling) with opposite handedness to those formed under
thermodynamic control (slow cooling).

In 2005, Ryu and Lee described the self-assembly of
a bolaamphipilic molecule 1 (Figure 1).[16] In this work, the
reversible aqueous coassembly of cylindrical structures of
1 and a complementary rod-coil-rod molecule was analyzed.
Strikingly, the desired cylindrical micelles of 1 were not
obtained directly upon SP, but instead spherical micelles were
formed. However, over a period of four weeks, the micellar
kinetic assemblies transformed into the thermodynamically
stable cylindrical architectures, as evidenced by dynamic light
scattering (DLS) and transmission electron microscopy
(TEM, Figure 1b,c).

More recently, Rybtchinski and co-workers reported the
amphiphilic PtII complex 2 that self-assembles into three
different aggregates depending on the selected percentages of
water and THF (Figure 2).[17] At high water contents (95:5),

Pathway complexity, hierarchical organization, out of equilibrium,
and metastable or kinetically trapped species are common terms
widely used in recent, high-quality publications in the field of supra-
molecular polymers. Often, the terminologies used to describe the
different self-assembly pathways, the species involved, as well as their
relationship and relative stability are not trivial. Different terms and
classifications are commonly found in the literature, however, in many
cases, without clear definitions or guidelines on how to use them and
how to determine them experimentally. The aim of this Minireview is
to classify, differentiate, and correlate the existing concepts with the
help of recent literature reports to provide the reader with a general
insight into thermodynamic and kinetic aspects of complex supra-
molecular polymerization processes. A good comprehension of these
terms and concepts should contribute to the development of new
complex, functional materials.

[*] J. Matern, Prof. Dr. G. Fern#ndez
Organisch-Chemisches Institut
Westf-lische Wilhelms-Universit-t Mfnster
Corrensstrasse 40, 48149 Mfnster (Germany)
E-mail: fernandg@uni-muenster.de

Y. Dorca, Prof. Dr. L. S#nchez
Departamento de Qu&mica Org#nica
Facultad de Ciencias Qu&micas
Universidad Complutense de Madrid
28040 Madrid (Spain)
E-mail: lusamar@quim.ucm.es

The ORCID identification number for some of the authors of this
article can be found under: https://doi.org/10.1002/anie.201905724.

T 2019 The Authors. Published by Wiley-VCH Verlag GmbH & Co.
KGaA. This is an open access article under the terms of the Creative
Commons Attribution Non-Commercial License, which permits use,
distribution and reproduction in any medium, provided the original
work is properly cited and is not used for commercial purposes.

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cryo-TEM revealed highly curved, fibrous assemblies with
a weak CD response that does not change over time (Figure 2,
pathway 1). Increasing the THF percentage to 20% induces
a marked CD signal that originates from helical, fibrous
structures (pathway 2). Another distinct CD pattern corre-
sponding to tightly packed, straight nanofibers was obtained
in 70:30 water/THF mixtures after 70 h (pathway 3). The
authors concluded that the aggregates formed at a high water
content are kinetic species that are unable to convert into the
thermodynamic structure because of strong hydrophobic
interactions. In contrast, assemblies prepared in 80:20 or

70:30 mixtures can equilibrate to the thermodynamic product.
Interestingly, depending on the preparation method, all three
structures could be isolated under equal final conditions (95:5
water/THF, c = 1x10@4, RT).

This “pathway-dependent” self-assembly, as denoted by
the authors, marked a milestone in exploiting kinetic control
to tune the outcome of SP.

2.2. The Concept of Pathway Complexity

Although the insufficiency of a mere thermodynamic
assessment had been recognized for more than a decade, it
was not until 2012 that Meijer and co-workers systematically
unraveled the competition between kinetics and thermody-

Jonas Matern received his B.Sc. and M.Sc.
from the Ruprecht-Karls-Universit-t Heidel-
berg (2016) and Westf-lische-Wilhelms Uni-
versit-t Mfnster (WWU, 2018), respectively.
He is currently working in the group of Prof.
Gustavo Fern#ndez at the WWU. His work
focuses on the systematic study of the
factors governing supramolecular
polymerization in metal-containing systems.

