Samsung’s push to become more self-reliant in smartphone chip development appears to be picking up speed. After the Exynos 2600 marked an important early step with Samsung’s first 2nm GAA smartphone SoC, the company is already turning its attention to what comes next. The Exynos 2700 has now surfaced again in Geekbench, suggesting Samsung is already testing and fine-tuning the silicon well ahead of its expected debut in the Galaxy S27 lineup.
What makes this new sighting notable is that it moves beyond earlier GPU-focused results. This time, the listing includes compute performance figures along with CPU benchmark scores, showing 2,603 points in single-core and 10,350 points in multi-core. On paper, those numbers won’t impress anyone expecting a major leap right away, but early Geekbench results often reflect pre-production hardware, conservative clock speeds, unfinished firmware, and incomplete scheduling and power management. In other words, it’s a snapshot of development progress rather than a final verdict.
The urgency behind Exynos 2700 development likely comes from the areas where the Exynos 2600 still needs work. Despite its advantages as Samsung’s first-generation 2nm GAA chip, one of the biggest concerns has been power efficiency under load. Reports indicate the Exynos 2600 can draw up to 30W when stressed, which is an obvious pressure point for sustained performance, thermals, and battery life.
That efficiency gap can translate directly into everyday user experience. In comparative battery testing scenarios, the Galaxy S26 variant powered by a competing flagship chip has been reported to last roughly 28 percent longer—more than two extra hours compared to the Exynos 2600 model. For buyers, that kind of difference isn’t a small benchmark detail; it’s the sort of real-world advantage that can shape purchasing decisions and influence how people perceive an entire smartphone series.
With Exynos 2700, Samsung is expected to respond with a more refined design and manufacturing approach. The company is reportedly planning to use its second-generation 2nm GAA process, which could help improve both performance and efficiency. A more mature node often enables better yields, higher clocks at lower voltage, and improved thermals—exactly the areas Samsung needs to strengthen if it wants Exynos-powered flagships to compete more confidently.
On the CPU side, the Exynos 2700 is still expected to feature a 10-core configuration, but the internal layout may be changing. Instead of the “1 + 3 + 6” setup associated with Exynos 2600, current expectations point to a “4 + 1 + 4 + 1” cluster arrangement. While final specifications can still change, this kind of shift may be aimed at improving efficiency and balancing performance more intelligently across different workloads, potentially reducing high-power spikes and improving sustained behavior.
The timeline also suggests Samsung is serious about scaling this platform. The Exynos 2700 is expected to enter mass production in the second half of 2026, positioning it for broader use across the Galaxy S27 family. If Samsung can successfully address efficiency issues and deliver a more consistent experience across performance, thermals, and battery life, the Exynos 2700 could become a key step in making Samsung’s in-house chipset strategy more competitive—and more widely adopted in its flagship phones.
