Next Article in Journal
Investigation on the Compressive Strength and Time of Setting of Low-Calcium Fly Ash Geopolymer Paste Using Response Surface Methodology
Next Article in Special Issue
Axial Compression Behavior of Ferrocement Geopolymer HSC Columns
Previous Article in Journal
Characteristics and Preparation of Designed Alginate-Based Composite Scaffold Membranes with Decellularized Fibrous Micro-Scaffold Structures from Porcine Skin
Previous Article in Special Issue
A Review on Synthesis, Structural, Flame Retardancy and Dielectric Properties of Hexasubstituted Cyclotriphosphazene
 
 
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Review

Liquid Crystals Investigation Behavior on Azo-Based Compounds: A Review

Sustainable Materials and Renewable Energy (SMRE) Research Group, Faculty of Science and Natural Resources, Universiti Malaysia Sabah, Jalan UMS, Kota Kinabalu 88400, Sabah, Malaysia
*
Author to whom correspondence should be addressed.
Polymers 2021, 13(20), 3462; https://doi.org/10.3390/polym13203462
Submission received: 29 August 2021 / Revised: 30 September 2021 / Accepted: 7 October 2021 / Published: 9 October 2021
(This article belongs to the Special Issue Synthesis, Processing, Structure and Properties of Polymer Materials)

Abstract

:
Liquid crystal is an intermediate phase between the crystalline solid and an isotropic liquid, a very common substance in our daily lives. Two major classes of liquid crystal are lyotropic, where a liquid crystal is dissolved in a specific solvent under a particular concentration and thermotropic, which can be observed under temperature difference. This review aims to understand how a structure of a certain azo compound might influence the liquid crystal properties. A few factors influence the formation of different liquid crystals: the length of the alkyl terminal chain, inter/intra-molecular interaction, presence of spacer, spacer length, polarization effects, odd-even effects, and the presence of an electron-withdrawing group or an electron-donating group. As final observations, we show the compound’s different factors, the other liquid crystal is exhibited, and the structure–property relationship is explained. Liquid crystal technology is an ideal system to be applied to products to maximize their use, especially in the electronic and medical areas.

1. Introduction

Azo compounds represent a large branch of the liquid crystal sciences. The azo compound is a compound that contains two or more organic groups, which an azo group separates by –N=N– as its linking unit [1,2]. In order to conserve natural flora and fauna sources, an alternative was taken by producing a synthetic dye using an azo compound. An azo compound is an important group used extensively in the textile industry [3], manufacture of ink [4], and the cosmetic industry [5].
Liquid crystal is a liquid that is not isotropic, has two refractive indexes, and displays interference in a polarized light [6,7]. According to Stegemeyer (1989), it was first discovered by Dr. Friedrich Reinitzer back in 1888 in a German University located in Prague, where he revealed two crucial traits of the cholesteric liquid crystal, which are the change of color with temperature and the temperature range of the cholesteric phase, and the melting point and clearing point [8,9].
It has been proven that liquid crystal can form an intermediate phase, called the mesophase. This phase is situated in the middle of a crystalline solid and an isotropic liquid [10]. Relying on a particular circumstance in which the mesophase becomes apparent, liquid crystal can be characterized into two major classes: lyotropic and thermotropic [11]. It can be suggested that lyotropic shows the liquid crystal state in a certain concentration, as Andrienko (2018) reported that the specification of this liquid crystal is its concentration [12].
However, Brightman (1954) has stated that the thermotropic phase is a phase where a liquid crystal is prepared via a heating process [7]. It can be signified as a liquid crystal formed with temperature change, in agreement with Kusabayashi and Takenaka (1984) who reported that thermotropic liquid crystals give out a few different forms with temperature variation [13]. Enantiotropic is a term to define a thermodynamically stable mesophase that appears on heating and cooling of the molecule, while a thermotropic mesophase that arises only during cooling of a molecule is termed as a monotropic mesophase. On the other hand, a molecule that exhibits liquid crystal under the same influence as a lyotropic (solvent) and a thermotropic (heat) is referred to as an amphotropic [14].
Generally, the systemic nature of the thermotropic liquid crystal is dependable on the molecular shape of the crystal, whether it is a rod-like or a disc-like shape molecule [15]. The thermotropic liquid crystal with disc-like molecules are a discotic mesogen, while a thermotropic liquid crystal with rod-like molecules is a calamitic mesogen, which can be sub-divided into nematic, cholesteric and smectic phase.
A nematic phase is the simplest liquid crystal where the molecules are positioned in a long axis across the same preferred direction [12]. This means that the rod-like molecules are arranged in a plane parallelly. In a thermotropic liquid crystal, the positional order of the molecules can be destructed if the molecules are treated with heat at a specific temperature but not the orientational order [15]. As a molecule of a nematic mesophase is aligned parallelly along its axes, this mesophase exhibits anisotropic physical properties. Typically, a nematic phase shows schlieren, marble, and pseudoisotropic textures in accordance with the structure of its surface.
Cholesteric mesophase is also known as a chiral nematic phase (N*) as it is formed via doping of a nematic liquid crystal or when the molecules of a system are chiral [16]. The director of a cholesteric mesogen tends to form a helix with pitch due to the alignment of an adjacent molecule at a trivial angle of one another. Basically, a pitch is a distance taken by the director to make one full turn in the helix. This helical structure of N* can reflect light with a wavelength uniform to the pitch length. A cholesteric mesogen commonly exhibit a schlieren textures.
Different from a nematic phase, a smectic phase is aligned in layers disclosing an association between its position along with the orientational order [12]. A different smectic phase is formed as the molecular order of the smectic phase change, which is Smectic A (SmA), Smectic B (SmB), Smectic C (SmC), Smectic F (SmF), and Smectic I (SmI). These smectic are then sub-divided into two categories depending on whether the molecules are tilted to the layer normal or not. A part of SmA and SmB, other smectic are tilted phase.
Among all other smectic, SmA or SmC are often observed. These mesogen is formed when each molecule does not have a long-range positional order [15]. The molecules in a smectic A phase are arranged in layers so that the long axis is perpendicularly aligned to the plane. Most compound that exhibits these kinds of structure is a compound that carries a terminal polar group [17]. Generally, this phase displays a focal-conic texture.
SmC differs from the SmA phase as the director of the molecule’s constant tilt angle measured normally to the smectic plane [18]. The layers of the smectic C phase are closely packed, respecting the director of the phase, in a short-range. Similar to the nematic mesophase, SmC has a chiral smectic C (SmC*). The director of the layer is identical to SmC, and the only difference it makes is that the angle that rotates from a layer to another and forms a helix. According to [16], there is a sub-phase of the smectic C phase called the anticlinic smectic C. The order of this molecule is similar compared to the order of a smectic C phase. The difference between each phase is the correlation between the tilted direction in the layers.
Understanding of the structure–property relationship of the compound is required in order to understand the interconnections between the core system, linking unit, and terminal group. Currently, there is a lack research focused on this area. There has been a lack of research that focuses on the azo-based compounds, especially on the methods and the structure–property relationship. Hence, this review will help future researchers to understand the phase properties and the characterization of azo-based compounds.

