Although several wide-bandgap (1.6-2.0 eV) chalcopyrites (e.g. CuGaSe₂, Cu(In,Ga)S₂, Cu(In,Al)Se₂, (Ag,Cu)GaSe₂) have been thus far studied as top cell absorbers for photoelectrochemical (PEC) water splitting tandem devices, CuGa(S,Se)₂ is a wide-Eg chalcopyrite that has not yet received any attention in this regard. In this communication, we report on the performance of wide-bandgap chalcopyrite CuGa(S,Se)₂ photocathodes as a top cell for PEC tandem water splitting. To be able to assess the PEC performance of CuGa(S,Se)₂ as well as its optical transmittance, transparent conductive fluorinated tin oxide (FTO) substrates were used as back contacts. Through our research, we found that synthesizing CuGa(S,Se)₂ films through sulfurization of a CuGaSe₂ precursor would degrade the optoelectronic properties of the FTO substrate. As such, a specific synthesis approach was developed to circumvent this problem and successfully fabricate functioning CuGa(S,Se)₂ PEC photocathodes on FTO. We present the PEC performance of our CuGa(S,Se)₂ photocathodes (J_SAT≈10 mA/cm²) as well as measurements relevant to its performance as a top cell, such as sub-bandgap transmittance. Finally, we present quantum efficiency of a low-bandgap Cu(In,Ga)Se₂ shaded by the CuGa(S,Se)₂ PEC photocathode, and discuss the potential of Cu(In,Ga)Se₂/CuGa(S,Se)₂ tandem structures for non-assisted PEC water splitting.