The i7-14701TE sits on the LGA 1700 socket and is built on a 10 nm semiconductor process, with a maximum operating temperature of 100 °C. It carries a 45W TDP, making it one of the more thermally conservative options in its class, and includes integrated graphics along with full 64-bit support. PCIe 5 connectivity is also present, keeping the platform current for modern expansion and storage interfaces.
The processor features eight cores running at a base clock of 2.1 GHz with a clock multiplier of 21, scaling up to a turbo clock of 5.2 GHz through Turbo Boost version 2 across 16 threads. The multiplier is locked, so manual overclocking is not available, and the chip does not use big.LITTLE heterogeneous core architecture. Cache is distributed as 640 KB of L1, 16 MB of L2 at 2 MB per core, and 33 MB of L3 at approximately 4.13 MB per core, providing a substantial buffer for data-heavy workloads.
In PassMark testing, the i7-14701TE achieves an overall score of 27,519, reflecting its multi-threaded throughput across eight cores and 16 threads. The single-threaded result stands at 4,252, indicating the per-core performance available for workloads that rely on sequential execution rather than parallelism.
The integrated UHD Graphics 770 operates at a base clock of 300 MHz and boosts up to 1650 MHz, with 32 execution units, 256 shading units, 16 texture mapping units, and 8 render output units. It can drive up to four displays simultaneously and supports DirectX 12, OpenGL 4.5, and OpenCL 3, covering the main graphics and compute APIs needed for general desktop use and light workloads.
The i7-14701TE supports DDR5 memory at speeds up to 5600 MHz across two channels, reaching a peak bandwidth of 89.6 GB/s. It can address up to 192 GB of RAM in total, and ECC memory is supported, which makes it a practical fit for environments where memory reliability and error correction are a requirement.
The i7-14701TE supports multithreading and includes the NX bit for hardware-enforced memory protection. Its instruction set coverage spans MMX, F16C, FMA3, AES, AVX, AVX2, SSE 4.1, and SSE 4.2, enabling hardware acceleration across a range of workloads including vectorized math, media processing, and encryption. The combination of AES instruction support and the NX bit makes the chip well-equipped for security-conscious deployments at the hardware level.