Key words
chirality-driven self-assembly - multi-functionalization - heterochiral metal–ligand
complexes
Introduction
Multi-component self-assembly is critical in the construction of functional hybrid
structures from various building blocks, constructing structurally complex and functional
architectures for various applications.[1] The process of self-assembly,[2] where building units of a system are organized into an ordered and/or functional
structure, has attracted researchers from a diverse range of disciplines that vary
from chemistry and materials science to engineering and technology.[3]
The assembly through covalent bonds[4] has the advantage of being independent of and unaffected by solvent conditions,
such as solvent polarity and ionic strength.[5] However, the generation of covalent bonds often raises challenges due to the compatibility
of reagents and reaction conditions for functional groups within building units.[6] This issue often results in significant limitations in the diversity of assembling
functional groups. In contrast, using non-covalent bonds[7] reduces the risk of their reaction compatibility due to their mild assembly conditions.
In addition, highly reversible bonds allow multi-functional structures disassemble
back into individual building units, enabling the recycling of these small units.[8] Unfortunately, their inherent weaker bond strengths, which are highly sensitive
to environmental conditions
such as solvent polarity, temperature, ionic strength, and pH, often severely
limit their range of applications.[9] To this end, reversible metal–ligand complexes[10] have higher stability under a broader range of reaction conditions/environments
and can be assembled in situ under mild conditions. Most examples utilize combinations
of metal and achiral ligands for self-assembly, and a lack of selectivities among
achiral ligands often leads to challenges in controlling the overall shapes and sizes
of supramolecules. To this end, we recently reported a versatile approach to preparing
resin-immobilized catalysts through metal–ligand complexes.[11] Our unique approach utilizes the concept of chirality-directed self-assembly[12] where chiral bis(oxazoline) (BOX) ligands with complemental chirality selectively
form a heterochiral Zn(II) complex,[13] anchoring a catalyst onto the resin. In other words, when equimolar amounts of chiral
BOX ligands with opposite enantiomers were mixed in the presence of Zn(OAc)2, exclusive formation of the heterochiral Zn(II) complex was observed. The high selectivity
toward the formation of the heterochiral Zn(II) BOX complex arises from reduced steric
crowding of the phenyl rings on the chiral BOX ligand around the Zn(II) center.[14] The Zn(II) center on the homochiral Zn(II) complex is destabilized by adopting a
distorted tetrahedral geometry to accommodate two phenyl substituents in the same
quadrant ([Figure 1]). The loaded catalyst can be altered in situ through ligand exchange for 2-step
sequential reactions using the same resin. The report demonstrated that resin-bound
catalysts could be easily recycled under mild conditions without damaging resin functional
groups, helping to reduce the
generation of microparticle wastes.
Figure 1 The difference in stability between heterochiral Zn(II) complex (left) vs. homochiral
Zn(II) complex (right).
The concept of chirality-directed self-assembly was also employed to quantitatively
generate distinct Janus dendrimers in situ from various dendron subunits attached
to chiral BOX ligands.[15] The highly selective formation of the heterochiral Zn(II) complex at the focal point
of the Janus dendrimer enables the exclusive formation of Janus dendrimer upon mixing
two distinct dendritic domains, each functionalized by opposite enantiomer of BOX
ligands. The heterochiral Zn(II) BOX complex at the focal point was stable under elevated
temperature. However, the complex can be reversibly disintegrated under mild conditions
with the use of EDTA.
These previous studies have led us to believe that resin multi-functionalization is
possible if we identify sets of chiral BOX ligands that selectively form multiple
Zn(II) BOX complexes on the resin surface.[1],[5],[16] In other words, to realize the multi-functionalization of the solid support, the
interaction between the BOX ligand immobilized on the solid support and added ligands
must be highly selective ([Scheme 1A]). Lack of such selectivity led to a non-selective complexation, resulting in the
generation of wasteful unbound catalysts ([Scheme 1B]); therefore, difficult to control the relative ratio of the functional groups on
the resin. Hence, our goal here is to identify the optimum sets of chiral BOX ligands
generating highly selective Zn(II) BOX complexes to establish a versatile one-pot
approach for the
multi-functionalization of solid support.
Scheme 1 Multi-functionalization of resins through A) selective heterochiral Zn(II)-complexation
(quantitative) vs. B) non-selective complexation (with unbound homochiral Zn(II)-complexes).