Yeray Dorca obtained his B.Sc. in Chemistry
(2015) and his M.Sc. in Organic Chemistry
(2016) at the Universidad Complutense de
Madrid (UCM). He joined the group of
Prof. Luis S#nchez as a PhD student, work-
ing on the self-assembly of nonplanar
aromatic molecules.

Luis S#nchez has been professor of Organic
Chemistry since 2002 and leads the
“Supramolecular Polymers” group at the
Universidad Complutense de Madrid. His
research interests focus on realizing new
supramolecular polymers, especially helical
aggregates, to develop functional materials.

Gustavo Fern#ndez has been professor of
Organic and Supramolecular Chemistry at
the WWU (Mfnster) since 2015, where he
heads a research group working on self-
assembled p-systems. His research focuses
on understanding the mechanistic aspects
involved in the supramolecular
polymerization of functional, metal-contain-
ing and BODIPY-based systems.

Figure 1. a) Chemical structure of amphiphile 1. b) Time-dependent
DLS measurement showing the transformation of initially formed
spherical micelles into cylindrical micelles. c) TEM image of an aged
solution showing cylindrical micelles. Adapted from Ref. [16] with
permission. Copyright 2005 American Chemical Society.

Figure 2. Chemical structure of amphiphilic PtII complex 2 and its
pathway-dependent self-assembly. Adapted from Ref. [17] with permis-
sion. Copyright 2011 Wiley-VCH.

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namics in SP. Following their seminal work on the nucleated
SP of a chiral oligophenylene vinylene (OPV) derivative 3,[18]

the authors examined the existence of competing pathways. In
particular, new kinetic experiments and calculations were
introduced to shed light onto the interplay between thermo-
dynamic and kinetic pathways, in terms of the influence of
concentration, temperature, and solvent composition.[19,20]

(S)-Chiral OPV 3 self-assembles into thermodynamically
stable, M-type helices upon slow cooling (1 K min@1) from the
molecularly dissolved state. In contrast, a fast temperature
drop to 273 K leads to a mixture of M-type and kinetically
favored P-type helices. Stopped-flow CD experiments, in
which a chloroform solution of 3 was injected into a large
volume of a poor solvent (methylcyclohexane, MCH),
revealed an initial formation of the kinetic P-type aggregates
at high concentrations (Figure 3b). The appearance of this
“off-pathway” assembly caused an increase in the time
required to assemble 50 % of the monomers (lag time, t50)
upon increasing the concentration. This behavior could be
explained by assuming that the P- to M-helix transition occurs
through a disassembly into the monomer (Figure 3c).

Hence, the formation of the kinetic polymers sequesters
the monomers, thus lowering the concentration of free
monomers able to engage in the thermodynamic pathway
and decelerating the formation of the M-helix. Simulations
could correlate these findings to a slightly more stable nucleus
for the P-helix, whereas the M-helix is more stable in the
elongation regime. Based on these findings, the authors
introduced the term pathway complexity, which was already
used for proteins, to describe the appearance of different
aggregation pathways that are in competition for the mono-
mer.[21]

Subsequent to this pioneering work, the focus in SP
shifted from a pure thermodynamic view towards increasing
attention to kinetic aspects. Pathway complexity has in the
meanwhile become a frequently used term in systems
exhibiting more than a simple monomer to aggregate trans-
formation.

2.3. Concepts Used To Describe Thermodynamic and Kinetic
Aspects of Complex SP

The increasingly detailed investigations on pathway com-
plexity phenomena prompted the emergence of a multitude
of concepts and terminologies to describe the SP processes
and species. Some of these concepts/classifications have been
used interchangeably in the literature, which makes a clear
differentiation between particular subsets difficult. In the
following, we provide our understanding of the concepts
commonly used to describe complex SP phenomena. In
particular, we aim to classify, summarize, relate, and expand
existing concepts to promote a uniform terminology that can
be generalized for all types of advanced SP systems. The
concepts illustrated in Figure 4 will be addressed in a general
manner in this section with the help of representative
examples from the literature. In particular, energy landscapes
under a given set of conditions (i.e. concentration, temper-
ature, solvent composition) will be used to distinguish the
different self-assembled structures encountered in a system.

