The telecom network semiconductor trifecta

To better understand this new era, Henkel surveyed semiconductor manufacturers about the evolving landscape of telecommunication chips, the most pressing challenges, and how they are being addressed. Below is a high-level summary of the findings. A deeper analysis is available here.

When it comes to regulations, semiconductor manufacturers must comply with some of the most stringent requirements. Henkel survey respondents pinpointed their number one concern as achieving regulatory compliance.

Regulatory demands are driving the need for innovative and advanced solutions in semiconductor design and packaging. Achieving compliance presents a multifaceted challenge that includes strong quality management systems, verification of source authenticity, detailed documentation of component origins, and securing necessary export licenses. However, these requirements can also increase costs and reduce profitability, pressing semiconductor manufacturers to carefully balance regulatory obligations with performance and sustainability goals.

Semiconductor reliability remains the top priority for ensuring stable, long-lasting telecom network performance, especially under harsh conditions. In addition, the rise of 5G and high-speed broadband drives the need for high-performing, power-efficient chips capable of handling greater data loads with low latency. To meet these demands, manufacturers are turning to advanced materials, innovative chip designs, and RF front-end integration. While integrating multiple RF components into a single chip boosts performance and reduces size, it also introduces thermal, signal isolation, and power management challenges that require precise assembly and specialized materials.

As semiconductor designs become increasingly compact and complex, managing manufacturing precision becomes increasingly critical—especially with RF front-end integration and support for multiple frequency bands. Edge AI adoption is further accelerating demand for semiconductors that enable real-time, decentralized processing in applications like IoT and autonomous vehicles. This shift requires highly integrated, power-efficient chip architectures combining CPUs, GPUs, and AI cores. At the same time, materials like SiC and GaN are gaining traction for their superior power and frequency performance, introducing new manufacturing requirements. Across the board, advanced materials play a central role in overcoming these technical hurdles, ensuring reliability, and maintaining manufacturing efficiency.