Results and Discussion
Comprehensive studies on the relative stability of various homo- and heterochiral
Zn(II) BOX complexes have not been reported thus far ([Scheme 1A] vs. [1B]). Therefore, we decided to elucidate the efficiency in generating heterochiral Zn(II)
complexes to identify the correlation between the size of chiral substituents and
selectivity toward forming heterochiral Zn(II) complexes ([Table 1]). For this investigation, the ratio of heterochiral vs. homochiral Zn(II) BOX complexes
was measured using 1H NMR spectroscopy in CDCl3 ([Figure 2]).
Table 1 The efficiency of the generation of the heterochiral Zn(II) BOX complexes using (S,S)- and (R,R)-BOX ligands with various substituents
|
|
Entry
|
(R1/R2)a
|
Heterochiral Zn(II) complex (%)
|
Homochiral Zn(II) complexes (%)
|
|
a Chirality color code: R1 = substituent on the (S,S)-BOX and R2 = substituent on the (R,R)-BOX; b % ratio was calculated after 0:5 h of incubation at ambient temperature. The ratio
remained the same after 5 days at ambient temperature.
|
|
1
|
Ph/Ph
|
>99
|
0
|
|
2 b
|
Bn/Bn
|
77
|
23
|
|
3 b
|
Me/Me
|
72
|
28
|
|
4 b
|
Me/Bn
|
73
|
27
|
Figure 2 1H NMR spectrum of the free ligand, homochiral Zn(II) complex, and heterochiral Zn(II)
complex of chiral BOX ligands (top: Ph-substituted, middle: Bn-substituted, and bottom:
Me-substituted).
The exclusive formation of the heterochiral Zn(II) complex (SS,RR)-Zn(II) BOX (Ph/Ph) was observed when equimolar amounts of (S,S)-BOX (Ph) and (R,R)-BOX (Ph) were used ([Table 1], entry 1; [Figure 2], top). The ligand exchange process was instantaneous, and no homochiral Zn(II) complexes
nor free ligands remained in the solutions. By contrast, when the steric bulkiness
was moved further away from the chiral center on the oxazoline ring, as steric interactions
among chiral substituents in the homochiral Zn(II) complex is reduced, selectivity
toward the heterochiral Zn(II) complex was reduced. For instance, the benzyl-substituted
chiral BOXʼs Zn(II) complex reached equilibrium at ambient temperature with 25% homochiral
Zn(II) complexes remaining in the solution ([Table 1], entry 2; [Figure 2], middle).[17]
Interestingly, similar selectivity was obtained with methyl-substituted chiral
BOX ([Table 1], entry 3; [Figure 2], bottom).
In addition, when equimolar amounts of (RR,RR)-Zn(II) BOX (Bn) and (SS,SS)-Zn(II) BOX (Me) were mixed, the outcome of selectivity toward generating the heterochiral
Zn(II) complex ((SS,RR)-Zn(II) BOX (Me/Bn)) was identical to the cases with (SS,RR)-Zn(II) BOX (Me) and (SS,RR)-Zn(II) BOX (Bn) (entry 4).
[18]
These results indicate that steric effect at the C1 position on the chiral substituent
is significant in the outcome of chiral discrimination processes.
Next, to probe stability differences among homochiral Zn(II) complexes ([Scheme 1B]), a free ligand titration experiment was conducted as shown in [Table 2]. When 1 equiv of free (S,S)-BOX (Me) ligand was added to the homochiral (SS,SS)-Zn(II) BOX (Ph), a mixture of three homochiral zinc complexes, (SS,SS)-Zn(II) BOX (Ph), (SS,SS)-Zn(II) BOX (Ph/Me), and (SS,SS)-Zn(II) BOX (Me), was formed in a ratio 1.0 : 2.0 : 1.4 in favor of (SS,SS)-Zn(II) BOX (Ph/Me) through a rapid ligand exchange (entry 1 vs. 2).