2.3.1. Dissipative versus Non-dissipative

When considering the self-assembly of a monomer (M)
into ordered nanostructures (i.e. moving along the energy
landscape of the system), the species that are stable on an
experimentally observable time scale represent minima of the
respective potential energy curve. Thus, their instantaneous
transformation into a lower-energy species is retarded by
a non-negligible activation barrier. These states are called
non-dissipative states (states A and B in Figure 4a).[22]

Dissipative or transient states, in contrast, (T in Figure 4 a)
have a very low or no activation barrier to hinder a further
descent in the energy landscape.[23] Therefore, the continuous
input of energy of some kind (i.e. a fuel) is required to prevent
relaxation into the next energy minimum.[24] The correspond-
ing far-from-equilibrium structures degrade when the fuel
supply is stopped. At this point, we refer the reader to
a handful of excellent reports on dissipative systems,[23, 25] as
this Minireview will focus on non-dissipative systems.

2.3.2. Equilibrium versus Non-equilibrium

The thermodynamic equilibrium is represented by the
global energy minimum of the energy landscape (B in
Figure 4a). A system in this condition may still be dynamic,
with monomers continuously equilibrating between solution
and aggregates, but the overall system does not change over
time. As the energy landscape is dependent on parameters
such as concentration, temperature, and solvent composition,
the equilibrium species may vary for a different set of

Figure 3. a) Chemical structure of 3. b) Plots of CD signal versus time
in stopped-flow kinetic experiments. c) Schematic illustration of the
competitive aggregation pathways of 3. Adapted from Ref. [20] with
permission. Copyright 2012 Springer Nature.

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conditions. However, the way in which it is reached has no
influence on the final equilibrium structure.[24, 26] Any other
species different from the thermodynamically stable one is
a kinetic, non-equilibrium structure. Recent advances in the
field have shown that time is a key parameter that must be
considered when assessing the equilibrium versus non-equi-
librium nature of different states. Kinetic, non-equilibrium
structures are prone to spontaneously convert into the
equilibrium state over time or by application of some kind
of stimulus that aids in overcoming the activation barrier to
ease into the global minimum.

2.3.3. Metastable versus Kinetically Trapped

The magnitude of this activation barrier can give rise to
a differentiation of kinetic species into either metastable or
kinetically trapped species.[22] Energy barriers that can be
overcome at room temperature (i.e. no greater than kBT) exist
for metastable structures. These structures transform to more
stable species within an experimentally observable time scale,
which often ranges from minutes to several months. Kineti-
cally trapped states, in contrast, reside in a local energy
minimum if not pushed over the energy barrier by some
external stimulus.[24] Nevertheless, the lack of explicit exper-
imental means to differentiate the two states has resulted in
these two terms having been used interchangeably in the
literature. However, for the assessment of the properties of
a SP system, the exact categorization of each kinetic species as
either metastable or kinetically trapped is not necessary, in
our opinion. The most crucial characteristic for controlling SP
through kinetic species, namely retardation of the sponta-
neous self-assembly of the thermodynamic polymer, is
guaranteed in both cases.

2.3.4. On- versus Off-Pathway Species, Consecutive and Competitive
Pathways

The occurrence of multiple pathways in SP prompted the
use of the terms “on-pathway” and “off-pathway” aggregates.
In many cases, the terms are used as synonyms for thermody-
namic and kinetic species, respectively. However, there are
examples of on- and off-pathway aggregates that cannot be
accurately described by this simple definition.[27] More

precisely, the terms refer to the final outcome of an individual
branch of an energy landscape. This becomes apparent when
inspecting the archetypal energy landscape of a more complex
system (Figure 4d).

Along the kinetic pathway, A is an on-pathway aggregate
towards species D. On the other hand, A is an off-pathway
aggregate with respect to thermodynamic species B. Thus, it is
crucial to define the state of reference when using the
expressions on- and off-pathway.

