Business
Device
Trusted digital IDs for every connected device,
from pre-shipment through the entire product lifecycle.
SEALSQ'sVaultIC Secure Element / INeS PKI Platform / WISeKey Root Certificatework together as one to manage IoT device digital identities from pre-shipment through end of life. They support major ecosystems such as Matter and Wi-SUN immediately and enable secure, rapid deployments at multi-million-device scale. Domestic Echonet Lite DA support is planned. Silicon Technology Co., Ltd. is SEALSQ'sauthorized distributor in Japanand provides full technical support for the Japanese market. 🔬 What is PQC? — Understand the Quantum Threat
Secure Element
Pre-Shipment Provisioning
Certificate Mgmt
Automated Management for Millions of Devices
Root of Trust
Root Certificate Authority
PQC Ready
Stay Ahead of Next-Generation Threats
🔬 Secure Semiconductors (Secure Chips)
SEALSQ is one of fewer than ten companies worldwide capable of developing certified secure microcontrollers. For more than 25 years, it has focused on secure chips and secure firmware and holds over 51 patent families. It offers a broad portfolio of CC EAL5+ and FIPS-certified products.
Quantum Shield QS7001
RISC-V Secure Hardware Platform — PQC Ready
An 80 MHz 32-bit RISC-V core with CC EAL5+ certified security directly implements Kyber and Dilithium quantum-resistant algorithms in silicon. It delivers up to 10x performance improvement, side-channel resistance, and tamper resistance. An open hardware platform supporting custom firmware. Development kits are available.
QVault TPM
Hardware Root of Trust — PQC-Ready TPM Platform
A secure hardware platform integrating TPM functions on an 80 MHz RISC-V core. It combines physical protection, independent execution, and secure key storage to enable device identity, secure boot, and attestation over 10+ year lifecycles. CC EAL5+ architecture.
A ready-to-use secure element for IoT. FIPS 140-3 and CC EAL5+ “ready” security provide strong protection against modern attack scenarios and an extended feature set designed for a wide range of IoT use cases.
A cost-efficient secure element designed to enable secure object authentication and efficient TLS connectivity to the cloud. Supports pre-installed Matter DAC certificates and is ideal for smart home and connected IoT devices.
Secure ARM Platform
High-Performance Secure MCU — CC EAL5+ Certified
A tamper-resistant secure microcontroller with a 32-bit ARM SC300 core. CC EAL5+ certified. A powerful, high-performance platform suitable for secure data storage, FIDO USB tokens, crypto wallets, and access control.
Smart Card Reader Chip
EMV Level 1 Compliant Reader IC
An EMV Level 1 compliant smart card reader chip family. Adopted by leading OEMs, it combines broad compatibility with excellent product performance.
🔑 PKI & Trust Services (INeS Platform)
At the core of SEALSQ's value proposition is not only secure microcontrollers, but also the ability to securely and efficiently generate, inject, and manage unique, globally trusted digital IDs for each device. PKI services create and assign a unique digital ID (certificate) to every connected device and manage the entire lifecycle.
INeS Managed PKI for IoT
With INeS, SEALSQ's PKI-as-a-Service platform, you can instantly generate and manage millions of IoT certificates that identify devices as part of trusted ecosystems such as Matter and Wi-SUN. It enables security, interoperability, and ease of use for end users.
Secure Factory Provisioning
Provisioning refers to injecting security credentials into devices. Depending on customer needs and manufacturing environments, SEALSQ offers multiple options, including chip-level provisioning, PCB-level provisioning, and provisioning of final devices before shipment.
Zero-Touch Provisioning (ZTP)
ZTP is a process that automatically configures network devices without user operation simply by physically connecting a device to the network and powering it on. This service securely provisions digital certificates and private keys directly in the field over the air, greatly minimizing operational burden and simplifying supply-chain and IoT platform connectivity.
Root CA and Chain of Trust (Root of Trust)
Public-key cryptography and digital certificates are used to encrypt or digitally sign all types of information, including communication data and firmware updates. These processes depend on the concepts of digital trust and Root of Trust, which are the only way to ensure trusted data is sent from genuine devices. SEALSQ enables the use of publicly or privately trusted root certificate authorities and builds trust models tailored to business needs.
🏅 Certifications, Compliance & Partnerships
Achieve rapid compliance with stringent regulatory frameworks and ensure the highest level of product security. SEALSQ chips are certified by some of the world’s strictest certification bodies (Common Criteria and FIPS) and are tested and manufactured to the highest standards of security, reliability, and quality. All operations are conducted in an ISO 27001 certified environment.