Table 2 Ligand exchange experiments adding a free BOX ligand (S,S)-BOX (Me) to the homochiral complex (SS,SS)-Zn(II)-(Ph/Ph)
|
|
Entry
|
(S,S)-BOX (Me)
(equiv)
|
(SS,SS)-Zn(II) BOX % distribution a
|
|
(SS,SS)-Zn(II) BOX (Ph/Ph) (%)
|
(SS,SS)-Zn(II) BOX (Ph/Me) (%)
|
(SS,SS)-Zn(II) BOX (Me/Me) (%)
|
|
a Calculated based on 1H NMR integration of the homochiral Zn(II) complexes without including free ligands.
|
|
1
|
0
|
>99
|
0
|
0
|
|
2
|
1.0
|
23
|
45
|
32
|
|
3
|
2.0
|
0
|
32
|
68
|
|
4
|
4.0
|
0
|
0
|
>99
|
Further addition of free (S,S)-BOX (Me) led to the complete disappearance of (SS,SS)-Zn(II) BOX (Ph/Ph), leaving two homochiral (SS,SS)-Zn(II) BOX (Ph/Me) and (SS,SS)-Zn(II) BOX (Me) in solution with a ratio of 1 : 2 : 1 (entry 3). The complete conversion
to (SS,SS)-Zn(II) BOX (Me/Me) was reached when 4 equiv of free (S,S)-BOX (Me) was added to (SS,SS)-Zn(II) BOX (Ph) (entry 4).
To achieve the quantitative multi-functionalization of the solid support ([Scheme 1A]), combinations of chiral ligands must be carefully chosen to avoid generating wasteful
unbound complexes. To this end, based on the results above, the heterochiral Zn(II)
complexes showed higher stabilities than all of the homochiral Zn(II) complexes studied
here. Indeed, the heterochiral (SS,RR)-Zn(II) BOX (Me/Ph) formed quantitatively when opposite enantiomers of (RR,RR)-Zn(II) BOX (Ph/Ph) and (SS,SS)-Zn(II) BOX (Me/Me) were mixed, leaving no homochiral Zn(II) complexes remaining
in the solution ([Figure 3-1]).[19]
Figure 3 Generation of two specific heterochiral Zn(II) BOX complexes from three homochiral
Zn(II) complexes.
In contrast, using a pair of homochiral Zn(II) complexes, (SS,SS)-Zn(II) BOX (Ph/Ph) and (SS,SS)-Zn(II) BOX (Me/Me), similar experiments afforded a mixture of homochiral Zn(II)
complexes in solution ([Figure 3-2]). Combined results from above, this result strongly indicates the higher stability
of heterochiral Zn(II) complexes over any combination of homochiral Zn(II) complexes.
To this end, when 2 equiv of (RR,RR)-Zn(II) BOX (Ph/Ph) was added to this mixture of homochiral Zn(II) complexes, and
all complexes were converted to a combination of heterochiral Zn(II) complexes ((SS,RR)-Zn(II) BOX (Me/Ph) and (SS,RR)-Zn(II) BOX (Ph/Ph)) ([Figure 3-3], [Figure 4], top). In other words, the selective generation of heterochiral Zn(II) complexes
can be accomplished by mixing (RR,RR)-Zn(II) BOX (Ph/Ph), (SS,SS)-Zn(II) BOX (Ph/Ph), and
(SS,SS)-Zn(II) BOX (Me/Me) in a 2 : 1 : 1 ratio resulting in the selective formation of
(SS,RR)-Zn(II) BOX (Me/Ph) and (SS,RR)-Zn(II) BOX (Ph/Ph) in situ. Identical results were obtained through mixing combinations
of free ligands (R,R)-Zn(II) BOX (Ph), (S,S)-Zn(II) BOX (Ph), and (S,S)-Zn(II) BOX (Me) in a 2 : 1 : 1 ratio along with Zn(OAc)2. When the ratio of (SS,SS)-Zn(II) BOX (Ph) and (SS,SS)-Zn(II) BOX (Me) was altered (2 : 1), the final ratio of (SS,RR)-Zn(II) BOX (Me/Ph) and (SS,RR)-Zn(II) BOX (Ph/Ph) was also altered, identical to the initial mixture ratio of two
homochiral Zn(II) complexes. Within a temperature range tested (25 – 125 °C in DMSO-d
6), no differences in thermal stability between (SS,RR)-Zn(II) BOX (Me/Ph) and (SS,RR)-Zn(II) BOX (Ph/Ph) were observed. In other words, both complexes were intact at
elevated temperatures, and no
disintegration of complexes was observed. These experiments suggest that chirality-driven
self-assembly can load multiple functional groups quantitatively through metal–ligand
complexes onto the resin without generating wasteful unbound ligands.