In this context, even though the terms sequential and
parallel have been referred to in the literature,[28] we suggest
the terms “consecutive” and “competitive” as a more intuitive
designation to describe the relationship of the individual
pathways (Figures 4b,c). Species or pathways that can only be
transformed into each other through disassembly into the
monomer are competitive (Figure 4b). When a species con-
verts into another one directly, for example, by means of
structural rearrangements or formation of higher ordered
architectures (e.g. clustering), then the pathway is consecutive
(Figure 4c). In the case of the most simple, three-state energy
landscape (Figures 4b,c), the classification of off- and on-
pathway for state A with respect to thermodynamic species B
coincides with the competitive/consecutive characterization
of the pathways.[28]

The key experiment to distinguish the two cases is the
time-dependent interconversion between the respective poly-
meric species at different concentrations. If the transforma-
tion is accelerated upon increasing the concentration, that is,
the time required for the transition to be completed (lag time)
is shorter, a consecutive pathway occurs. On the other hand, if
the lag time increases with increasing concentration, com-
petitive pathways exist, as the less-stable species has to be
transformed into free, aggregation-active monomers prior to
assembly into the more stable aggregate. Other distinctive
features of competitive and consecutive systems will be
mentioned in the following section by describing selected
examples from the literature.

2.3.5. Hierarchy

The concept of hierarchy was derived from protein
folding, which proceeds in a series of successive steps, that
is, hierarchical levels (primary to quaternary structure).[29] A

Figure 4. Energy landscapes illustrating the different concepts for pathway/aggregate characterization: a) dissipative versus non-dissipative and
equilibrium versus non-equilibrium states; b) competitive pathways; c) consecutive pathways; d) system of higher complexity with a hierarchical
kinetic pathway and the possibility of living SP by a seeded-growth approach.

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hierarchical process is defined by consecutive assembly levels,
where a more advanced macroscopic organization is added at
each stage, while keeping the substructure motifs of the
precedent levels. In most cases, a correlation between the
hierarchical level and the forces governing its structure exists.
The stronger interactions dictate the formation of the first
aggregation step, while the strength of these forces diminishes
when approaching the lowest energy state. Usually, a hier-
archical SP is directly related to a consecutive pathway.

2.3.6. Living/Seeded Supramolecular Polymerization

Inspired by the work on crystallization-driven self-assem-
bly by Manners and co-workers,[30] and in analogy to classical
chain-growth polymerization, living supramolecular polymer-
ization (LSP) has been exploited as a tool to control the
length and polydispersity in SP. This approach takes advant-
age of kinetic species, which serve as a monomer reservoir.
The metastable or kinetically trapped species are transformed
to aggregates of lower energy when certain stimuli are applied
to the inactive species (Figure 4 d). A prerequisite for LSP is
the retardation of the spontaneous self-assembly of the
thermodynamically favored species.[31] The terms living and
seeded SP are often used interchangeably in the current
literature. Our view on this subject is that the most
appropriate terminology would be “LSP by seeded growth”
or “seed-mediated LSP”, as the seeds are the specific stimuli
that initiate SP with living character. LSP has also been
achieved by an initiator molecule-induced approach by the
group of Aida,[32] as will be outlined in Section 2.5.

Before moving on to illustrate these concepts using
selected literature examples, it should be mentioned that
such phenomena are often combined or occur simultaneously.
For example, hierarchical levels can be encountered along
both the kinetic and thermodynamic pathways. This also
applies to metastable or kinetically trapped species (Fig-
ure 4d). Furthermore, those species could be inactive aggre-
gates or “dormant” monomers (e.g. through intramolecular
H-bonding[33–38]). In the following, we will systematically
move from purely consecutive to purely competitive systems
to finally show complex systems exhibiting several of the
aforementioned phenomena. For more detailed information
about the key experiments needed to identify all the concepts
described in this section, the reader is referred to the original
manuscripts.

2.4. Consecutive Pathways

An archetypal example of a system exhibiting consecutive
pathways is the hierarchical supramolecular polymerization
of a series of merocyanine dyes reported by Wgrthner and co-
workers (Figure 5).[12, 14, 39] Initially, two dye units of 4 form
antiparallel dimer aggregates (D-aggregates) through dipolar
interactions and these aggregates organize into single fibrils
with a helical conformation. Six of the resulting helical fibrils
further grow into densely packed rods with the alkoxy chains
pointing outwards (H-aggregates). At higher concentrations,
gelation occurs as a result of inter-rod interdigitation of the