2. Structure–Property Relationship

Despite being lyotropic or thermotropic, most liquid crystal can exhibit at least one liquid crystal phase. According to Safinya et al. (1986), a thermotropic liquid crystal can exhibit one to several liquid crystal phases between the crystal and isotropic states [18]. However, there is a time where a liquid crystal does not exhibit any mesophase at all. This study will explain the possibilities of liquid crystal disclosing different types of liquid crystal phase, why a structure with the same central unit gives out different liquid crystal phases, and how any substitution can affect the mesomorphic.
In accordance with a study by Collings and Hird (1997), the structure–properties relationship is crucial to understand for the synthesizing or altering of a molecule in a certain way or arrangement to get a certain mesomorphic phase [14]. This understanding is important, especially when the liquid crystal is synthesized for a particular application that requires a particular liquid crystal phase.
A study was conducted in 1997 by Parra et al. on the structure–properties relationship of azo-based compounds [19]. In this study, Parra and her co-worker synthesized two azo compounds, 1(a–f) and 2(a–f). All homologues of compound 1a were claimed to display a nematic phase. In addition, homologues n = 9 and 10, compounds 1e and 1f, respectively, show a monotropic smectic C phase. Similar to compound 1, all homologues of compound 2 also exhibit an enantiotropic nematic phase. However, compounds 2(a–c) displays a monotropic smectic C while compound 2(d–f) exhibit an enantiotropic smectic C phase. Compound 2 appears to have more extensive mesomorphic range compared to compound 1. Parra and her co-worker stated that the low mesophase stability of compound 1 is caused by the presence of a thiophene ring which produces an additional deviation that hinders the formation of a stable mesophase.
Polymers 13 03462 i001
Comp1a1b1c1d1e1f
RC5H11C6H13C7H15C8H17C9H19C10H21
Polymers 13 03462 i002
Comp2a2b2c2d2e2f
RC5H11C6H13C7H15C8H17C9H19C10H21
Two years later, Belmar et al. (1999) synthesized quite a similar azo compound, namely compounds 3(a–h) [20]. All homologues of compound 3 give out a nematic phase showing that corresponding molecular interactions occur that give the same outcome in terms of molecular arrangement and thermal stability. However, not all homologues exhibit smectic C phase, such as compounds 3(a–d) as a layered smectic order is not ideal due to the difference in the volume occupied by the opposite chain. Nevertheless, a tilted smectic C order is formed as the alkoxy chain lengthens starting of homologues 7 to 10, and almost the same to the opposite chain.
Polymers 13 03462 i003
Comp3a3b3c3d3e3f3g3h
RC3H7C4H9C5H11C6H13C7H15C8H17C9H19C10H21
In 2001, Lee et al. synthesized two crystalline dyes containing a non-activated pyranylazo group, compounds 4(a–f) and 5(a–f) [21]. At the first heating phase, none of the homologues of compounds 4 and 5 display any mesomorphic property due to the thermo- and photochromic properties of the dye. This property causes a small ring-opened merocyanine species, which is not favored at high temperatures. Only after the first heating-cooling phase does the compound starting to exhibit a mesophase. Compounds 4a and 4c show an enantiotropic nematic phase, compounds 4b and 4d display a monotropic nematic phase, while compounds 4e and 4f do not form any liquid crystal phase. In contrast, all homologues of compound 5 form a nematic phase, and some even display a smectic A phase, except compounds 5d and 5e.
Polymers 13 03462 i004
Comp4a4b4c4d4e4f
R(CH2)4CH3(CH2)5CH3(CH2)6CH3(CH2)7CH3(CH2)8CH3(CH2)9CH3
Polymers 13 03462 i005
Comp5a5b5c5d5e5f
R(CH2)4CH3(CH2)5CH3(CH2)6CH3(CH2)7CH3(CH2)8CH3(CH2)9CH3
In the same year, two azo compounds were synthesized containing a similar structural unit, comprised of pyridine in compounds 6(a–f) and 1,3,4-thiadiazole rings in both compounds 6(a–f) and 7(a–f) [22]. All homologues of both compounds exhibit a liquid crystal phase. As for compound 6, all homologues display a crystal to isotropic transition, and only two of the highest homologues, compounds 6e and 6f exhibit a monotropic nematic phase. Compound 7 shows a dimorphism of a nematic phase and a smectic C phase. However, compounds 7(a–c) exhibit a monotropic smectic C phase. Nevertheless, the thermal stability of compound 7 is higher compared to the thermal stability of compound 6. The most prominent difference between compounds 6 and 7 can be seen from the structure. Compound 6 comprises a pyridine unit at the end of the central core and only one lateral chain, while compound 7 has a benzene ring instead of a pyridine, two lateral units, and a greater molecular length. To briefly summarize, compound 6 contains a pyridine unit, and is not long enough to be polarized enough to exhibit a stable liquid crystal phase compared to compound 7.
Polymers 13 03462 i006
Comp6a6b6c6d6e6f
RC5H11C6H13C7H15C8H17C9H19C10H21
Polymers 13 03462 i007
Comp7a7b7c7d7e7f
RC5H11C6H13C7H15C8H17C9H19C10H21
So et al. (2003) reported in his study about compounds 8(a–d), where this compound has two two-ring mesogenic units that are connected by a spacer, namely 2-hydroxy-1,3-dioxypropylene [23]. All homologues of compound 8 have display an enantiotropic schlieren and/or a broken fan textured smectic C phase except for compound 8a. Figure 1 shows a micrograph of compound 8c. This phenomenon happens due to the temperature range of mesophase increase with the increasing length of the terminal alkyl chain.
Polymers 13 03462 i008
Comp8a8b8c8d
RC6H13C8H17C10H21C12H25
Compounds 9(a–c) was synthesized by Abbasi et al. (2006) [24]. Compounds 9(a–b) display a monotropic liquid crystal phase during cooling from the isotropic liquid. However, compound 9c formed an enantiotropic mesophase behavior and showed a liquid crystalline characteristic on heating and cooling from the isotropic liquid. Abbasi et al. declared that the stability of mesophase is influenced by the alkyl length (R). Compound 9c with the longest alkyl chain length exhibit enantiotropic mesophase which is thermodynamically stable compound, and compound with a short chain length (9a and 9b) exhibit unstable mesomorphic behavior.
Polymers 13 03462 i009
Comp9a9b9c
RC7H15C11H23C15H31
In the same year, compounds 10(a–c) and 11(a–c) were synthesized by Rezvani et al. (2006) [25]. Compounds 10(a–c) did not show any liquid crystal phase as this compound directly melted into an isotropic liquid. It was claimed that the melting point of the ligands decreases with increasing alkyl chain length value. Compound 11a exhibit four endothermic transitions, where the first two transitions are equivalent to the crystal-to-crystal transition. The third transition peak at 204.3 °C with enthalpy values of 532.43 kJ mol−1 is corresponding to a crystal phase to a mesophase. A Schlieren texture typically for the smectic C phase was detected, as reported in Figure 2. The fourth transition peak at 240.3 °C with a low enthalpy value of 5.25 kJ mol−1 is responsible for the transition from mesophase to the isotropic liquid. The high clearing enthalpy corresponding to the mesophase to isotropic transition indicates that the mesophase structure is highly in order.
Polymers 13 03462 i010
Comp10a10b10c
RC9H19C11H23C13H27
Polymers 13 03462 i011
Comp11a11b11c
RC9H19C11H23C13H27
Compounds 12(a–c) were first synthesized by So et al. in 2001. In 2006, he conducted another study using the same compound but with a different alkyl chain [26]. During the heating phase, compound with the highest homologues, compound 12c, exhibits a crystal to smectic C phase at 163.0 °C, and smectic C to isotropic liquid at 168.0 °C and compounds 12a and 12b does not show any mesomorphic phase. However, during the cooling scan, compounds 12b and 12c show a smectic C mesophase (Figure 3) but not compound 12a. Compound 12b form a monotropic smectic C liquid crystal phase with a schlieren or broken-fan texture, whereas compound 12c exhibit an enantiotropic smectic C liquid crystal phase with a schlieren texture and compound 12a shows no mesomorphic behavior. So et al. (2006) reported that increasing the alkyl chain is expected to increase the length-to-breadth, resulting in a liquid crystal phase, especially the smectic phase [27]. He also claimed that as the length of the terminal chain increase, the temperature range of the smectic phase also increases. It was also discussed in the study that the entropy change keeps increasing as the terminal chain increase, hence, a smectic mesophase is prone to show, and as the terminal chain increases, the thermal stability of a tilted smectic C also increases.