Figure 4 Comparison of 1H NMR spectra: (SS,RR)-Zn(II) BOX (Ph/Ph) (bottom), (SS,RR)-Zn(II) BOX (Me/Ph) (middle), and formation of two specific heterochiral Zn(II) BOX
complexes (top).
To probe the applicability of the chirality-driven self-assembly for the multi-functionalization
of resin depicted in [Scheme 1A], we decided to use (R,R)-BOX-immobilized Wang resin,[20] which we have previously used to demonstrate a single functionalization of resin
through self-assembly. As previously demonstrated, the functional loading capacity
of the (R,R)-BOX-immobilized Wang resin was calculated by the standard Fmoc-quantification approach
and determined to be 0.28 mmol/g.[21] The generation of heterochiral Zn(II) BOX on the resin was achieved by mixing (R,R)-BOX-immobilized Wang resin with free (S,S)-BOX ligands in the presence of an equimolar amount of Zn(OAc)2. The formation of heterochiral Zn(II) complexes on the resin was monitored through
FTIR analysis. Any unbound free ligand and free Zn(II) complexes can be detected by
1H NMR spectroscopy by analyzing the supernatant solution.
When the equimolar BOX ligand, (S,S)-BOX (Ph), was added to the (R,R)-BOX (Ph)-functionalized Wang resin along with Zn(OAc)2, no free ligands or unbound homochiral Zn(II) BOX (Ph) complexes were detected in
the supernatant solution (CDCl3) ([Table 3], entry 1). FTIR analysis shows that the C=N stretch shifted from 1655 cm−1 (uncomplexed (R,R)-BOX (Ph) on a resin) to 1601 cm−1 (complexed) ([Figure 5A] vs. [5B]), and the results are consistent with previously observed values.[22],[23] The functionalization of resin required Zn(OAc)2 as its absence results in quantitative recovery of (S,S)-BOX (Ph) from the supernatant solution (entry 2). The resin-bound heterochiral Zn(II)
complex, (SS,RR)-Zn(II) BOX (Ph/Ph), remained intact and the complex did
not disintegrate when the resin was heated up to 160 °C for 72 h in d
6-DMSO. However, the treatment with EDTA disintegrated the complex, and then the released
(S,S)-BOX (Ph) was recovered quantitatively from the supernatant solution.
Table 3 A single functionalization of Wang resin through chirality-directed self-assembly
|
|
Entry
|
Added free ligand a
|
Product
|
|
Bound
|
Unbound
|
|
a Equimolar amounts (0.28 mmol/g) of ligand and Zn(OAc)2 were added to the suspended resin; b (S,S)-BOX (Ph) was mixed with suspended resin in the absence of Zn(OAc)2; c No free ligand was observed in the supernatant solution.; d ND: not detected.
|
|
1
|
(S,S)-BOX (Ph)
|
>98%
|
ND d
|
|
2
|
(S,S)-BOX (Ph) b
|
ND d
|
>98%
|
|
3 c
|
(R,R)-BOX (Ph)
|
46%
|
54%
|
Figure 5 FTIR comparison of A) (R,R)-BOX (Ph)-functionalized Wang resin, B) (RR,SS)-BOX (Ph/Ph)-functionalized Wang resin, C) (RR,SS)-BOX (Ph/Me)-functionalized Wang resin, D) (RR,SS)-BOX (Ph/Ph)- and (RR,SS)-BOX (Ph/Me)-functionalized Wang resin.
The FTIR analysis of EDTA-treated resin shows the C=N stretch at 1655 cm−1, indicating that the (R,R)-BOX (Ph) covalently attached to the resin was not affected by the EDTA treatment.
In fact, the heterochiral Zn(II) BOX can be regenerated on the EDTA-treated resin
by mixing an equimolar amount of (S,S)-BOX (Ph) along with Zn(OAc)2. In sharp contrast to the formation of the heterochiral Zn(II) complex on the resin,
the efficiency in forming homochiral Zn(II) complex, using (R,R)-BOX (Ph), on the resin was not efficient as almost half of the added ligand formed
unbound homochiral Zn(II) complex in solution (entry 3). These results support that
using chiral BOX ligands with complemental chirality led to quantitative loading of
the functional group on the resin.