paraffinic side chains (Figures 5c–e). The stabilization of the
different hierarchical states by variation of the concentration
and solvent (i.e. change in the energy landscape) was
successfully exploited to isolate monomeric as well as D-
and H-aggregated species. In CH2Cl2, 4 is molecularly
dissolved with an absorption maximum at l = 570 nm, while
a sharp blue-shifted band, originating from highly organized
H-type aggregates, is evident in apolar MCH (Figure 5b). In
solvents of intermediate polarity, such as tetrachloroethane
(TCE), the previously mentioned and less hypsochromically
shifted D-band, is observed. In the appropriate solvent
combination (42:58 MCH/THF), full transition from mono-
mers to elongated H-aggregates via the formation of D-
aggregates was achieved by variation of the temperature, thus
indicating the consecutive, hierarchical nature of the self-
assembly. Additional proof of the hierarchical self-assembly
was achieved with chiral congeners of 4, where the D- to H-
aggregate transformation could be monitored over time by
CD spectroscopy.[12, 14]

Yagai and co-workers reported the hierarchical SP of a V-
shaped azobenzene-based photochromic system 5 (Fig-
ure 6).[40] Cooling monomer solutions of 5 in MCH leads to
a weak bisignate Cotton effect between 44 88C and 20 88C (inset
Figure 6b). These spectroscopic changes were attributed to
the formation of H-type nanotoroids driven by hydrogen
bonding, as confirmed by AFM (Figure 6c), TEM, and FTIR
spectroscopy. Further cooling causes the appearance of
several new, intense dichroic signals (Figure 6 b). This rever-
sible transition is ascribed to the subsequent organization of
the toroids into chiral nanotubes through p-stacking (Fig-
ure 6d). Ageing of the solution at 0 88C induces a subsequent
stacking and twisting into supercoiled fibrils that eventually
intertwine to form chiral double helices (Figure 6e).

Ajayaghosh and co-workers recently reported another
remarkable example of consecutive assemblies involving

Figure 5. a) Structure of merocyanine dye 4 and b) its solvent-depen-
dent UV/Vis spectra. Hierarchical self-assembly by dimerization and
subsequent growth into c) helical fibrils that d) form rods that e) ulti-
mately intertwine. Adapted from Ref. [39] with permission. Copyright
2003 Wiley-VCH.

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exceptional chiroptical transitions depending on the hierar-
chy level.[41] Oligophenylene-ethynylene (OPE) derivative 6
self-assembles into chiral helices whose handedness is in-
verted when they coil into superhelical structures (Figure 7).
Disassembly curves of superhelices, and their single-helix
precursors could prove the direct, consecutive interconver-
sion of the two species. The convergence of the temperature-
induced depolymerization curve of P-superhelices into the
one obtained for single M-helices under equal conditions
(n-decane, c = 5x10@5m) perfectly corroborated their hier-
archical relationship (Figure 7b).

The appearance of assembly or disassembly curves with
two or more transitions during variable-temperature (VT)
spectroscopic measurements has been observed in several
systems exhibiting consecutive pathways. In particular, exam-
ples of partially fluorinated benzenetricarboxamides[42] and
N-annulated perylenes[35, 37] show three regimes in the re-

spective VT-UV/Vis experiments that correspond to nuclea-
tion, elongation, and, finally, bundling into thicker aggregates.

2.5. Competitive Pathways

Competitive pathways occur when two or more self-
assembled structures compete for the monomer, that is,
interconversion is only possible by disassembly and subse-
quent reassembly into a different structure. One of the most
prominent examples of competitive pathways was the pre-
viously described (S)-OPV 3, which forms two species of
opposite helicity.[20]

In 2014, Ogi et al. reported the first example of LSP when
investigating a Zn porphyrin (ZnP) that self-assembles
through two competitive pathways (Figure 8).[43] Upon cool-

ing monomer solutions of 7 in MCH, nanoparticles with
a slipped J-type stacking were formed in an isodesmic fashion
(step 1 in Figures 8b,c). No thermal hysteresis, that is,
discrepancy between the cooling and heating curves in
a successive cycle of assembly and disassembly, could be
detected for this process. Such hysteresis is a distinct charac-
teristic of a competing species that sequesters free mono-
mers.[33–37] However, over the course of several days, the J-
aggregates transformed to H-type fibers (step 2). The lag time
(t50) for this transformation was found to increase with the
concentration of 7. This suggested that the transformation
proceeds via free monomer, thereby establishing the nano-
particles as off-pathway aggregates.