Polymers 13 03462 i012
Comp12a12b12c
RC5H11C7H15C9H19
Lutfor et al. (2009) have synthesized compounds 13(a–f) with six different homologues [28]. As for raw compound 13a, two transition peaks were observed during cooling of compound at 175.2 and 123.1 °C, which are assigned for the isotropic to smectic and smectic to crystal transition, respectively. Chloro-substituted compound 13b also shows two peaks on cooling, 144.3 and 126.0 °C, which are corresponded to isotropic to smectic and smectic to crystal transition, respectively. Compound 13c and 13f do not display any liquid crystal phase, and it melts at 168.0 and 165.0 °C and crystallized at 162.0 °C and 160.0 °C, respectively. Compound 13d is a fluoro-substituted compound that displays two peaks on cooling at exactly 150.5 and 127.1°C, corresponding to isotropic to smectic and smectic to crystal transition, respectively. Compound 13e is a fluoro, and chloro-substituted compound that shows two peaks on cooling at 142.9 and 126.3 °C, correspond to isotropic to smectic phase and smectic to crystal phase. In summary, the substitution of F atom to the aromatic core in compound 13d and chloro-substituted of compound 13b decreases the mesophase-isotropic transition temperature compared to compound 13a. Compound 13e possessing both F and Cl atoms have the lowest transition temperature compared to the other compounds.
When cooling from the isotropic liquid, compounds 13d and 13e exhibit a fan-like texture which is typical for a smectic phase. Both compounds form a smectic phase at a lower temperature due to the addition of F atoms in compound 13d and F and Cl atoms in compound 13e. Compound 13(a, b, d, and e) were found to be monotropic in nature (Figure 4), and only compound 13a was studied to be thermodynamically more stable compared to the other compound. However, it was expected that compound 13a has the highest mesomorphic stability as it contains no lateral substitution that may disturb the aromatic core packing.
Polymers 13 03462 i013
Comp13a13b13c13d13e13f
RHHHFFF
R’HClCOOHHClCOOH
There are several possible reasons for the absence of a smectic mesophase. Firstly, the dipole of the substituent is partly canceled by the dipole of the ester group. Next, no other dipole across the long axis of molecules. Lastly, the strength of intermolecular lateral attractions is reduced as a result of a long narrow to be pushed further apart due to an increase in molecular breadth [29]. Compounds 14(a–b) consists of CH3 and F substituted compounds, respectively. Compound 14a is prone to show a nematic phase while compound 14b tend to exhibit both nematic and smectic phase. Briefly summarize, the ratio of lateral to the terminal attraction of compound 14b is higher than compound 14a. This is because the F atom does not increase the molecule width due to the small atomic size compared to the adjacent substituent. Although the C–F bond has a high dipole moment, the bond itself cannot be entirely canceled by the dipole moment because of the ester group that presents in the compound. The dipole moment of the long axis will approach the dipole moment of the lateral axis, causing the attractive terminal forces is almost the same as the attractive lateral forces. Hence, two phases were formed at low temperatures.
Polymers 13 03462 i014
Comp14a14b
RCH3F
In 2011, two ligands containing Cu and Ni atoms were synthesized by Yeap et al. (2011), namely compounds 15(a–e) and 16(a–e) [30]. All compound 15 first exhibits a schlieren textured nematic phase followed by a focal conic fan shape textured typically for smectic A. However, all compound 16 does not exhibit a mesomorphic behavior due to direct isotropization during the heating and cooling phase without exhibiting any liquid crystal phase. The layer spacing of compound 15(a–e) is 1.04 Å. This layer spacing corresponds to the molecular length, and the layer thickness of compound 15 is slightly lower than its molecular length. This explains the presence of interdigitation of the alkoxy chain and its neighboring layer.
Polymers 13 03462 i015
Comp15a15b15c15d15e
MCuCuCuCuCu
RC8H17C10H21C12H25C14H29C16H33
Comp16a16b16c16d16e
MNiNiNiNiNi
RC8H17C10H21C12H25C14H29C16H33
Yeap et al. (2011) also focused on the study of a structure–property relationship of compound 17, which was synthesized by Reddy et al. (1991) [30,31]. Compound 17 exhibit a smectic A phase and is thermodynamically enantiotropic up to the clearing temperature of 33.0–261.0 °C. Such a thing happens due to the introduction of azobenzene cored that may induce mesophase formation in compound 17 and lower the temperature of complexes.
Polymers 13 03462 i016
Comp17
RC5H11
A year later, compounds 18(a–d) were synthesized by Yang et al. (2012) [32]. In this study, all compounds 18 exhibit mesomorphic phases. This is due to the six or eleven segments (n = 6 or 11) present in the compound that acts as a spacer. In his study, Yang et al. (2012) argued that in order for a compound to exhibit a mesomorphic phase, a liquid crystal must contain a suitable spacer length between the center and the terminal chain [32]. This flexible spacer is also crucial as it affects the dipole and molecular interaction between the compound, which will play an important role in mesophase formation. During the heating scan, compound 18a melted, and a cholesteric liquid crystal was exhibited between 138.7 and 189.1 °C. On the other hand, compound 18c was observed to show an enantiotropic mesophase at between 160.0–185.4 °C and 135.6–183.1 °C, upon heating and cooling scan, respectively. Compound 18a displayed a broader phase transition temperature range compared to 18c, which shows that the electron-withdrawing nitro moiety intensifies the head-to-tail molecular interactions. However, in compound 18b, the longer methylene spacer decreases the head-to-tail interactions, resulting in a phase transition temperature range. In contrast, compounds 18c and 18d that contain a methoxy terminal chain exhibit different behavior. Compound 18d has a broader phase transition temperature change compared to compound 18c. Based on this observation, the rigidity of the mesomorphic core, length of the flexible spacer, and the type of terminal chain play an important role in the dipole–dipole interaction that leads to the variability of the phase transition temperature. Hence, it will later influence the formation of different types of liquid crystal properties and textures.
Polymers 13 03462 i017
Comp18a18b18c18d
n611611
RNO2NO2OCH3OCH3
Two azo compounds bearing two different moieties used at the end terminal were synthesized: compounds 19(a–i) and 20(a–i). Lower homologues of both compounds only exhibit a nematic phase, while compounds with higher homologues, which are compounds 19h, 19i, 20f, 20g, 20h, and 20i, possess a longer terminal chain exhibit an additional phase transition directing to a layered mesophase. During the cooling scan, all homologues of both compounds are enantiotropic in nature and exhibit a schlieren and marbled texture typically for a nematic mesophase. As observed, the nematic phase range decreases with an increasing chain length in both compounds [33].
Polymers 13 03462 i018
Comp19a19b19c19d19e19f19g19h19i
n456789101112
XCNCNCNCNCNCNCNCNCN
Comp20a20b20c20d20e20f20g20h20i
n456789101112
XNO2NO2NO2NO2NO2NO2NO2NO2NO2