Encouraged by the results above, a quantitative formation of two distinct heterochiral
Zn(II) complexes on the (R,R)-BOX (Ph)-functionalized Wang resin was investigated. When 0.5 equiv of each (S,S)-BOX (Ph) and (S,S)-BOX (Me) were mixed with the (R,R)-BOX (Ph)-functionalized resin in the presence of Zn(OAc)2, these added free ligands quickly disappeared from the supernatant solution ([Table 4], entry 1). The FTIR analysis of the resin indicated a generation of two heterochiral
Zn(II) complexes on a resin with two C=N stretches, 1598 cm−1 ((SS,RR)-Zn(II) BOX (Ph/Ph)) and 1593 cm−1 ((SS,RR)-Zn(II) BOX (Me/Ph)), shifted from 1655 cm−1 (uncomplexed (R,R)-BOX (Ph) on a resin) (Scheme 6D vs. 6B and 6C). We did not observe any thermal stability
differences on the resin between (SS,RR)-Zn(II) BOX (Ph/Ph) and (SS,RR)-Zn(II) BOX (Me/Ph) through a
temperature range tested (up to 160 °C in d
6-DMSO). In addition, no ligand exchange took place when additional (S,S)-BOX (Ph) or (S,S)-BOX (Me) was further mixed with the above dual-functionalized resin. For example,
when 10 equiv of (S,S)-BOX (Me) was mixed with (SS,RR)-Zn(II) BOX (Ph/Ph)/(SS,RR)-Zn(II) BOX (Me/Ph) dual-functionalized resin, no (S,S)-BOX (Ph) was released into the supernatant solution after 72 h at ambient temperature.
In addition, both FTIR C=N stretch signals (1598 cm−1 and 1593 cm−1) remained the same after the resulting resins were washed several times.
Table 4 A dual functionalization of Wang resin
|
|
Entry
|
Added ligands a,b
|
Product c
|
|
Bound
|
Unbound
|
|
a 1 equiv of free ligand = 0.28 mmol per 1.0 g of BOX-functionalized resin; b Equimolar amount of Zn(OAc)2 was used in all cases. c Bound/unbound ligands are calculated based on 1) quantification of bound ligands
upon their detachment from resin through EDTA treatment, and 2) quantification of
unbound complexes in the supernatant solution; d Based on resin loading capacity. e ND: not detected.
|
|
1
|
(S,S)-BOX (Ph) (0.5 equiv)
(S,S)-BOX (Me) (0.5 equiv)
|
>98%
|
ND e
|
|
2
|
(R,R)-BOX (Ph) (0.5 equiv)
(R,R)-BOX (Me) (0.5 equiv)
|
32%
|
68%
|
|
3
|
(S,S)-BOX (Ph) (0.25 equiv)
(S,S)-BOX (Me) (0.75 equiv)
|
>98%
|
ND e
|
|
4
|
(S,S)-BOX (Ph) (1.0 equiv)
(S,S)-BOX (Me) (3.0 equiv)
|
25%
(>98%)d
|
75%
|
These observations have led us to believe the alteration of the ratio of loading functional
group can be possible by simply adjusting the mixture ratio of chiral BOX ligands.
Indeed, when a ligand mixture consisting of 1 : 3 ratio of (S,S)-BOX (Me) and Fmoc-functionalized (S,S)-BOX (Ph) was mixed with (R,R)-BOX (Ph)-immobilized resin in the presence of Zn(OAc)2, the ratio of bound ligands (> 98% saturation on loading capacity) was identical
(1 : 3) to the added free ligand mixture (entry 3). An identical result was obtained
when the same mixture was used in excess molar amount (entry 4). These results indicate
that the ratio of loaded functional groups can be precisely controlled by altering
the mixture ratio of added functional groups.
Conclusions
In summary, the chirality-directed self-assembly of heteroleptic Zn(II) complexes
can be used as a strategy to load multiple functional groups on resin. Due to the
high selectivity toward forming heteroleptic Zn(II) complexes, this straightforward
process can be used without purification because there are no by-products formed.
The selectivity toward the formation of heterochiral Zn(II) core complexes was not
influenced by the size of the chiral substituents on the BOX ligand. The resin-generated
heteroleptic Zn(II) complexes are stable at elevated temperatures; however, they can
be easily disassembled through treatment by EDTA for resin recyclization. In theory,
this methodology enables to functionalize a range of solid supports such as graphene,
metal nanoparticles, and various polymer-based materials. Further studies are currently
in progress, including theoretical calculations of various homo- and heterochiral
BOX Zn(II) complexes.
