In recent years, global warming and climate change have posed significant threats, necessitating urgent energy-saving and carbon-reduction measures to protect our planet. The international community has made efforts to reduce carbon emissions, particularly in the cement industry, which is one of the major sources of global carbon emissions. This has led to research and improvements in the cement production process, the search for more environmentally friendly production methods, the development of new materials, and the adoption of energy-saving technologies to reduce carbon emissions. This study aims to reduce carbon emissions by using limestone cement, producing limestone blended cement to replace Portland cement, which is currently an effective carbon reduction method internationally. The study considers the effects of different mix proportions on material performance, investigating the impact of different limestone cement specifications, mineral admixtures, and aggregates. Tests on fresh properties, mechanical properties, durability, and adiabatic temperature rise were conducted. Through in-depth research on concrete and cement mortar, a comprehensive understanding of the effects of different factors on material performance can be achieved, providing a more scientific basis for mix design, thereby improving concrete performance and enhancing the quality and durability of concrete structures. According to the experimental results, the workability of concrete can be successfully controlled by adding appropriate additives to different proportions of limestone cement specifications, mineral admixtures, and aggregates, ensuring that the performance meets the standard requirements. Limestone blended cement and Portland Type I cement exhibited similar fresh properties. In terms of mechanical properties, when different mineral admixtures and aggregates are used, limestone cement demonstrated higher compressive strength during the early hardening stage. However, as the age increased, the compressive strength began to decline, and the final strength showed no significant difference compared to Type I cement. Limestone cement showed a slight advantage in chloride ion resistance but required the addition of mineral admixtures to enhance its durability against sulfate attack.