We propose an asynchronous-logic (async) Quasi-Delay-Insensitive (QDI) Static Logic Transistor-level Implementation (SLTI) approach for low power sub-threshold operation. The approach is implemented to design 32-bit pipelined Arithmetic and Logic Units (ALUs), the primary computation core for microprocessors, and benchmarked against the reported Pre-Charged Half-Buffer (PCHB). There are two key attributes in this proposed design. First, the proposed SLTI ALU design can perform dynamic voltage scaling seamless by only changing the supply voltage from nominal (1V) to sub-threshold (~0.2V) regions for high speed/low power operation. Second, the ALU achieves ultra-low power dissipation (3.5μW) at the lowest V_DD point (~0.15V). For fair of comparison, both implemented ALUs have identical functionality and functional blocks, are implemented using the same 65nm CMOS process. Based on the simulations, the minimum energy point occurs at V_DD = 0.2V for SLTI-based ALU and at V_DD = 0.3V for PCHB-based ALU. The SLTI-based ALU have ~93% and ~89% lower energy on the arithmetic and logic operations respectively from V_DD = 1V to V_DD = 0.2V. At V_DD = 0.2V, with 9MHz input switching rate, the async ALU based on our proposed SLTI approach dissipates ~51% and ~44% lower power than the reported PCHB counterpart on the arithmetic and logic operations respectively.