SEALSQ Demonstrates the Convergence of Post-Quantum Secure Physical AI and Robotics, Showcasing WISeRobot During the Davos Event

Geneva, Switzerland, Jan. 26, 2026 (GLOBE NEWSWIRE) —

SEALSQ Corp (NASDAQ: LAES) (“SEALSQ” or the “Company”), a global leader in semiconductors, PKI, and post-quantum cryptography (PQC) hardware and software solutions, today announced a live demonstration exploring its Post-Quantum Cryptography Robotic Concept during the Physical AI Roundtable held in Davos on the margins of the World Economic Forum Annual Meeting. The demonstration featured WISeRobot, developed in cooperation with its parent company WISeKey International Holding Ltd (“WISeKey”) (SIX: WIHN, NASDAQ: WKEY), a leading global cybersecurity, blockchain, and IoT company, and illustrated the potential and need for post-quantum security to one day be embedded directly into physical AI and robotic systems.

As quantum computing continues to advance, many of today’s cryptographic standards are expected to become vulnerable. SEALSQ is proactively addressing this challenge by working on the integration of quantum-resistant algorithms and hardware-based roots of trust into robotic platforms, with the goal of ensuring long-term security, integrity, and trusted operation for AI-driven and autonomous systems deployed in real-world, often adversarial environments.

The demonstration leveraged WISeRobot.ch, an advanced robotics platform meant to illustrate how post-quantum security could eventually be anchored across the silicon, firmware, and system levels. During the roundtable, WISeRobot actively participated as a live, interactive presence, animating discussions by demonstrating secure digital identity, trusted human–machine and machine-to-machine interactions, cryptographically protected communications, and hardware-anchored trust in real time.

Physical AI, which is AI embodied in machines that perceive, decide, and act in the physical world, requires a fundamentally different security model than purely digital systems. SEALSQ is exploring and plans to address this by embedding trust directly into its secure semiconductors through hardware-based roots of trust, post-quantum cryptographic accelerators, secure key storage, and lifecycle management. Each Physical AI system could be provisioned at manufacturing with a unique, unclonable cryptographic identity protected inside secure hardware, enabling trusted boot, authenticated firmware and AI models, integrity attestation, and secure interaction with humans, infrastructure, and other machines.

By planning to integrate post-quantum cryptography directly into the semiconductor layer, SEALSQ aims to ensure that communications, commands, AI decisions, and software updates remain secure and authentic even in the presence of future quantum computers. This approach is intended to enable long-lived autonomous systems deployed today to remain resilient well beyond the expected arrival of practical quantum computing capabilities. During the Physical AI Roundtable, David Shrier, Professor of Practice at Imperial College London, described how artificial intelligence and quantum computing are set to converge, fundamentally reshaping how machines learn, reason, and optimize decisions. He emphasized that while quantum technologies will dramatically accelerate certain classes of computation, they will also amplify systemic risk unless AI systems, particularly Physical AI, are built on verifiable trust, secure identity, and resilient cryptographic foundations from the outset.

The human dimension of this transformation was further highlighted by Sol Rashidi, the world’s first Chief AI Officer, former Amazon and C-suite executive, best-selling author, and globally recognized AI anthropologist and workforce architect. Rashidi stressed that as AI expands into Physical AI, where machines interact directly with humans and the real world, human-centric requirements become non-negotiable. She underscored the need for AI systems to be transparent, accountable, explainable, and aligned with human values, noting that without embedded trust, security, and ethical guardrails, Physical AI risks eroding confidence rather than augmenting human capability.

During the same discussions, Mark Hughes, Global Managing Partner of Cybersecurity Services at IBM, stated that quantum computers are expected to arrive as early as 2028 and confirmed that IBM is already prepared for this transition. These perspectives reinforced a shared conclusion among participants: the post-quantum era is approaching faster than previously anticipated, making immediate action essential to protect digital identities, AI systems, and autonomous machines from future cryptographic disruption.