Experimental Section
General Information: Solvents and materials were obtained from commercial suppliers (Fisher Scientific,
Sigma-Aldrich, and Alfa Aesar) and used without further purification. Unless otherwise
noted, all reactions were performed in standard dry glassware under an Argon atmosphere
in dry solvents. Evaporation and concentration of solvents were carried out with Büchi
Rotavapor R-200 attached to a Maximadry vacuum pump. Roto-evaporation for all zinc
complexes was performed at ambient temperature, and the residue was further dried
under a high vacuum to obtain the complexed products. THF used for the synthesis of
substituted box derivatives was dried using 4 Å molecular sieves. Preparative separations
were performed by silica gel gravity column chromatography using Silica Flash P60.
TLC analyses were performed on Merck Kieselgel 60 F254 glass plates and were visualized
with UV light or stains (iodine, vanillin, ninhydrin). 1H NMR and 13C NMR
spectra were recorded at 25 °C on a Varian 400 MHz spectrometer using CDCl3 and DMSO-d
6 as solvents, which were purchased from Sigma Aldrich and Cambridge Isotope Laboratories,
respectively. The solvent signals were used as internal standards for both 1H NMR (CDCl3
δ = 7.26 ppm) and 13C NMR (CDCl3
δ = 77.20 ppm) recordings. 1H NMR data are reported as follows: chemical shift (reported in parts per million),
multiplicity (s = singlet, d = doublet, t = triplet, quart = quartet, quint = quintet,
sext = sextet, sept = septet, br = broad, and m = multiplet), integration, and coupling
constants (reported in hertz). Mass spectra were measured with a Thermo Fisher Scientific
Q Exactive Plus (ESI, APCI) spectrometer and an ABI 4700 mass spectrometer. Infrared
spectra were collected on a Nicolet iS10 FTIR spectrometer using a Smart iTR-attenuated
total reflectance sampling accessory with a single bounce ZnSe crystal plate. Polarimetry
was measured in a Perkin Elmer Model 341 polarimeter at 25 °C in a 100 mm cell at
589 nm using CH2Cl2 as the solvent.
General Procedure for Preparation of Chiral BOX Ligands: (R,R)- or (S,S)-BOX ligands were prepared according to the published procedure.[24]
(R,R)- or (S,S)-BOX (Ph): To a solution of diethyl malonimidate dihydrochloride (90 mmol) in dichloromethane
(600 mL) was added the amino alcohol (98 mmol, 2.2 equiv) at room temperature. The
reaction mixture was stirred under reflux for 48 h, and water (150 mL) was added to
the reaction mixture. The crude product was extracted using dichloromethane (3 × 100 mL),
and the combined organic layers were washed with brine (2 × 200 mL). Solvents were
evaporated under reduced pressure, and the crude product was purified by column chromatography
with DCM/MeOH (19 : 1) as the eluent to give pure chiral BOX ligands. (S,S)-BOX (Ph): pale brown oil.; 1H NMR (400 MHz, CDCl3): δ 7.35 – 7.17 (m, 10 H), 5.25 (dd, J = 9.8, 8.3 Hz, 2 H), 4.67 (dd, J = 10.2, 8.4 Hz, 2 H), 4.17 (dd, J = 8.4, 7.9 Hz, 2 H), 3.57 (s, 2 H) ppm. 13C NMR (101 MHz, CDCl3): δ 163.00, 142.03, 128.69, 127.58,
126.64, 75.31, 69.74, 28.39 ppm. MS (ESI): m/z calculated for C19H18 N2O2 [M + H]+, 307.1441; found, 307.1427.