The cooperative mechanism governing the formation of
7H-agg was unveiled by monitoring the dissociation process
upon heating (step 4). Notably, the elongation temperature Te

Figure 6. a) Structure of photochromic unit 5 and b) corresponding
CD spectra recorded upon hierarchical SP into c) nanotoroids,
d) nanotubes, and e) eventually chiral single and double helices, as
observed by AFM. Adapted from Ref. [40] with permission. Copyright
2012 American Chemical Society.

Figure 7. a) Chemical structure of OPE 6 and c) its hierarchical self-
assembly. b) Temperature-induced disassembly curve of P-type super-
helices that converges with the curve obtained for M-type helices.
Adapted from Ref. [41] with permission. Copyright 2017 Wiley-VCH.

Figure 8. a) Chemical structure of 7 and b) its competitive J- versus H-
type aggregation. c) Cooling (pink) and heating (green) curves for the
two possible pathways. d) Four-cycle LSP through seeded growth from
J- to H-aggregates. Adapted from Ref. [43] with permission. Copyright
2014 Springer Nature.

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for 7H-agg in this experiment (heating!thermodynamic con-
trol) was higher than the value predicted by the cooperative
model without interference of the off-pathway aggregate
(Te’!hysteresis; Figure 8 c). This can be explained by a lower
concentration of free monomer that can form nuclei of 7H-agg

as a result of the formation of the off-pathway 7J-agg. Thus, the
appearance of 7J-agg has a direct impact on the formation of
the thermodynamic species by inhibiting the spontaneous
polymerization of 7H-agg. This analogy to nucleated amyloid
fibril formation in nature[44] inspired the authors to probe the
possibility of LSP for the first time. Indeed, the addition of
seeds of 7H-agg (obtained by sonication) to 7J-agg caused an
immediate J!H transition, whose kinetics depend on the [7J-

agg]/[7H-seed] ratio. Repeated cycles of mixing equally concen-
trated solutions of 7J-agg and 7H-seed corroborated the living
nature of the observed process, as the rate was diminished by
half in each cycle (Figure 8d).

A particularly relevant approach to broaden the scope of
LSP consists of the use of monomers that can be trapped in
a “dormant” state through the formation of intramolecular
hydrogen bonds, which retards spontaneous self-assembly.
This is the case for PBI 8 reported by Wgrthner and co-
workers, in which the stabilization of a dormant monomer
through amide/imide intramolecular hydrogen bonding pre-
vents self-nucleation (Figure 9a).[34] A clear hysteresis in both
pure toluene and MCH/toluene (2:1) was observed when
comparing the cooling and heating cycles (Figure 9b). The
kinetic dormant state can be subsequently used as a monomer
reservoir for seed-induced LSP, thereby demonstrating that it
is not only kinetic aggregates that can serve as monomer
feedstock in controlled SP.

Aida and co-workers reported on the initiator molecule-
induced LSP of a bowl-shaped corannulene derivative (9M)
with five amide-appended thioalkyl side chains. This molecule
remains in a cage-like “dormant” monomer conformation as
a consequence of the formation of an array of intramolecular
hydrogen bonds in MCH at 25 88C (Figure 9c).[32] Increasing
the temperature allows 9M to adopt an open conformation
that enables SP, thus showing the competitive character of the
closed conformation (dormant monomer) and polymer.
Based on these observations, the authors realized LSP by
the addition of the N-methylated derivative 9I, a polymeri-
zation initiator that is unable to adopt the closed conforma-
tion (Figure 9c). Molecules of 9I act as hydrogen-bond
acceptors, inducing reorganization in the dormant monomers
and thus initiating LSP.