The WISeRobot concept demonstrated at Davos illustrated how post-quantum-ready security can move from theory into operational reality, establishing a new benchmark for trusted autonomous systems in critical environments such as government, healthcare, smart infrastructure, and industrial automation. The demonstration highlighted how intelligent machines can be engineered to be secure by default, resilient by design, and fundamenally aligned with human-centric values.

“Robotics and AI are rapidly becoming part of our critical infrastructure,” said Carlos Moreira, CEO of SEALSQ. “By conducting experiments with post-quantum cryptography in robotics and bringing this first concept to animate our Davos Roundtable, we are demonstrating how trust, security, and human-centric principles can be embedded into intelligent machines from the very beginning.

Jonathan Llamas, VP of Decentralized Strategy of WISeKey noted, “Building on this trusted hardware and post-quantum foundation, SEALCOIN extends the Physical AI stack by enabling a native settlement and accountability layer for autonomous machines. As Physical AI systems move from perception and decision-making to action in real-world environments, true autonomy requires the ability to settle value, enforce economic rules, and execute obligations without human intervention. SEALCOIN provides this missing layer, allowing certified machines to transact, compensate, and be economically accountable in a secure and auditable way. From a machine perspective, integrating settlement is the final step toward autonomy, enabling Physical AI systems not only to act securely, but to operate as independent economic agents within trusted human-defined boundaries.”

SEALSQ’s post-quantum robotics initiative reflects the Company’s broader commitment to developing and delivering quantum-ready technologies that protect digital identities, AI systems, and critical infrastructures worldwide, while contributing to global discussions on trusted artificial intelligence, technological sovereignty, and secure digital ecosystems in a quantum-enabled future.

About SEALSQ:
SEALSQ is a leading innovator in Post-Quantum Technology hardware and software solutions. Our technology seamlessly integrates Semiconductors, PKI (Public Key Infrastructure), and Provisioning Services, with a strategic emphasis on developing state-of-the-art Quantum Resistant Cryptography and Semiconductors designed to address the urgent security challenges posed by quantum computing. As quantum computers advance, traditional cryptographic methods like RSA and Elliptic Curve Cryptography (ECC) are increasingly vulnerable.

SEALSQ is pioneering the development of Post-Quantum Semiconductors that provide robust, future-proof protection for sensitive data across a wide range of applications, including Multi-Factor Authentication tokens, Smart Energy, Medical and Healthcare Systems, Defense, IT Network Infrastructure, Automotive, and Industrial Automation and Control Systems. By embedding Post-Quantum Cryptography into our semiconductor solutions, SEALSQ ensures that organizations stay protected against quantum threats. Our products are engineered to safeguard critical systems, enhancing resilience and security across diverse industries.

For more information on our Post-Quantum Semiconductors and security solutions, please visit www.sealsq.com.

Forward-Looking Statements
This communication expressly or implicitly contains certain forward-looking statements concerning SEALSQ Corp and its businesses. Forward-looking statements include statements regarding our business strategy, financial performance, results of operations, market data, events or developments that we expect or anticipate will occur in the future, as well as any other statements which are not historical facts. Although we believe that the expectations reflected in such forward-looking statements are reasonable, no assurance can be given that such expectations will prove to have been correct. These statements involve known and unknown risks and are based upon a number of assumptions and estimates which are inherently subject to significant uncertainties and contingencies, many of which are beyond our control. Actual results may differ materially from those expressed or implied by such forward-looking statements. Important factors that, in our view, could cause actual results to differ materially from those discussed in the forward-looking statements include SEALSQ’s ability to continue beneficial transactions with material parties, including a limited number of significant customers; market demand and semiconductor industry conditions; and the risks discussed in SEALSQ’s filings with the SEC. Risks and uncertainties are further described in reports filed by SEALSQ with the SEC.

SEALSQ Corp is providing this communication as of this date and does not undertake to update any forward-looking statements contained herein as a result of new information, future events or otherwise.