Compounds 21(a–d) have a similar molecular structure except for the R group that was substituted on the benzothiazole ring. Hence, different types of mesophase were displayed by each compound during the heating and cooling cycles. Generally, the terminal methacrylate unit and the substituent on the benzothiazole ring are crucial to forming a liquid crystal. Compound 21a shows only a smectic mesophase, while compounds 21b, 21c, and 21d display both nematic and smectic phases. The terminal methacrylate unit is responsible for forming the smectic phase as this unit elevates the polarizability anisotropy, which is ideal for the lateral attraction of molecules to form a strong smectic phase. As mentioned earlier, compounds 21b, 21c, and 21d exhibited both smectic and nematic liquid crystal phases. Nematic liquid crystal is favored as the replacement of hydrogen atom on compound 21a by a methyl group on compound 21b, methoxy group on compound 21c, and ethoxy group on compound 21d, to the sixth position of the benzothiazole ring was facilitated by conjugation of the high core polarizability with the short terminal chain [34]. The polarization of benzothiazole moiety is directly affected by the electron distribution in the electron-donating substituent. The substituent size also influences the mesophase temperature transition in the sixth position of the benzothiazole ring. The ethoxy substituent has the greatest mesophase stability compared to the methoxy or methyl substituent. To conclude, the terminal methacrylate unit and the sixth position substitution play a vital role in confirming the liquid crystal phase formation.
Polymers 13 03462 i019
Comp21a21b21c21d
RHCH3OCH3OC2H5
Compounds 22 and 23 are azobenzene chromophores with a fluoro substituent. Both compounds are similar compared to the number of fluorine atom each compound possess, compound 22 contain only one fluorine atom while compound 23 contain two fluorine atoms. Compound 22 shows a nematic to isotropic transition at 158.9 °C, whereas compound 23 exhibit a smectic A to isotropic transition at exactly 157.6 °C. The number of fluorine substituent present in the compound influence the transition temperature by increasing the number of fluorine atom, the transition temperature will decrease [35].
Polymers 13 03462 i020
Compound 22
Polymers 13 03462 i021
Compound 23
All compounds 24(a–f) exhibited a schlieren texture in an enantiotropic liquid crystal phase which is typical for a nematic phase. The thermal transition of the nematic phase of methoxy homologues (24d, 24e, and 24f) is higher than the methyl homologues compounds (24a, 24b, and 24c). The presence of an oxygen atom on the methoxy group is vital domination in the mesophase thermal stability and the thermal phase range. Upon heating, the enthalpy values of the crystal to the nematic phase transition of compounds 24a, 24b, and 24c are 38.8, 46.6, and 50.3 °C, respectively. As for compounds 24d, 24e, and 24f are 99.0, 77.8, and 72.4 °C, respectively. These large enthalpy values suggest a strong Van der Waals interaction between the end unit of an adjacent molecule. However, upon cooling, the enthalpy values recorded for the crystal to the nematic phase transition are 26.2, 27.1, 25.8, 46.6, 43.7, and 47.0 °C for each compound, respectively. These lower enthalpy values upon cooling are lower compared to the enthalpy values upon heating. This is due to the fact that the strong Van der Waals interactions between the end of the chain of a neighboring molecule keep them static in the crystalline state before the gradation to liquid crystal starts in the heating cycle [36].
Polymers 13 03462 i022
Comp24a24b24c24d24e24f
n456456
RCH3CH3CH3OCH3OCH3OCH3
Compounds 25(a,b) are novel benzoates that contain three phenyl rings and a trimethylsilyl group in the terminal position. Both compounds possess a similar structural formula having a central azo compound with an eminently polar nitro group and a pentyl chain except the R group at the end of the chain. Despite having a similar structural formula, only one compound exhibits a liquid crystal property, which is compound 25a. The optical texture of compound 25a is illustrated in Figure 5. The polar nitro terminal favored a smectic A phase, while compound 25b possessing an alkyl chain does not display any liquid crystalline phase property. To conclude, the property of a liquid crystal is reduced as the chain length lengthen as per the disruption of the packing layers. Hence, the only molecule with a short-chain compound can display any liquid crystalline property [37].
Polymers 13 03462 i023
Comp25a25b
RNO2C5H11
Compounds 26(a–e) were synthesized by Selvarasu and Kannan, in 2015 [38]. Generally, the transition temperature of compounds 26a and 26b is larger compared to the transition temperature range of compounds 26d and 26e, as the electron-withdrawing substituent in compounds 26a and 26b have a strong Π to Π* interaction that increase the head to tail molecular structure. The nematic to the isotropic thermal stability of compounds 26a and 26b are higher compared to compounds 26d and 26e. The reason is that the –CN and –Cl groups as well as the benzene ring located in the terminal position will cause both compounds to have high polarity and thermal attraction that later will causes the thermal stability to increase. The only difference that compounds 26a and 26e show is on the substitution unit at the terminal end. Both of these compounds share the same central unit, a cinnamoyloxy group (–C6H5–CH=CH–COO–) which is directly connected to the alkyloxyphenylester group. The presence of the double bond in the cinnamoyloxy group lengthen the length of polarizability and elevate the thermal stability.
Polymers 13 03462 i024
Comp26a26b26c26d26e
RCNClHCH3OCH3
A year later, Selvarasu and Kannan (2016) synthesized a new azobenzene compound, compound 27 [39]. Compounds 27a, 27b, and 27c exhibit a nematic phase with the lowest homologues of n: 6 forming small droplets that affiliate into a classic schlieren nematic and compound of homologues n: 8 and 10 display a focal-conic textured nematic phase while the compound with the highest homologues exhibits a nematic phase and an addition of a focal conic textured smectic C phase upon cooling from the isotropic liquid. The formation of a nematic phase is a result of the alkoxy chain terminal being more noticeable. Compound 27 contains a cinnamoyloxy group connected directly to the azo compound and the ester group that acts as the central unit of the molecule, and a double bond that increase the polarizability. The core of compound 27 is directly bonded to an ester group, causing the molecule to lose stability. This phenomenon is due to the ability of the oxygen atom of the carbonyl group to bump into the non-bonded sides of the adjacent hydrogen in the aromatic ring, which attributed to the strain in the molecules. An ester linkage contains a ketonic bond, where the electron is being pulled by the ester group which causes the transition temperature to decline. To sum everything up, the attributes responsible for mesophase formation are the effect of terminal alkoxy containing azobenzene moiety and the central linkage with or without the spacer. The presence of an olefinic unit reinforces the length of polarizability, and an additional olefinic unit would proliferate the thermal stability with a high polarizability.
Polymers 13 03462 i025
Comp27a27b27c27d
RC6H13C8H17C10H21C12H25
Compounds 28(a–f) are azo-bridged compounds with triphenylene cores. The only difference between the compounds 28(af) is the length of the methylene units. The length of the spacer has a vital role in the fluctuation of the transition temperature. Upon cooling, the melting point of compound 28a is higher compared to compound 28b. However, it gradually elevates from compounds 28b to 28e. According to Yeap et al. (2016), it has something to do with the spacer length [40]. As the length of spacer increase, the melting point continue to decrease from compounds 28e to 28f. Nonetheless, the clearing temperature of compound increase from compounds 28b to 28c and keep on descending as the length of alkyl chain increase. By reason, it may be due to the dilution of the mesogenic core, which causes the spacer to be flexible.