Recently, our groups reported an example of a supra-
molecular polymer that exists as two concomitant, stable,
polymorphic structures. VT-UV/Vis and AFM experiments
showed that OPE-based PtII complex 10 forms two competing
aggregates in MCH depending on the cooling rate and
concentration (species A and B in Figure 10b).[45] Polymorph
A with a slipped molecular arrangement stabilized by
N@H···Cl@Pt interactions is obtained at high rates (2 K min@1)
through an isodesmic mechanism. The cooperative formation
of B, characterized by a pseudoparallel stacking driven by
N@H···Oalkoxy hydrogen bonding, is preferred at lower cooling
rates (0.1 K min@1). Under intermediate conditions, the two
species form concomitantly without interconversion, even

Figure 9. a) Chemical structure of PBI 8 and the equilibrium between
the active and dormant conformation. b) Thermal hysteresis during
the SP of 8 in toluene and MCH/toluene (2:1 v/v). c) Chemical
structures of corannulene derivatives 9M (monomer) and 9I (initiator).
A schematic representation of LSP of dormant 9M initiated through
addition of 9I inducing H-bond reorganization is also shown. Adapted
from Ref. [34] with permission. Copyright 2015 American Chemical
Society and from Ref. [32]. Copyright 2015 AAAS.

Figure 10. a) Chemical structure of OPE-PtII complex 10. b) UV/Vis
spectra of the monomer (M), as well as concomitant aggregates (A
and B). c) Time-dependent UV/Vis spectra showing the transformation
of A into B via M. d) Phase diagram and energy landscape showing
the competitive pathways. Adapted from Ref. [45] with permission.
Copyright 2019 American Chemical Society.

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after prolonged time. This demonstrates the minor energy
difference between the two species, which was calculated to
be 4 kJmol@1. The A!B transformation could only be
realized upon annealing solutions of kinetic species A at
elevated temperatures (Figure 10c). The corresponding UV/
Vis studies showed that disassembly of A into monomers
occurs prior to reassembly into polymorph B, thus showing
that A is a competitive, off-pathway aggregate with respect to
B. Close scrutiny of the system allowed an experimental phase
diagram to be established that can be used to predict the
outcome of the SP (Figure 10 d).

2.6. Systems of Higher Complexity

All of the previously described systems were character-
ized by an energy landscape consisting of only one thermo-
dynamic and one kinetic pathway. However, analysis of SP
can become more challenging in those cases where more than
one kinetic pathway exists.

In this context, the groups of De Cola and Mauro reported
the SP of PtII complex 11, which forms three aggregates with
remarkably different emission properties (Figure 11a).[46]

Initially, kinetic nanoparticle aggregates A were obtained
after injecting a 1,4-dioxane solution of molecularly dissolved
11 into water. These nanoparticles, which are strongly
emissive due to close Pt–Pt interactions, convert into the
thermodynamic species C within three weeks. Solvent com-
position-dependent as well as VT-UV/Vis and photolumines-
cence (PL) studies revealed a cooperative mechanism for the
formation of C in contrast to the isodesmic growth for A. By
adjusting the water/dioxane ratio after obtaining A, the
energy barrier for the A!C conversion could be modulated,
which allowed the process to be monitored by fluorescence
confocal microscopy (Figure 11b). Surprisingly, an intermedi-

ate species B was observed in these experiments. The
transient nature of this assembly precluded its isolation when
starting from monomeric 11. However, irradiation of C
(lexc = 405 nm) resulted in a fast, quantitative C!B con-
version.

Sugiyasu, Takeuchi, and co-workers demonstrated that
LSP is not limited to off-pathway assemblies or inactive
monomers serving as the polymerization feedstock.[27] Similar
to 7, ZnPs 12 and 13 self-assemble into J-aggregate nano-
particles (NPs) through an isodesmic mechanism (Figure 12).

After a lag time, the NPs propagate into 2D nanosheets
(NSs). This process is accelerated by increasing the ZnP
concentration, which indicates that 13NP is an on-pathway
intermediate in the formation of 13NS. Notably, this is one of
the few examples of a non-hierarchical consecutive pathway.
Moreover, sonication of 12NP produced H-type nanofibers
(NFs). This transition is, however, decelerated upon increas-
ing the concentration. Thermodynamic analysis disclosed the
fibers to be of slightly lower energy than 12NS, thus being the
thermodynamic structure. Hence, 12NP is simultaneously an
on-pathway intermediate along the kinetic route and an off-
pathway intermediate in the thermodynamic route. Strikingly,
LSP could be performed along both pathways, thereby
leading to 1D and 2D supramolecular architectures, respec-
tively. The difference in the dimensionality of the seeds was
evident from the kinetics of the seeded growth: 1D fibers
propagated linearly with time, whereas the growth of the
“reactive edge” in the nanosheets resulted in a sigmoidal
transition. Based on the profound understanding of the
energy landscape governing this system, exceptional control
over this multidimensional system could be achieved (Fig-
ure 12b).

