Quantum circuits constitute Intellectual Property (IP) of the quantum developers and users, which needs to be protected from theft by adversarial agents e.g., the quantum cloud provider or a rogue adversary present in the cloud. This necessitates the exploration of low-overhead techniques applicable to near-term quantum devices, to trace the quantum circuits/algorithms' IP and their output. We present two such lightweight watermarking techniques to prove ownership in the event of an adversary cloning the circuit design. For the first technique a rotation gate is placed on ancilla qubits combined with other gate (s) at the output of the circuit. For the second method, a set of random gates are inserted in the middle of the circuit followed by its inverse, separated from the circuit by a barrier. These models are combined and applied on benchmark circuits and the circuit depth, 2-qubit gate count, probability of successful trials (PST) and probabilistic proof of authorship (PPA) are compared against the state-of-the-art. The PST is reduced by a miniscule 0.53% against the non-watermarked benchmarks and is up to 22.69% higher compared to existing techniques. The circuit depth has been reduced by up to 27.7% as against the state-of-the-art. The PPA is astronomically smaller than existing watermarks.