Compound 28f exhibits a smectic C phase, where it has been claimed that the formation of a smectic phase results from a side-by-side organization of azobenzene base peripheral units that are adjacent in parallel to each other. Many flexible spacers link all homologues of compound 28. This flexible spacer enables a conformational change so that a rod-shaped unit could align in a parallel arrangement resulting in a layered structure of a smectic phase [40].
Polymers 13 03462 i026
Comp28a28b28c28d28e28f
n5678910
R Polymers 13 03462 i027
Compounds 29(a–c) were synthesized by Sen et al. (2016) [41]. All of compounds 29(a–c) exhibit only one mesophase transition (Figure 6). Uncommonly for a rod-shaped molecule, the enthalpy values for the liquid crystalline phase of the isotropic liquid are higher than the enthalpy values of a solid–liquid crystalline phase. This unusual phenomenon may be due to the molecule’s arrangement within each layer, which the minimized steric forces have driven.
Polymers 13 03462 i028
Comp29a29b29c
n101218
RHHH
Jaworska et al. (2017) synthesized compounds 30(a–n) [42]. Out of 14 compounds with different homologues, he showed that two of them do not exhibit any liquid crystalline property. Compounds 30a and 30b do not possess any liquid crystal phase; by reason both compounds have high melting points compared to other homologues. Other compounds studied exhibit at least one enantiotropic mesophase, which was identified as a focal-conic textured smectic A. Compound 30c is the first homologue displaying smectic A and the width is 30.0 °C, as it can be seen in Figure 7. Starting from compound 30d until compound 30k, the width of the smectic A phase is broader, ranging from 40.0 to 75.0 °C. The smectic range keeps narrowing corresponding to increasing the alkoxy chain to n: 14 and above.
Polymers 13 03462 i029
Comp30a30b30c30d30e30f30g
n45678910
Comp30h30i30j30k30l30m30n
n45678910
All compounds 31(a–e) possess at least one liquid crystal phase except compound 31e, where it exhibits an extra liquid crystalline phase familiar as a smectic phase. This is a result of the length of the alkoxy chain in compound 31e is long enough to stabilize the lamellar molecular arrangement ideal for the molecule to display a smectic phase. The variation of the terminal group by the methylene spacer located in 1,4-disubstituted triazole derivatives, the molecular alignment of mesophase is stabilized [43]. Imine as a central unit causes the polarity to increase through retaining of linear patter. Minor changes in the alkyl chain may cause major changes in the transition temperature and types of mesophase formed.
Polymers 13 03462 i030
Comp31a31b31c31d31e
RC6H13C7H15C8H17C9H19C10H21
In the same year, two identical compounds, 32 and 33, were synthesized. The only difference between these two compounds is the central unit, where it exchanges place with the adjacent group. The melting point and the clearing point of compounds 32 and 33 are 104.8, 130.2, and 166.5, 162.2 °C, respectively. These temperature changes may be due to the length to diameter ratio, which eventually increases the transition temperature [44].
Polymers 13 03462 i031
Compound 32
Polymers 13 03462 i032
Compound 33
Each homologue of compounds 34(a–c) exhibit a different liquid crystal phase despite having similar compound. The formation of different mesophase within this compound is influenced by the substitution terminal (–R). Compound 33a contains an end non-polar methyl group, and it shows a nematic phase at 31.7 °C upon cooling. Compound 33b comprises a relatively polar chloro moiety, revealing a nematic phase about 3.0 °C above the isotropic liquid and a smectic A phase at 47.0 °C upon cooling. A polar nitro moiety is present in compound 33c, a long-range smectic A phase is observed at 106.3 °C in the cooling scan. The polarity of substituent not only affects the formation of different mesophase, but also caused the clearing temperature to change. The mesophase range increase as the polarity of substituent increase from 33a to 33c [45].
Polymers 13 03462 i033
Comp34a34b34c
RCH3ClNO2
Compounds 35(a–e) were synthesized in 2019 by Madiahlagan et al., and are a series of azo-coumarin compounds with different aliphatic chain lengths [46]. Lower homologues of compound 35 displayed a nematic phase at 120.0 °C for compound 35b, while compound 35e exhibited a broken fan-shaped smectic A at 170.0 °C upon cooling from the isotropic liquid. The difference in mesomorphic formation and the transition temperature is greatly influenced by the increasing carbon atom of the aliphatic substituent.
Polymers 13 03462 i034
Comp35a35b35c35d35e
RC6H13C8H17C10H21C12H25C14H29
The shortest terminal chain, compounds 36a and 36e, exhibited three liquid crystal phases which are nematic phase, smectic A phase, and smectic C phase, while compound 36c containing a butyl terminal chain exhibit a twist grain boundary smectic A (TGBA) rather than a smectic A itself and a smectic C phase. However, the broadest smectic S phase was observed to be of compound 36b. The TGBA phase does not present in 36b, and 36d is due to the odd-even effect. Compound 36i with the longest aliphatic group displayed a smectic A to smectic C mesophase transition with the temperature narrowed. It was affected by the elongation of the non-chiral alkyl chain, which eventually decreases the mesophase range.
As for compounds 37(a–i), the TGBA phase appeared in compound 37a and disappeared from compounds 37b to 37d and re-appear in compound 37e implying that a change has happened for compounds with the middle length alkyl chain. Further studies were done to identify the cause, however, further increase of the carboxylate group leads to a reduction of mesophase property [47].
Polymers 13 03462 i035
Comp36a36b36c36d36e36f36g36h36i
RC2H5C3H7C4H9C5H11C6H13C7H15C8H17C10H21C12H25
Polymers 13 03462 i036
Comp37a37b37c37d37e37f37g37h37i
RC2H5C3H7C4H9C5H11C6H13C7H15C8H17C10H21C12H25
In the following year, compounds 38(a–e) and 39(a–e) were synthesized, where all compounds studied exhibit a liquid crystalline property. Within compound 38 and all higher homologues were observed to be enantiotropic except compounds 38a, and 38b, while compounds 39a and 39d are enantiotropic in nature. Compounds 38b and 38c display an enantiotropic smectic B1 phase, while compound 38d exhibits an enantiotropic smectic B1 phase and an addition of a monotropic smectic B2 phase. Theoretically, a change in the alkyl chain will cause the mesophase property to be varied, and the formation of smectic B proves the point [48].
Polymers 13 03462 i037
Comp38a38b38c38d38e
RC4H9C6H13C8H17C10H21C12H25
Comp39a39b39c39d39e
ROC4H9OC6H13OC8H17OC10H21OC12H25
Sardon et al. (2021) synthesized compounds 40(a–d) and compared them with a compound studied back in 2016 by Karim et al., labeled as compounds 41(b–c) [49,50]. The result of this observation is illustrated in Table 1.
Based on Table 1, it can be observed that the mesophase stability is inconsistent. This inconsistency is caused by the substituent (–H, –Cl, –Br, –CN). However, the nematic mesophase range of compounds 40(b–d) are wider. The substitution of hydrogen atom on the para-position of benzene ring affects the polarizability of mesogens that aid the formation of the liquid crystal phase. Compound 40d presented the highest nematic to isotropic clearing transition temperature because of higher polarization effects caused by the cyano substitution that gives high temperature to break the association within the molecule.
Compounds 40b and 40c only reveal the formation of a nematic phase, while compounds 41b and 41c displayed both nematic and smectic A phases. The methyl side chain substituent in compounds 40b and 40c truncate the melting and clearing temperature compared to compounds 41b and 41c that possess no methyl side chain. Generally, any lateral group attached to the core unit of a compound may cause some changes in the mesomorphic behavior. The presence of methyl side-chain group widens the core unit where the intermolecular separation is eventually increased and leads to lower mesophase stability.
Polymers 13 03462 i038
Comp40a40b40c40d
RHClBrCN
Polymers 13 03462 i039
Comp41a41b
RClBr