Very recently, Wgrthner and co-workers reported one of
the most complex SP systems investigated to date. Perylene

Figure 11. a) Chemical structure of Pt complex 11 and schematic
representation of its self-assembly pathways. b) Fluorescence confocal
microscopy images depicting the evolution (from left to right) of A
into B and C. Adapted from Ref. [46] with permission. Copyright 2015
Springer Nature.

Figure 12. a) Chemical structure of ZnPs 12 and 13 as well as b) the
energy landscape depicting one- and two-dimensional LSP along
thermodynamic and kinetic pathways. Adapted from Ref. [27] with
permission. Copyright 2016 Springer Nature.

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bisimide (PBI) 14 self-assembles into three supramolecular
polymorphs (Agg 1 — Agg 3, Figure 13a,b).[47] Upon increas-
ing the concentration, 14 self-assembles into Agg 1 dimers,
which elongate into oligomers through an anticooperative
process. The high energy barrier associated with the nucle-
ation step for the growth of the cooperatively formed Agg 2 +

3 prevents their formation under dilute conditions.
However, both Agg 2 and Agg 3 can be obtained from

Agg 1 by sonication (Figure 13b). Quantum chemical simu-
lations starting from optimized dimer structures elucidated
that both Agg 1!Agg 2 and Agg 1!Agg 3 transformations
proceed through rearrangement of the dimers, which does not
require disassembly. This unprecedented, simultaneous on-
pathway nature of Agg 1 with regard to Agg 2 and Agg 3 was
confirmed experimentally for both transitions. Moreover, the
two transformations could be induced chemically by the
addition of the respective seeds to solutions of Agg 1. The
qualitative energy landscape in Figure 13c summarizes all the
characteristics of the system. It furthermore perfectly exem-
plifies how the precise description of the individual pathways
and phenomena according to the concepts discussed in
Sections 2.3–2.6 will help to fully understand and compare
such highly complex systems.

3. Conclusion and Outlook

In this Minireview, we have summarized the existing
concepts used to describe SP under kinetic and thermody-
namic control and critically reviewed their use in the current
literature. The selected examples show that careful attention
has to be paid to the terminology used to describe the nature
of pathways and their mutual relationship, especially in the
context of pathway complexity. Furthermore, various prepa-
ration methods to access different aggregates from the same
monomer as well as the corresponding energy landscapes
have been outlined. It is important to note that each energy

landscape is only valid for one set of final experimental
conditions. However, as a result of kinetic contributions, the
way to reach these conditions biases the product of SP.
Nevertheless, this dependence on experimental parameters
allows the polymerization outcome to be regulated (e.g
switching on or off certain pathways or changing the energy
landscape by changing the final conditions). We believe that
this work facilitates the establishment of reliable energy
landscapes for self-assembled systems and enables the gen-
eralization of current concepts in the literature. Thus, a de-
tailed understanding of the respective energy landscape will
enable the fine-tuning of the self-assembly and, in turn, the
functional properties of the emerging materials.

Acknowledgements

Financial support by the MINECO of Spain (CTQ2017-
82706-P) and the Comunidad de Madrid (P2018/NMT-4389)
is acknowledged. Y.D. is thankful to Comunidad de Madrid
for his predoctoral fellowship. G.F. thanks the European
Commission (ERC-StG2016-SUPRACOP-715923). J.M.
thanks the “Verband der chemischen Industrie” for his
Kekul8 PhD Fellowship.

Conflict of interest

The authors declare no conflict of interest.

How to cite: Angew. Chem. Int. Ed. 2019, 58, 16730–16740
Angew. Chem. 2019, 131, 16884–16895

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Manuscript received: May 8, 2019
Accepted manuscript online: July 4, 2019
Version of record online: September 30, 2019

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