Tellurophenes

Cross-coupling

Halide-substituted tellurophenes participate in metal-catalyzed cross coupling reactions.^[8][11] Perfluoroaryl-substituted tellurophenes form by Stille coupling.^[11]

Metal-catalyzed cross-couplings to synthesize 3-functionalized tellurophenes require 3-bromo- or 3-iodo-tellurophenes, the syntheses of which could be complicated.^[6][7]

Lewis acidity

Bistellurophenes form complexes with halides, demonstrating their Lewis acid character. The binding of chloride to 2,5-bis[(perfluoro)aryl]tellurophene has an association constant (K_a) of 310 ± 20 L mol⁻¹.^[11]

Redox

Tellurophenes undergo oxidative addition of halogens to give Te(IV) derivatives. The reaction is reversed with UV-radiation.^[13][12] Tellurophene can be oxidized with hydrogen peroxide to give the oxide:

The oxidative ring opening of 2,5-diphenyltellurophene (PT) with meta-chloroperoxybenzoic acid (mCPBA).^[15]

Polymers

Poly-3-alkyltellurophenes (P3ATe) can be obtained through catalyst transfer polymerization (CTP).^[16][17] CTP is an important route to synthesize polymers with a narrow molecular weight distribution and a well defined end-group,^[18] but it was found in 2013 that applying CTP-conditions for the synthesis of P3ATe led to polymers with low molecular weights, and broad polydispersities. To obtain P3ATe with a narrow polydispersity, the authors investigated the optimal conditions using kinetic studies and DFT calculations. It was found experimentally that the branched side chain played an important role on the polymerization rate and polymer quality. To mitigate this effect, monomers with various other side chains were synthesized. From this, it was found that moving the ethyl branches away from the heterocycle to the more remote 3- and 4- positions led to an improved polymerization rate and control, such that P3ATe with narrow polydispersities and high molecular weights were obtained. This improvement was attributed to the lack of steric hindrance. Furthermore, it was found that upon moving the branching point away from the heterocycle led to a red-shift in the optical absorption, which was attributed to a decrease in the degree of twisting, resulting in an increase in the conjugation between the tellurophene backbone.

Tellurophene-vinylene copolymer can be obtained through Stille coupling of 2,5-dibromo-3-dodecyltellurophene and (E)-1,2-bis(tributylstannyl)ethylene, resulting in P3TeV in 57% yield with an approximate M_n of 10 kDa and a polydispersity of 2.4.^[19] By synthesizing thiophene and selenophene analogues, it was found that there was a reduction in the optical band gap as a result of the stabilization of the LUMO, resulting in a small band gap of 1.4 eV for P3TeV. By constructing organic field effect transistors (OFETs), it was found that the selenophene polymer had the highest charge mobility, and that the tellurium analogue did not lead to an increase in mobility despite the larger size of tellurium, and possibility of closer interchain Te-Te interactions, which was attributed to the low solubility of P3TeV which resulted in poor film formation. Therefore, the authors remarked that future work entailed modifying the side-chains to increase solubility.

Optoelectronic properties

The optical properties of tellurophenes have been reported.^[20] In 2014, Rivard et al. reported the phosphorescence of pinacolboronate-substituted tellurophenes at room temperature,^[21] Phosphorescence was found to be aggregation-induced, as the tellurophene was non-emissive when dissolved in THF solution. ^[22][23]

Compared to thiophenes, tellurophenes have lower optical band gaps, significantly lower LUMO levels, and higher charge carrier mobilities. This was in contrast to the sulfur and selenium analogues, where the triplet state was found to be ~1 eV higher in energy.