Electropolymerizable Conjugated Polymers with High Contrast in Infrared Region

Two conjugated molecules have been designed and synthesized for preparing electrochromic thin film devices on the surface of electrodes through electropolymerization. These devices exhibit good contrast at around 80% in mid-infrared region and rapid response time, especially EP02 which could be switched between on and off state in around 1 s. The interesting electrochromic properties and easy processable properties open the door to electrochromic applications using large or flexible surfaces such as IR shutters and apertures.

Advanced materials capable of large, dynamic (swit chable, controllable) variation of infrared (IR) signature have been intensely sought recently for two urgent applications: 1) As infrared camouflage countermeasures against night vision sensors for all armed forces components (land/sea vehicles, aircraft, soldiers) [19]; 2) For optical information technology, to replace bulky, costly mechanical shutter and filter in infrared detection and imaging [20].While conducting polymers [21,22] have shown some intrinsic variation of mid-to far-IR signature, the practical utilization of this has remained elusive.
In the earlier work, Dan et al. have synthesized and used of a series of conjugated polymers with different functional groups which have enabled further exploration in the relationship between electrochromic properties and chemical structures [23].These polymers contain ethylenedioxythiophene (EDOT) units, which provide exceptional stability in the oxidation state and combined with a low energy requirement for oxidation.Fluorene and Carbazole are introduced into the polymer chains to improve ECDs' performance through the adjustment of spacing between the polymer chains to facilitate ion injection [24].The introduction of the acceptor unit benzothiadiazole (BT) and its derivations was used to decrease the lowest unoccupied molecular orbital (LUMO) level and narrow the band gap, thereby extending absorbance to longer wavelengths.
Herein, we prepare electrochromic thin film devices in the solid state, which are fabricated through electropolymerization in solutions from donor-acceptor-donor narrow band gap monomers.Compared with spin-coated samples [23], these electrodeposited products are easy patterned and fabricated to highly scalable, uniform and homogeneous thin films.Most importantly, the devices based on these films can be switched reversibly between the doped and de-doped states with rapid response times and high contrast in IR, which are promising to be prac-tically used on fabrication of large and flexible devices.

Experiment Section
All reagents are purchased from commercial sources and used without further purification, unless otherwise noted.The solvents are distilled and dried using known methods [25].All reactions are carried in air atmosphere unless otherwise mentioned.The following acceptor and donor blocks were prepared according to literature procedures: 4,7-dibromo-2,1,3-benzothiodiazole (DB-BT), [26] tributyl (2,3-dihydrothieno [3,4- [29].ITO/glass electrodes are obtained from Delta Technologies, Ltd., and rinsed successively with distilled water, acetone and isopropanol before use.

Electrochemical Polymerization
Electrochemical studies were carried out with a CHI 600D electrochemical workstation, using an indium tin oxide (ITO)-coated glass slide as the working electrode (25 × 15 × 0.8 mm, R S = 70 -100 Ω), a gold flag as the counter electrode, and an AgCl coated Ag wire, which was directly dipped in the electrolyte solution, as the reference electrode.The E 1/2 = (E pa + E pc )/2 of the Copyright © 2012 SciRes.OJPChem Fc/Fc + couple is 0.26 V vs Ag/AgCl under these conditions.
The polymer films of EP01 and EP02 (polymerized from monomer 1 and 2, respectively) are deposited on ITO-coated glass substrates by cycled scanning at a scan rate of 250 mV/s from -0.2 to 1.2 V vs Ag/Ag + from a 0.01 M monomer solution in 0.1 M TBAPF 6 / acetonitrile, which are bubbled with nitrogen before use to remove any incipient oxygen.Several drops of Dichloromethane are required to dissolve the monomers and then CH 3 CN is added to get the solution in certain concentration.However, too much CH 2 Cl 2 hindered polymer formation and deposition on the electrode and only the use of monomer saturated solution helped to circumvent that problem.
The repeated scanning electropolymerizations of monomer 1 and of 2 are shown in Figure 1, respectively.During the first anodic scan, a single peak is observed which corresponds to irreversible monomer oxidation and formation of cation radicals.The oxidation of monomer 1 (E p,m ) is starting at +1.06 V, and at 1.02 V for monomer 2. With repeated potential scanning, polymers EP01 and EP02 films grow onto the electrode surface in succession.The oxidation potentials of the polymer also increase with film thickness due to the increase in polymer resistance.
The polymer films formed on the electrode are rinsed with a monomer-free solution of CH 3 CN in which films are not soluble, and cyclic voltammograms are further recorded with scan rate values of 250 mV/s.The E p,ox and Ep, red of the EP01 and EP02 system are highly separated as the longer and bulkier chains on the periphery inhibit the fast movement of counter ions.The peak oxidation (E p,ox ) potentials of EP01is around +0.41 V at 250 mV•s -1 .However, E p,ox for EP02 is +0.75 V at 250 mV•s -1 ).The lower (E p,ox ) potentials of EP01 than that of EP02 reveals the weaker effect of the electron accepting capability of the benzo [c] [1,2,5] thiadiazole unit on the polymer oxidation process than that of quinoxaline [30].

