for this application. [1][2][3][4][5][6] Recently, however, new classes of materials are being investigated for hydrogen evolution from water, such as nitrogen doped graphene oxide, [7] covalent organic frameworks, [8][9][10] conjugated polymer networks, [11][12][13][14] and linear conjugated polymers. [15][16][17][18][19][20] With the notable exception of graphitic carbon nitride, [21] most organic semiconductors have required an additional metal co-catalyst to produce an appreciable H 2 evolution rate, often introduced by Pt photo deposition, [22] or the addition of a molecular catalyst. [8,23,24] However, recent reports of photocatalysis employing both linear and cross-linked conjugated polymers suggest that these systems are able to produce H 2 under visible light irradiation without any added co-catalyst, at a much faster rate than commercial graphitic carbon nitride, even when the latter is subjected to Pt photodeposition. [11] Activity without the need for co-catalysts, which are often precious metals or molecular complexes with limited stability, [25] could be a very attractive feature of such polymer photocatalysts with the potential to vastly reduce the cost and complexity of current photocatalytic systems.A feature of these linear and cross-linked conjugated polymers that has not yet been systematically studied is the presence of significant quantities of residual Pd originating from their synthesis via Pd catalyzed polycondensation reactions. [11,12,15,26] It has previously been shown that the molecular Pd catalysts used in these reactions can decompose via deligation and subsequent Ostwald ripening to form metallic Pd 0 particles, which are strongly retained within the polymer matrix and are difficult to remove via classical purification techniques. [27][28][29][30][31] Similar to Pt 0 , Pd 0 is a highly active proton reduction electrocatalyst. [32][33][34] Therefore, it is possible that the residual Pd, dispersed within these polymer structures, facilitates H 2 evolution and removes the need for additional co-catalysts. Much uncertainty remains about the nature of the active site in conjugated polymer systems, and there are conflicting views in the literature on whether or not the residual amounts of Pd play a significant role. No correlation was seen between Pd concentration and hydrogen evolution reaction (HER) rate in a range of conjugated micro porous polymers, [11] and in a series of linear polymersThe effect of residual Pd on hydrogen evolution activity in conjugated polymer photocatalytic systems is systematically investigated using colloidal poly(9,9-dioctylfluorene-alt-benzothiadiazole) (F8BT) nanoparticles as a model system. Residual Pd, originating from the synthesis of F8BT via Pd catalyzed polycondensation polymerization, is observed in the form of homogeneously distributed Pd nanoparticles within the polymer. Residual Pd is essential for any hydrogen evolution to be observed from this polymer, and very low Pd concentrations (<40 ppm) are sufficient to have a significant effect on the h...