Common Criteria
EAL5+ Certification
FIPS 140-3
FIPS 203/204
Trusted Computing
Group Certification
ISO 27001
Information Security
NIST NCCoE
PQC Migration Consortium
CSA Matter
Certification Authority (PAA)
Echonet Lite DA
Planned Support
*Not a certification body
Wi-SUN Alliance
Certification Support
GSMA
Root Certificate
WebTrust for CA
Audited PKI
① Understand the Quantum Threat
SEALSQ gives a clear warning.existing public-key cryptography may be broken by the computing power of quantum systemsModern Internet and IoT systems depend onRSAandECC (elliptic curve cryptography)which base their security on the computational difficulty of factoring large integers and solving elliptic-curve discrete logarithm problems.Today, billions of IoT devices around the world are protected by these algorithms. Quantum computers have the power to overturn that security model.
Quantum computers use properties of quantum physics (superposition and quantum entanglement ) to store and process data. Conventional computers (smartphones and laptops) represent information asbitsbut quantum computers usequantum bits (qubits).
An 8-bit classical computer can represent one specific number from 0 to 255. However,an 8-qubit quantum computer can represent all numbers from 0 to 255 simultaneously. When hundreds of qubits are entangled, they can process more numerical states simultaneously than the number of atoms in the universe—this is the essence of the disruptive computing power of quantum computers.
In 1994, mathematician Peter Shor published“Shor’s algorithm”which showed that a quantum computer could factor large integers in polynomial time. The algorithm has not been invalidated; it is waiting for machines capable of running it. According to SEALSQ, that era is no longer a distant future.
A 2019 study suggested that a powerful quantum computer could break RSA inabout eight hoursGoogle’s quantum chip “Willow,” announced in late 2024, showed major progress in error correction, rapidly increasing threat assessments among experts.
SEALSQ states on its website that action is needed now, even before practical quantum computers arrive. Malicious attackers are alreadycollecting and storing encrypted communications datawith the intent to decrypt it later using future quantum computers. Harvest Now, Decrypt Later (HNDL/SNDL) attacks are now a real threat. Organizations handling sensitive information or long-life products shouldnowbegin migrating to post-quantum cryptography.
② What is PQC (Post-Quantum Cryptography)? — SEALSQ's Definition
SEALSQ defines Post-Quantum Cryptography (PQC) as “ , next-generation cryptographic algorithms that can remain secure against the computing power of quantum computers”. It is based on problems considered mathematically difficult for quantum computers to solve, such as lattice problems and hash functions, and can run on today’s digital infrastructure, enabling practical migration.
SEALSQ does not leave PQC as academic research; it provides it asreal silicon chips, secure firmware, and PKI cloud servicesand is one of the world’s leading companies commercializing these technologies. In Japan, these products are available through Silicon Technology.
Quantum cryptography (Quantum Key Distribution: QKD) uses quantum mechanicstosecurely distribute keys. By contrast, PQC as promoted by SEALSQ replaces algorithms running on existing digital infrastructure (software and hardware). SEALSQ believes that, for IoT and embedded devices,practically implementable PQCis the most practical approach industry can adopt now.
Current Cryptography vs Post-Quantum Cryptography — Comparison
| Item | Conventional public-key cryptography (RSA/ECC) | PQC (Post-Quantum Cryptography) |
|---|---|---|
| Mathematical basis | Factorization / discrete logarithm problems | Lattice problems / hashes / codes / multivariate polynomials |
| Resistance to classical computers | ○ Secure | ○ Secure |
| Resistance to quantum computers | ✕ At risk (Shor’s algorithm) | ○ Secure by design |
| NIST standardization | Conventional standards (e.g., FIPS 186) | Finalized in August 2024 (FIPS 203/204) |
| Implementation form | Widely deployed in software and hardware | Software implementation possible; hardware-level implementation offers the highest trust |
③ Details of NIST-Standardized Algorithms
The U.S. National Institute of Standards and Technology (NIST) has solicited and evaluated PQC algorithms worldwide since 2016 and, in August 2024, officially published the firstPQC standards (FIPS 203 and 204)The two main algorithms are as follows.
Based on the computational difficulty of lattice problems (Module-LWE). Used for secure key sharing and exchange. Ideal for key establishment in IoT devices and TLS communications, replacing RSA and ECDH.
A lattice-based signature algorithm used for device authentication, firmware signing, and certificate issuance. Designed as a successor to ECDSA and RSA signatures and efficient in embedded environments.
A signature scheme based on NTRU lattices. Its signature and public-key sizes are very small, making it suitable for embedded devices and bandwidth-constrained communication links.
During the migration period, it is recommended to run conventional RSA/ECC and new PQC algorithmsin parallel (hybrid mode)This preserves backward compatibility with existing infrastructure while gradually adding quantum resistance. SEALSQ's QS7001 supports this hybrid migration at the hardware level.
④ SEALSQ'sApproach:Quantum Lab QUASARSProject
SEALSQ “Understand the Quantum Threat” , threats mission . R&D Quantum Lab .NIST standard PQC secure semiconductors / secure firmware / cloud trust services integration research / validation / complianceframework .
SEALSQ collaborates with world-class research institutions and works at the forefront of quantum-safe technology, including cooperation with France’s École des Mines. In 2022, together with France’s national cybersecurity agency ANSSI, itCommon Criteria EAL5+to develop a PQC-ready hardware Root of Trust meeting the requirements ofQUASARSProjectlaunched the project.