Optoelectrochemical Analyses
For assembling electrochromic cells, a quasisolid or viscous gel electrolyte base prepare from an acetonitrile solution of poly(methyl methacrylate) (PMMA), propylene carbonate and ethylene carbonate in weight ratios of 1:0.1:0.4:0.4,and then tetrabutyl ammonium tetrafluoroborate TBABF 4 is added in a 0.9 M concentration relative to the solution.30 times cycled scanning at a scan rate of 250 mV/s from -0.2 to 1.2 V are enforced to reach 220 nm thin films.Before examining the optical properties of polymer films, they are rinsed with acetonetrile twice before devices fabrication and then place in a vacuum oven at 80˚centigrade overnight.And followed by spin-coating a gel electrolyte on two separate ITO/ glass substrates, the coated surfaces were manually sandwiched together and sealed with epoxy.The electrochromic devices were placed to dry at room temperature overnight.UV-Vis-NIR spectra are recorded on a V -570 Jasco UV-Vis-NIR spectrophotometer.
The in situ spectroelectrochemistry is performed by holding the film at the desired potential and measuring the absorbance from 400 nm to 2500 nm with applied potentials at 0 V and 2.5 V vs Fc/Fc + for p-doping.The polymer switches from a dark teal-green in the neutral state to a slate-blue in the oxidized state.As shown in Figure 2, the polymer EP01 and EP02 have the analogous absorbance bands in the visible region at around 550 nm, characteristic of donor-acceptor systems.A window of transmission is centered on 500 nm and gives the polymer a green color as the green light is not absorbed and is allowed to pass through the film.As the polymers are oxidized, depletion of both of these transitions occurs with a decrease in the absorbances at 550 nm and 400 nm.For polymer EP01, the doping-induced infrared absorption bands centered at 900 nm and a broad absorbance beginning at 1200 nm and extending into the mid-IR corresponding to 2.5 V bias.The electrochromic property of EP02 is slightly different when device is turned on.The doping-induced absorbance at around 1000 nm and a broad absorbance beginning at 1500 nm and also extending into the mid-IR, which is due to the narrower band gap of origin materials.
While ITO/glass electrodes are sufficiently transparent in the visible region, their transmission window drops off substantially at longer wavelengths, as shown in Figure 2. The ITO/glass utilized in this study has a transmittance value of 85% at 1500 nm, reduced to 72% at 2500 nm, the limiting wavelength for solution-based spectraelectrochemistry.In Figure 3, the normalized absorbance of both polymers with the elimination of glass/ITO absorbance revealed that both devices have the maximum con-trast is 85%, almost in the whole mid-IR region have around 80% contrast.Especially EP02, the absorption curved is more flat and smooth, which meet the practically application requirement well.However, for applying in IR region, an electrode material with higher nearto mid-IR transparency is required in the future.

Electrochromic Switching Studies
Electrochromic switching studies are carried out to monitor absorbance changes with time during repeated potential stepping between reduced and oxidized states to obtain an insight into changes in the optical contrast.In an initial experiment illustrate in Figure 4, the EP01 and EP02 devices are switched by stepping the potential between -2.5 and +2.5 V with a switching interval of 10 s while monitoring the absorbance at 900 nm and 1000 nm, respectively.The polymer film repeatedly and reproducibly change from a dark blue absorptive reduced state at -2.5 V to a light gray transmission oxidized state at +2.5 V with a higher transmission.By examination of one of the double potential switches of EP01 and EP02, device based on EP01 need around 4 s to turn on device to reach 80% of total transformation and 2 s to turn device off.Meanwhile, the device based on EP02 switch much faster, which the reduction is completed in ca.0.8 s, reoxidation requires around 1.5 s.It can be seen that in both cases the reductive processes proceed somewhat more rapidly than the oxidation processes.The rapidity of the reduction can be attributed to the ease of transport through the polymer film to the electrode contact.Reoxidation of the neutral film initiates at the insulating polymer-electrode interface, and a conducting front propagates through the film's thickness.For EP01, the longer alkyl-substitution on polymer back bone lead to a larger inter-chain distance, which will block the transport from film to electrode.As the result, the conductivity of oxidized polymer EP01 films is lower than that of EP02 and result in a slower turn off speed.Moreover, as the subunit of EP02, the ProDOT (3,4-propylenedioxythiophene), which have cyclic substitutions propylenedioxy, could separate polymer back bone and afford a suitable space for ion injection and accelerate the oxidation process.[31]

Conclusion
We have prepared two donor-acceptor-donor structured monomers containing extended conjugation systems in good yields which are easily electrochemically polymerized to yield stable and uniform electroactive films.The devices in solid state based on the two polymers show good contrast and rapid responds, which are as high as 80% in mid-IR region and the switching speed of EP02 is around 1s which is faster than that of EP01.The reason would be the substitutions on EP02 afford suitable size for ion injection, which could accelerate polymer doping.And the side chains on EP02 are shorter than that of EP01, which attributed to reasonable conductivity to ease transport through the polymer film to the electrode.These interesting solubility and easy processability properties open the door to electrochromic applications on large or flexible surfaces such as IR shutters and apertures.

Figure 2 .
Figure 2. Electrochromic properties of devices based on (a) EP01 and (b) EP02 at 2.5 V and 0 V.