3. Application

In this era, everyone uses at least one liquid crystal in their daily life. Over the years, the use of electronic devices has increased to meet the demand of easing our lives. The most common liquid crystal used is the liquid crystal display (LCD) that is present on our mobile phones, computers, laptops, and many more [51,52]. LCD is an electronic display device with a flat panel that uses a liquid crystal as its main operation medium [53]. An LCD possess both nematic and smectic phase. However, a smectic LCD is more demanded compared to the nematic LCD as the response is faster. The display on an LCD is not emitted by the liquid crystal, instead of liquid crystal acts as a reflector that produces the image in either monochrome or in color [27].
Another application is the liquid crystal thermometer. As informed, a thermometer detects the temperature of something. Liquid crystal is applied to this system so that when it detects any temperature, a specific color persists. Recalling from a study by Kitzerow and Bahr (2001), a chiral nematic liquid crystal reflects light of a wavelength of the same length of the pitch [16]. As the pitch is temperature-dependent, the color that is reflected is also temperature-dependent. This set-up is applied to various applications, such as the mood ring that has recently gone viral, where the ring will conjure different color according to our body temperature. In addition to that, this application is ideal for use in the medical area where it can detect different temperature distributions on a tumor patient as the tumor, and its surrounding tissues develop different temperatures [14].

4. Conclusions

There are several factors observed that might influence the formation of a different liquid crystal phase. The most common factor that can be scrutinized in most studies conducted by most authors is the increase in the alkyl terminal chain. These factors may have several consequences, which are the main influences on mesophase development. The effects of the increase in the terminal alkyl chain are that it regulates the increase in molecular length-to-breadth, amplifies the entropy chain, enhances thermal stability, and diminishes the clearing temperature. Moreover, the azo linking unit increase the linearity of the molecule and this characteristic able to induce the mesophase transition.

Author Contributions

Conceptualization, N.A.R. and Z.J.; validation, N.A.R. and Z.J.; formal analysis, N.A.R.; investigation, N.A.R.; data curation, N.A.R. and Z.J.; writing—original draft preparation, N.A.R. and Z.J.; writing—review and editing, N.A.R. and Z.J.; visualization, N.A.R.; supervision, Z.J.; project administration, Z.J.; funding acquisition, Z.J. Both authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by Universiti Malaysia Sabah (UMS), grant number SBK0488-2021 and The APC was funded by Universiti Malaysia Sabah (UMS).