SEALSQ directly participates in the“Migration to PQC Consortium” led by NIST’s National Cybersecurity Center of Excellence (NCCoE)contributing to industry standards while simultaneously advancing product-level implementation. This is one of its greatest strengths.
⑤ Product Introduction:Quantum Shield QS7001
2025, SEALSQ Industry-first secure chip with PQC algorithms implemented directly in silicon (hardware), Quantum Shield QS7001It offers major advantages over software-level PQC implementations in performance, tamper resistance, and side-channel attack resistance.
Quantum Shield QS7001
Industry-first — NISTstandardPQC
QS7001 Key Features
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01Hardware-Level PQC Implementation
ML-KEM / ML-DSAis integrated directly in silicon. Dedicated cryptographic accelerators enable low latency and low power consumption even in embedded and IoT environments.
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02Hardware Root of Trust
Protects device IDs, cryptographic keys, and firmware integrity at the silicon level. Supports secure boot, remote attestation, and key lifecycle management.
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03Hybrid Cryptographic Migration Support
ECDSA + Dilithium dual-stack operation .existing systems backward compatibility , gradual PQCmigration-ready design.
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04Open Platform Design
An open hardware platform supporting custom firmware and application deployment. It can flexibly adapt to a wide range of industrial applications.
⑥ SEALSQIndustrial Use Cases Implemented by
SEALSQ , QS7001 target fields “Multi-Factor Authentication / smart energy / medical / defense / IT network infrastructure / industrial automation” states.is already shipping mass-production products to customers worldwide, Eviden(Atos ) / Capgemini Engineering / Kaynes Semiconductorand has confirmed partnerships with others.
🇯🇵 ECHONET Lite DA Planned Support
⑦ SEALSQPQC Migration Roadmap Presented by
SEALSQ company blog“Quantum risk is no longer tomorrow's problem” , U.S. government CNSA 2.0 / NISTguidelines / White House executive order migration timeline publishes. SEALSQ / PKIProduct development plans building . authorized distributor , support .
U.S. NSA CNSA 2.0 20271to national security systems quantum-safe migration mandates , EU allied countries 2026–2030 phased mandates are planning.SEALSQ regulatory schedule Product fully aligned.
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NowPhase 1(2025–2026):NIST PQC integration
QS7001 shipment .ML-KEM / ML-DSA same-dayCNSA 2.0compliant . / SDK , now evaluation begin . Sample Request .
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Near TermPhase 2(2027–2030):ECC+PQC CNSA 2.0compliant
QS7001 CNSA 1.0 / CNSA 2.0 / support.existing systems backward compatibility gradual .QVault TPM 2026 begin , form .
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FuturePhase 3(2030 ):IoT / ID / Authentication PQC
SEALSQ'sINeS PKI Platform CNSA 2.0compliantPost-Quantumcertificate issuance U.S. Root of Trust . 20251121 .INeS / ZTP / Secure Factory Provisioning , quantum-safe migration .
17.5 or moredeployed across devices / QS7001 / QVault TPM 4,980 USD(2026–2028 )/ total pipeline Approx.2 USD(2026–2028)/ partners and customers in discussion 115 or more(North America / Europe / Asia-Pacific)
Source: SEALSQ Corp. press release 20251216
⑧ :SEALSQ authorized distributor in Japan
Silicon Technology Co., Ltd. is, SEALSQ Corp. (NASDAQ: LAES) authorized distributor in Japan(Authorized Distributor) .SEALSQ / Product , customers in Japan technical consultationfromevaluation samplesarrangementtoprovided end-to-end.
SEALSQ's“Understand the Quantum Threat” , preparation nowstarting important . engineers / design engineers / procurement personnel professionals for, support / implementation consultationavailable.
Silicon Technology Co., Ltd. isSEALSQ'sauthorized distributor in Japan , QS7001evaluation board arrangement / technical specifications Details / NDA Detailsdocument provisionto .
🌐 Contactform: si-tech.co.jp/contact →
💡 Solutions
SEALSQ semiconductor chips / PKI / , broadsecurity challenges end-to-end Solutions . SEALSQ keySolutions .
All of the above solutionsSilicon Technology Co., Ltd. (SEALSQauthorized distributor in Japan)are available for consultation through.product selection / evaluationto .
→ Contact
🌐 SEALSQAbout(Company)
SEALSQ , 25 semiconductor chips / secure firmware / service (NASDAQ : LAES).“a safer connected world” vision , (PQC) front line .
SEALSQ'sStrengths:end-to-end Trust Framework
SEALSQ , single company , one of the few companies worldwide .secure microcontrollers design and manufacturingfrom, PKI service, , to, complete trust chain building .
Silicon Technology Co., Ltd. isSEALSQ Corp. (NASDAQ: LAES) authorized distributor in Japan(Authorized Distributor in Japan) , SEALSQ's Product / service .technical consultation / evaluation samplesto .
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