General Procedure for Preparation of Homochiral Zn(II) BOX Complexes: (SS,SS)-Zn(II) BOX (Ph) was prepared according to the published procedure.[24] To a solution of (S,S)-BOX (Ph) (2.0 g, 6.53 mmol) in dichloromethane (10 mL) was added Zn(OAc)2 (600 mg, 3.26 mmol) in methanol (5 mL) and the resulting reaction mixture was stirred
for 1 min and solvents are removed under reduced pressure to give 2.1 g (> 95%) of
pure (SS,SS)-Zn(II) BOX (Ph) as a clear crystal. 1H NMR (400 MHz, CDCl3) δ 7.20 – 7.10 (m, 12 H), 6.88 (dd, J = 6.2, 3.0 Hz, 8 H), 4.54 (t, J = 8.5 Hz, 4 H), 4.32 (t, J = 8.4 Hz, 4 H), 3.95 (s, 2 H), 3.77 (t, J = 8.4 Hz, 4 H) ppm. 13C NMR (101 MHz, CDCl3) δ 171.92, 141.03, 128.47, 127.64, 126.72, 73.34, 66.52, 54.30 ppm. MS (ESI): m/z calculated for
C38H35 N4O4Zn [M+H]+, 675.1993; found, 675.1802.
General Procedure for Preparation of Heterochiral Zn(II) BOX Complexes: (SS,RR)-Zn(II) BOX (Ph) was prepared according to the published procedure.[24] To a solution of (S,S)-BOX (Ph) (1.0 g, 3.26 mmol) in dichloromethane (5 mL) was added (R,R)-BOX (Ph) (1.0 g, 3.26 mmol) in dichloromethane (5 mL) at room temperature. Zn(OAc)2 (600 mg, 3.26 mmol) in methanol (5 mL) was added to the mixture, and the resulting
reaction mixture was stirred for 1 min, and the solvents were removed under reduced
pressure to give pure (SS,RR)-Zn(II) BOX (Ph) as white crystals. 1H NMR (400 MHz, CDCl3): δ 7.34 – 7.26 (m, 8 H), 7.25 – 7.18 (m, 4 H), 7.12 – 6.99 (m, 8 H), 4.05 (dd, J = 8.3, 5.2 Hz, 4 H), 3.89 (t, J = 8.7 Hz, 4 H), 3.38 (dd, J = 9.1, 5.2 Hz, 4 H) ppm.
General Procedure for Generation of Two Specific Sets of Heterochiral Zn(II) Complexes: Mixtures of (SS,RR)-Zn(II) BOX (Me/Ph) and (SS,RR)-Zn(II) BOX (Me/Ph) were prepared in one pot by simply mixing (RR,RR)-Zn(II) BOX (Ph/Ph), (SS,SS)-Zn(II) BOX (Me/Me) and (SS,SS)-Zn(II) BOX (Ph/Ph) in a 2 : 1 : 1 ratio. The mixture was a white powder. 1H NMR (600 MHz, CDCl3): δ 7.33 – 7.17 (m, 24 H), 7.10 – 7.03 (m, 8 H), 4.83 (dd, J = 8.9, 5.6 Hz, 2 H), 4.50 (t, J = 8.8 Hz, 2 H), 4.31 (dd, J = 8.6, 5.6 Hz, 2 H), 4.15 (s, 1 H), 4.06 (dd, J = 8.2, 5.3 Hz, 4 H), 3.89 (t, J = 8.7 Hz, 4 H), 3.87 (s, 2 H), 3.78 (t, J = 8.1 Hz, 2 H), 3.64 (s, 1 H), 3.45 (t, J = 7.4 Hz, 2 H), 3.38 (dd, J = 9.1, 5.2 Hz, 4 H), 2.69 (m, J = 6.7 Hz, 2 H), 0.97 (d, J = 6.3 Hz, 6 H) ppm.
Generation of Dual-Heterochiral Zn(II) Complexes on the Wang Resin: The (R,R)-BOX-functionalized resin (R,R)-SI-2 (3.00 g, 0.278 mmol/g) was suspended in dry DCM and stirred at ambient temperature
for 1 h. To the solution was added (S,S)-BOX (Ph) (128 mg, 0.42 mmol) and (S,S)-BOX (Me) (76 mg, 0.42 mmol) in DCM (2 mL), and the mixture was stirred for 1 min.
A solution of Zn(OAc)2 (153 mg, 0.84 mmol) in MeOH (2.0 mL) was added to the mixture and stirred for 10 min
at room temperature. The resin was removed by filtration and washed with DCM (3 × 10 mL),
followed by diethyl ether (3 × 10 mL). FTIR: 1598 cm−1 ((SS,RR)-Zn(II) BOX (Ph/Ph)) and 1593 cm−1 ((SS,RR)-Zn(II) BOX (Me/Ph)).
Funding Information
This work is supported by the National Science Foundation under grant number 1 856 522.