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Acknowledgments

The authors would like to thanks Universiti Malaysia Sabah (UMS) for the technical and financial support.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Jamain, Z.; Habil, S.; Makmud, M.Z.H.; Khairuddean, M. Synthesis, structural and dielectric characteristics of liquid crystalline azo-based compounds with different terminal length. In Proceedings of the 2021 IEEE International Conference on the Properties and Applications of Dielectric Materials (ICPADM), Johor Bahru, Malaysia, 12–14 July 2021; pp. 49–52. [Google Scholar]
  2. Jamain, Z.; Khairuddean, M.; Loh, M.L.; Manaff, N.L.A.; Makmud, M.Z.H. Synthesis and characterization of hexasubstituted cyclotriphosphazene derivatives with azo linking units. Malays. J. Chem. 2020, 22, 125–140. [Google Scholar]
  3. Benkhaya, S.; Rabet, S.M.; Harfi, A.E. A review on classifications, recent synthesis and applications of textile dyes. Inorg. Chem. Commun. 2020, 115, 107891. [Google Scholar] [CrossRef]
  4. Selvaraj, V.; Karthika, T.S.; Mansiya, C.; Alagar, M. An over review on recently developed techniques, mechanisms and intermediate involved in the advanced azo dye degradation for industrial applications. J. Mol. Struct. 2021, 1224, 129195. [Google Scholar] [CrossRef]
  5. Kyei, S.K.; Akaranta, O.; Darko, G. Synthesis, characterization and antimicrobial activity of peanut skin extract-azo-compounds. Sci. Afr. 2020, 8, e00406. [Google Scholar] [CrossRef]
  6. Jamain, Z.; Khairuddean, M.; Guan-Seng, T.; Rahman, A.B.A. Synthesis, characterization and mesophase transition of hexasubstituted cyclotriphosphazene molecules with Schiff base and azo linking units and determination of their fire retardant properties. Macromol. Res. 2021, 29, 331–341. [Google Scholar] [CrossRef]
  7. Brightman, R. Dictionary of Chemistry in Nature; Mc-Graw Hill: New York, NY, USA, 1954; pp. 219–376. [Google Scholar]
  8. Stegemeyer, H. Centenary of the discovery of liquid crystals. Liq. Cryst. 1989, 5, 5–6. [Google Scholar] [CrossRef]
  9. Lejcek, L.; Glogarova, M.; Tesinska, E. Commemorative plaque of Prof. Friedrich Reinitzer installed in Prague. Liq. Cryst. Today 2017, 26, 66–68. [Google Scholar] [CrossRef]
  10. Yildiz, S.; Cetinkaya, M.C.; Ozbek, H.; Tzitzios, V.; Nounesis, G. High-resolution birefringence investigation on the effect of surface-functionalized CdSe nanoparticles on the phase transitions of a smectic—A liquid crystal. J. Mol. Liq. 2020, 298, 112029. [Google Scholar] [CrossRef]
  11. Carlescu, I. Introductory Chapter: Liquid Crystals. In Liquid Crystals—Self-Organized Soft Functional Materials for Advanced Applications; IntechOpen: Bucharest, Romania, 2018. [Google Scholar]
  12. Andrienko, D. Introduction to liquid crystals. J. Mol. Liq. 2018, 267, 520–541. [Google Scholar] [CrossRef]
  13. Kusabayashi, S.; Takenaka, S. Structure and Properties of Liquid Crystals. J. Syn. Org. Chem. 1984, 42, 2–12. [Google Scholar] [CrossRef]
  14. Lehn, J.M. Supramolecular Chemistry; Wiley-VCH: Weinheim, Germany, 1995; pp. 177–219. [Google Scholar]
  15. Collings, T.D.; Hird, M. Introduction to Liquid Crystal; Taylor & Francis: London, UK, 1997. [Google Scholar]
  16. Kitzerow, H.S.; Bahr, C. Chirality in Liquid Crystals; Springer: Berlin/Heidelberg, Germany, 2001. [Google Scholar]
  17. Goodby, J.W. Materials and Phase Structure of Calamatic and Discotic Liquid Crystals; Springer: Cham, Switzerland, 2016. [Google Scholar]
  18. Safinya, C.R.; Varady, W.A. Calamitic liquid crystals-nematic and smectic mesophases. Liq. Cryst. 1986, 57, 43–77. [Google Scholar]
  19. Parra, M.; Villouta, S.; Vera, V.; Belmar, J.; Zúñiga, C.; Zunza, H. Synthesis and mesomorphic properties of azo compounds derived from phenyl- and thienyl-1,3,4-thiadiazole. Z. Fur. Naturforsch.-B J. Chem. Sci. 1997, 52, 1533–1538. [Google Scholar] [CrossRef]
  20. Belmar, J.; Parra, M.; Zuniga, C.; Perez, C.; Munoz, C. New liquid crystals containing the benzothiazol unit: Amides and azo compounds. Liq. Cryst. 1999, 26, 389–396. [Google Scholar] [CrossRef]
  21. Lee, M.J.; Yoo, B.W.; Shin, S.T.; Keum, S.R. Synthesis and properties of new liquid crystalline compounds containing an indolinobenzospiropyranylazo group. Dyes Pigm. 2001, 51, 15–24. [Google Scholar] [CrossRef]
  22. Parra, M.; Alderete, J.; Zuñiga, C.; Gallardo, H.; Hidalgo, P.; Vergara, J.; Hernandez, S. Azo compounds and Schiff’s bases derived from 5-(4-pyridyl)-2-amino-1,3,4-thiadiazole: Synthesis, mesomorphic properties and structural study by semi-empirical calculations. Liq. Cryst. 2001, 28, 1659–1666. [Google Scholar] [CrossRef]
  23. So, B.K.; Jang, M.C.; Park, J.H.; Lee, K.S.; Song, H.H.; Lee, S.M. Novel bent-shaped liquid crystalline compounds: 1. Synthesis and structure analysis of dimesogenic compounds with azo units. Opt. Mater. 2003, 21, 685–689. [Google Scholar] [CrossRef]
  24. Abbasi, A.R.; Rezvani, Z.; Nejati, K. Synthesis and properties of new liquid crystalline compounds containing an alkoxyphenylazo group. Dyes Pigm. 2006, 70, 71–75. [Google Scholar] [CrossRef]
  25. Rezvani, Z.; Divband, B.; Abbasi, A.R.; Nejati, K. Liquid crystalline properties of copper (II) complexes derived from azo-containing salicylaldimine ligands. Polyhedron 2006, 25, 1915–1920. [Google Scholar] [CrossRef]
  26. So, B.K.; Kim, H.J.; Lee, S.M.; Song, H.H.; Park, J.H. Novel bent-shaped liquid crystalline compounds: IV. Dimesogenic compounds containing 2-hydroxy-1,3-dioxypropylene and azobenzene mesogens. Dyes Pigm. 2006, 70, 38–42. [Google Scholar] [CrossRef]
  27. Dunmur, D.; Walton, H.G. “Liquid Crystal Display”. Encyclopedia Britannica, 3 August 2015. Available online: https://www.britannica.com/technology/liquid-crystal-display (accessed on 10 August 2021).
  28. Lutfor, M.R.; Hegde, G.; Kumar, S.; Tschierske, C.; Chigrinov, V.G. Synthesis and characterization of bent-shaped azobenzene monomers: Guest-host effects in liquid crystals with azo dyes for optical image storage devices. Opt. Mater. 2009, 32, 176–183. [Google Scholar] [CrossRef]
  29. Al-hamdani, U.J.; Gassim, T.E.; Radhy, H.H. Synthesis and Characterization of Azo Compounds and Study of the Effect of Substituents on Their Liquid Crystalline Behavior. Molecules 2010, 15, 5620–5628. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  30. Yeap, G.Y.; Heng, B.T.; Kakeya, M.; Takeuchi, D.; Gorecka, E.; Ito, M.M. Synthesis, 2D NMR and X-ray diffraction studies on Cu(II) and Ni(II) complexes with ligands derived from azobenzene-cored Schiff base: Mesomorphic behaviors of Cu(II)-phenolates and crystal structure of bis [4-(4-alkoxy-2-hydroxybenzylideneamino)azobenzen. J. Mol. Struct. 2011, 999, 68–82. [Google Scholar] [CrossRef]
  31. Reddy, K.P.; Brown, T.L. Synthesis and thermal behaviour of mesomorphic Cu(II) Schiff’s base complexes. J. Mater. Chem. 1991, 1, 757–764. [Google Scholar] [CrossRef]
  32. Yang, P.C.; Li, C.Y.; Wu, H.; Chiang, J.C. Synthesis and mesomorphic properties of photoresponsive azobenzene-containing chromophores with various terminal groups. J. Taiwan Inst. Chem. Eng. 2012, 43, 480–490. [Google Scholar] [CrossRef]
  33. Debnath, S.; Mohiuddin, G.; Turlapati, S.; Begum, N.; Sarkar, D.D.; Rao, V.S.N. Nematic phases in achiral unsymmetrical four-ring bent-core azo compounds possessing strongly polar cyano and nitro moieties as end substituents: Synthesis and characterization. Dyes Pigm. 2013, 99, 447–455. [Google Scholar] [CrossRef]
  34. Karim, R.; Salleh, N.M.; Yahya, R.; Hassan, A.; Hoque, A. Synthesis and characterization of azo benzothiazole chromophore based liquid crystal macromers: Effects of substituents on benzothiazole ring and terminal group on mesomorphic, thermal and optical properties. Mater. Chem. Phys. 2013, 140, 543–552. [Google Scholar] [CrossRef]
  35. Rahman, M.L.; Biswas, T.K.; Sarkar, S.M.; Yusoff, M.M.; Yuvaraj, A.R.; Kumar, S. Synthesis of new liquid crystals embedded gold nanoparticles for photoswitching properties. J. Colloid Interface Sci. 2016, 478, 384–393. [Google Scholar] [CrossRef] [Green Version]
