Institutional R&D · post-quantum cryptography
Post Quantum engineers post-quantum cryptographic architectures, NIST PQC standards (ML-KEM, ML-DSA, FIPS 203), published threat models, CRQC-oriented vulnerability assessment, and deterministic migration frameworks for sovereign infrastructure.
Current Status:Active R&D Initiative30+ Libraries ReleasedStandards-Aligned (FIPS 203)
Security · Transparency · Readiness
Threat-modeled research. Inspectable libraries. Deterministic production paths.
Peer-reviewed cryptographic research aligned with NIST PQC, including ML-KEM, ML-DSA, and FIPS 203. Hardware-software co-design, kernel-level optimization, and published threat models with reproducible benchmark methodology.
Open-source reference libraries on PyPI and GitHub with published threat models, benchmark suites, and migration playbooks released alongside source for independent verification.
Browse librariesPost Quantum publishes auditable blueprints and libraries. Bajpai Labs delivers systems-level implementation with deterministic execution when deployments require high-availability architecture, kernel-level hardening, or hardware-software integration under strict regulatory controls. Same engineering team; sovereign infrastructure from research through production.
Engage production engineeringWhy open source?
“Cryptographic security is only as strong as its transparency. PQL maintains fully auditable source, benchmarks, threat models, and methodology: no backdoors, no proprietary limitations.”
Read the PQL standard for transparency requirements, published threat models, and deterministic execution paths.
Migration journey
Threat modeling and vulnerability assessment to map harvest-now-decrypt-later (HNDL) exposure, CRQC timelines, and cryptographic agility gaps.
Deploy using our open-source libraries: ML-KEM, ML-DSA, and FIPS 203 aligned reference implementations.
Deploy sovereign infrastructure with deterministic execution paths: kernel-level hardening, regulatory compliance controls, and operational rollout on hardened architecture.
Global PQC migration timeline
Now
Enterprise PQC pilots; hybrid algorithms in high-sensitivity systems.
2025 – 2026
NIST finalization; migration acceleration in finance and healthcare.
2026 – 2028
Mandated PQC adoption in critical infrastructure; legacy retirement.
2030 +
Complete transition; post-quantum internet backbone operational.
Flagship frameworks
Each framework ships with reference implementation, benchmark suite, and threat model. Maintained on a rolling release alongside NIST publication cycles.
Open-source library catalogMemory-hardened architecture for persistent AI agents with post-quantum cryptographic isolation. Prevents state injection and quantum-era memory leakage.
Automated scanning for harvest-now-decrypt-later exposure, CRQC threat timelines, and cryptographic agility across enterprise stacks.
Hybrid quantum-classical orchestration, enterprise PQC migration strategy, and PQC adoption roadmaps for regulated industries.
Kernel-level optimizations for ML-KEM, ML-DSA, and SLH-DSA reducing cryptographic overhead by 40–60% vs. standard software implementations.
Post Quantum publishes threat models, reference implementations, and migration frameworks for sovereign infrastructure under CRQC timelines. Read the research program charter.