  36. Paul, M.K.; Kalita, G.; Laskar, A.R.; Debnath, S.; Gude, V.; Sarkar, D.D.; Mohiuddin, G.; Varshney, S.K.; Nandiraju, R.V.S. Synthesis and mesomorphic behaviour of achiral four-ring unsymmetrical bent-core liquid crystals: Nematic phases. J. Mol. Struct. 2013, 1049, 78–89. [Google Scholar] [CrossRef]
  37. Srinivasa, H.T.; Hariprasad, S. 4-[2-(Trimethylsilyl)ethynyl]benzoates: Synthesis and evaluation for mesomorphic properties of some novel calamitic molecules. J. Organomet. Chem. 2014, 774, 19–25. [Google Scholar] [CrossRef]
  38. Selvarasu, C.; Kannan, P. Synthesis, characterization of azobenzene and cinnamate ester based calamitic liquid crystalline compounds and their photoresponsive properties. J. Mol. Struct. 2015, 1092, 176–186. [Google Scholar] [CrossRef]
  39. Selvarasu, C.; Kannan, P. Effect of azo and ester linkages on rod shaped Schiff base liquid crystals and their photophysical investigations. J. Mol. Struct. 2016, 1125, 234–240. [Google Scholar] [CrossRef]
  40. Yeap, G.; Abdul, M.; Lin, C.; Lin, H.; Maeta, N.; Ito, M.M. Synthesis and liquid crystalline studies of disc-shaped molecule on azo-bridged benzothiazole-phenyl ethers. J. Mol. Liq. 2016, 223, 734–740. [Google Scholar] [CrossRef]
  41. Sen, C.; Mallick, D.; Patra, C.; Roy, S.; Sinha, R.K.; Ghosh, R.; Mondal, J.A.; Palit, D.K.; Sinha, C. Spectroscopic characterization, photochromism and mesomorphism of cadmium(II)-1-alkyl-2-(arylazo)imidazole complexes and DFT correlative studies. Polyhedron 2016, 117, 463–477. [Google Scholar] [CrossRef]
  42. Jaworska, J.; Korbecka, I.; Kochel, A.; Galewski, Z. 4-(4′-Alkyloxyphenylazo)benzoyl chlorides not only intermediates but photosensitive mesogens for optical switching. J. Mol. Liq. 2017, 225, 877–882. [Google Scholar] [CrossRef]
  43. Boopathi, T.S.; Senthil, S. Synthesis and characterization of heterocyclic nonlinear mesogen. Mater. Today Proc. 2018, 5, 16172–16180. [Google Scholar] [CrossRef]
  44. Luo, C.C.; Sun, S.L.; Wang, Y.S.; Meng, F.B.; Hu, J.S.; Jia, Y.G. The effect of various functional groups on mesophase behavior and optical property of blue phase liquid crystal compounds based on (−) menthol. J. Mol. Liq. 2018, 269, 755–765. [Google Scholar] [CrossRef]
  45. Patranabish, S.; Mohiuddin, G.; Begum, N.; Laskar, A.R.; Pal, S.K.; Rao, N.V.S.; Sinha, A. Cybotactic nematic phase of achiral unsymmetrical bent-core liquid crystals—Quelling of polar ordering and the influence of terminal substituent moiety. J. Mol. Liq. 2018, 257, 144–154. [Google Scholar] [CrossRef]
  46. Madiahlagan, E.; Sunil, B.N.; Ngaini, Z.; Hegde, G. Synthesis, liquid crystalline properties and photo switching properties of coumarin-azo bearing aliphatic chains: Application in optical storage devices. J. Mol. Liq. 2019, 292, 111328. [Google Scholar] [CrossRef]
  47. Poryvai, A.; Bubnov, A.; Pociecha, D.; Svoboda, J.; Kohout, M. The effect of the length of terminal n-alkyl carboxylate chain on self-assembling and photosensitive properties of chiral lactic acid derivatives. J. Mol. Liq. 2019, 275, 829–838. [Google Scholar] [CrossRef]
  48. Hegde, R.S.; Sunil, B.N.; Hegde, G.; Prasad, V. Influence of alkyl and alkoxy groups on photoresponsive behaviour of bent-core azo mesogens: Synthesis, mesomorphic and photoswitching properties. J. Mol. Liq. 2020, 309, 113091. [Google Scholar] [CrossRef]
  49. Karim, M.R.; Sheikh, M.R.K.; Yahya, R.; Mohamad, S.N.; Lo, K.M.; Mahmud, H.N.M.E. The effect of terminal substituents on crystal structure, mesophase behaviour and optical property of azo ester linked materials. Liq. Cryst. 2016, 43, 1862–1874. [Google Scholar] [CrossRef]
  50. Sardon, S.N.F.; Rahman, N.M.M.A.; Karim, M.R.; Zahid, N.I.; Salleh, N.M. Effects of lateral methyl and terminal substituents on thermal, mesomorphic and optical properties of azo ester mesogens. J. Mol. Struct. 2021, 1225, 129112. [Google Scholar] [CrossRef]
  51. Jamain, Z.; Khairuddean, M.; Guan-Seng, T. Synthesis of new star-shaped liquid crystalline cyclotriphosphazene derivatives with fire retardancy bearing amide-azo and azo-azo linking units. Int. J. Mol. Sci. 2020, 21, 4267. [Google Scholar] [CrossRef] [PubMed]
  52. Jamain, Z.; Faizawani, N.; Khairuddean, M. Synthesis and determination of thermotropic liquid crystalline behaviour of cinnamaldehyde-based molecules with two Schiff base linking units. Molecules 2020, 25, 3780. [Google Scholar] [CrossRef] [PubMed]
  53. Smith, C. A review of liquid crystal display technologies, electronic interconnection and failure analysis. Circuit World 2008, 34, 35–41. [Google Scholar] [CrossRef]
Figure 1. Polarizing optical micrographs upon cooling of isotropic liquid of compound 8c at 168.0 °C [23].
Figure 1. Polarizing optical micrographs upon cooling of isotropic liquid of compound 8c at 168.0 °C [23].
Polymers 13 03462 g001
Figure 2. Optical texture of compound 11a at 210.0 °C [25].
Figure 2. Optical texture of compound 11a at 210.0 °C [25].
Polymers 13 03462 g002
Figure 3. (a) Schlieren textured smectic C of compound 12b at 160.0 °C, and (b) Schlieren textured smectic C of compound 12c at 160.2 °C [26].
Figure 3. (a) Schlieren textured smectic C of compound 12b at 160.0 °C, and (b) Schlieren textured smectic C of compound 12c at 160.2 °C [26].
Polymers 13 03462 g003
Figure 4. Optical micrograph of (a) compound 13a at 164.0 °C, (b) compound 13b at 130.0 °C, (c) compound 13d at 129.0 °C, and (d) compound 13e at 134.0 °C [28].
Figure 4. Optical micrograph of (a) compound 13a at 164.0 °C, (b) compound 13b at 130.0 °C, (c) compound 13d at 129.0 °C, and (d) compound 13e at 134.0 °C [28].
Polymers 13 03462 g004
Figure 5. (a) Early-stage smectic A compound 25a at 185 °C, and (b) fully grown smectic A phase of compound 25b at 100.0 °C [37].
Figure 5. (a) Early-stage smectic A compound 25a at 185 °C, and (b) fully grown smectic A phase of compound 25b at 100.0 °C [37].
Polymers 13 03462 g005
Figure 6. Polarizing micrograph ring-like texture of (a) compound 29a at 123.0 °C, (b) compound 29b at 191.0 °C, and (c) cone-like texture of hexatic phase of compound 29c at 123.0 °C [41].
Figure 6. Polarizing micrograph ring-like texture of (a) compound 29a at 123.0 °C, (b) compound 29b at 191.0 °C, and (c) cone-like texture of hexatic phase of compound 29c at 123.0 °C [41].
Polymers 13 03462 g006
Figure 7. Focal-conic textured smectic A liquid crystalline phase present in compound 30c [42].
Figure 7. Focal-conic textured smectic A liquid crystalline phase present in compound 30c [42].
Polymers 13 03462 g007
Table 1. Phase transition temperature and enthalpy changes of 40(a–d) and 41(b–c).
Table 1. Phase transition temperature and enthalpy changes of 40(a–d) and 41(b–c).
CompoundScanTransition Temperature (°C)
(Enthalpy Changes (kJ mol−1))
Mesophase Range (°C)
SmAN
40aHeatCr1 61 (4.5) Cr2 88 (16.1) N 98 (3.7)-10
CoolI 57 (−0.4) N 18 (−3.8) Cr
40bHeatCr 108 (34.6) N 140 (0.5) I-32
CoolI 138 (−0.3) N 73 (−33.3) Cr
40cHeatCr1 93 (0.9) Cr2 115 (31.8) N 136 (0.5) I-21
CoolI 134 (−0.4) N 33 (−15.7) Cr
40dHeatCr 127 (58.4) N 159 (0.9) I-32
CoolI 156 (−1.2) N 74 (−49.3) Cr
41bHeatCr 116 (33.1) SmA 185 (0.9) N 203 (0.3) I6918
CoolI 197 (−0.3) N 173 (−0.5) SmA 101 (−15.7)
41cHeatCr 124 (15.7) SmA 192 (1.1) N 204 (0.3) I6812
CoolI 192 (−0.2) N 174 (−0.3) SmA 112 (−13.0)
Abbreviations: Cr = crystalline phase; SmA = smectic A phase; N = nematic phase; I = isotropic phase.
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

Razali, N.A.; Jamain, Z. Liquid Crystals Investigation Behavior on Azo-Based Compounds: A Review. Polymers 2021, 13, 3462. https://doi.org/10.3390/polym13203462

AMA Style

Razali NA, Jamain Z. Liquid Crystals Investigation Behavior on Azo-Based Compounds: A Review. Polymers. 2021; 13(20):3462. https://doi.org/10.3390/polym13203462

Chicago/Turabian Style

Razali, Nurul Asma, and Zuhair Jamain. 2021. "Liquid Crystals Investigation Behavior on Azo-Based Compounds: A Review" Polymers 13, no. 20: 3462. https://doi.org/10.3390/polym13203462

APA Style

Razali, N. A., & Jamain, Z. (2021). Liquid Crystals Investigation Behavior on Azo-Based Compounds: A Review. Polymers, 13(20), 3462. https://doi.org/10.3390/polym13203462

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop