Post-Quantum Cryptography: Quantum Computers Will Break Today’s Encryption – Are You Ready?
Today’s encryption will not survive quantum computing. It was never designed to.
When large-scale quantum systems become viable, widely used algorithms like RSA and elliptic-curve cryptography will fail—not gradually, but all at once.
The risk is already in motion. Attackers can capture encrypted data today and decrypt it later when quantum capabilities catch up. It has a name: harvest now, decrypt later. Encryption that cannot be broken today is increasingly likely to be broken within the next decade, and much of the encrypted data being collected now will still be sensitive when that happens.
Why post-quantum cryptography matters now
Post-Quantum Cryptography (PQC) requires organizations to move to new, quantum-resistant algorithms. These are not simple or quick changes for most businesses. Cryptography is embedded into every layer of the software stack—from applications to infrastructure to core dependencies—and is often hard-coded into legacy systems that are difficult and costly to change. Updates can also have downstream impacts on performance and load calculations.
To prepare, organizations need to build a clear picture of where cryptography exists across their environments. That means creating a new kind of bill of materials to inventory and track cryptographic implementations, and becoming more crypto-agile so updates can happen more routinely as standards evolve.
Auditing where cryptography exists—and understanding the shelf lives of sensitive data—helps organizations prioritize their early efforts. Data that needs to remain secure for years is already exposed to harvest now, decrypt later attacks. In many cases, the algorithms protecting that data today will take time to replace, especially as changes need to propagate through complex systems and supply chains.
Regulatory pressure is accelerating the timeline
Regulators are setting concrete timelines that make post-quantum cryptography a near-term engineering concern—not a theoretical one.
In the U.S., the CNSA 2.0 program from the National Security Agency (NSA) mandates a phased transition to post-quantum cryptography, with key deadlines beginning in 2027 and major migration milestones by 2030.
In Europe, frameworks such as the NIS2 Directive and the Digital Operational Resilience Act (DORA) require organizations to assess cryptographic risk, enforce stronger cryptographic controls, and demonstrate readiness to evolve toward quantum-resistant approaches.
PQC is no longer a distant concern. It is already on compliance roadmaps.
Securing the transition to post-quantum cryptography
The shift to post-quantum cryptography goes beyond a technology upgrade, and introduces a fundamental change in how software is built, validated, and governed.
As AI-assisted development accelerates, development teams need confidence that cryptographic patterns are applied correctly and consistently. This depends on visibility into how code is created and clear validation that secure practices are followed across workflows.
AI can assist in generating and reviewing code, but it does not guarantee secure outcomes. Validating implementations and reinforcing secure patterns still needs to be part of everyday development.
AI Software Governance connects visibility, risk correlation, and developer capability. Secure Code Warrior provides visibility into AI-generated code, correlates risk at commit, and strengthens developer capability through hands-on secure coding learning. Together, this enables organizations to adopt post-quantum cryptography while maintaining control as development becomes increasingly AI-assisted.
New post-quantum cryptography learning in Secure Code Warrior
To support this transition, Secure Code Warrior has introduced a new vulnerability category: Improper Post-Quantum Cryptography (PQC).
New learning topics are available across ten languages and frameworks, including Terraform (AWS and GCP), Python, Java, Java Spring, C# (.NET Core and Basic), JavaScript and TypeScript (Node.js Express), and Go. Cloud and backend infrastructure are where early PQC efforts are most urgent, and where most organizations will find their most critical cryptography components.
Each topic includes language-specific guidance, hands-on AI Challenges, and real-world scenarios that simulate PQC implementation risks. This gives developers practical experience with how quantum-safe cryptography is implemented and where it can fail.
Post-quantum readiness requires teams to understand where cryptography exists in their code, how PQC impacts implementation, and how to apply secure patterns consistently across development. As quantum-resistant approaches begin to appear in modern standards, teams must also validate how they are applied in real code. Clear visibility into development workflows, combined with reinforcement of secure practices, helps reduce software risk at the source and maintain control as development becomes increasingly AI-assisted.
You can find the new PQC topics in Secure Code Warrior across Quests, Learn, and Explore. Start building the developer capability required to secure what comes next.
Post-quantum cryptography (PQC) is critical for protecting data from quantum computing threats. Learn how “harvest now, decrypt later” exposes risk and how developers can prepare for quantum-safe security.
Shannon Holt は、アプリケーション セキュリティ、クラウド セキュリティ サービス、PCI-DSS や HITRUST などのコンプライアンス標準に関する経験を持つサイバー セキュリティ製品のマーケティング担当者です。
セキュアコードウォリアーは、ソフトウェア開発ライフサイクル全体を通じてコードを保護し、サイバーセキュリティを最優先とする文化を組織に根付かせるために存在します。AppSec管理者、開発者、CISO、あるいはセキュリティに関わるあらゆる立場の方々に対し、組織が安全でないコードに関連するリスクを軽減できるよう支援します。
デモ予約
Shannon Holt は、アプリケーション セキュリティ、クラウド セキュリティ サービス、PCI-DSS や HITRUST などのコンプライアンス標準に関する経験を持つサイバー セキュリティ製品のマーケティング担当者です。
シャノン・ホルトは、アプリケーションセキュリティ、クラウドセキュリティサービス、そしてPCI-DSSやHITRUSTといったコンプライアンス標準に精通したサイバーセキュリティ製品マーケターです。彼女は、セキュリティに対する期待と現代のソフトウェア開発の現実とのギャップを埋め、技術チームにとって安全な開発とコンプライアンスをより実践的で身近なものにすることに情熱を注いでいます。
Today’s encryption will not survive quantum computing. It was never designed to.
When large-scale quantum systems become viable, widely used algorithms like RSA and elliptic-curve cryptography will fail—not gradually, but all at once.
The risk is already in motion. Attackers can capture encrypted data today and decrypt it later when quantum capabilities catch up. It has a name: harvest now, decrypt later. Encryption that cannot be broken today is increasingly likely to be broken within the next decade, and much of the encrypted data being collected now will still be sensitive when that happens.
Why post-quantum cryptography matters now
Post-Quantum Cryptography (PQC) requires organizations to move to new, quantum-resistant algorithms. These are not simple or quick changes for most businesses. Cryptography is embedded into every layer of the software stack—from applications to infrastructure to core dependencies—and is often hard-coded into legacy systems that are difficult and costly to change. Updates can also have downstream impacts on performance and load calculations.
To prepare, organizations need to build a clear picture of where cryptography exists across their environments. That means creating a new kind of bill of materials to inventory and track cryptographic implementations, and becoming more crypto-agile so updates can happen more routinely as standards evolve.
Auditing where cryptography exists—and understanding the shelf lives of sensitive data—helps organizations prioritize their early efforts. Data that needs to remain secure for years is already exposed to harvest now, decrypt later attacks. In many cases, the algorithms protecting that data today will take time to replace, especially as changes need to propagate through complex systems and supply chains.
Regulatory pressure is accelerating the timeline
Regulators are setting concrete timelines that make post-quantum cryptography a near-term engineering concern—not a theoretical one.
In the U.S., the CNSA 2.0 program from the National Security Agency (NSA) mandates a phased transition to post-quantum cryptography, with key deadlines beginning in 2027 and major migration milestones by 2030.
In Europe, frameworks such as the NIS2 Directive and the Digital Operational Resilience Act (DORA) require organizations to assess cryptographic risk, enforce stronger cryptographic controls, and demonstrate readiness to evolve toward quantum-resistant approaches.
PQC is no longer a distant concern. It is already on compliance roadmaps.
Securing the transition to post-quantum cryptography
The shift to post-quantum cryptography goes beyond a technology upgrade, and introduces a fundamental change in how software is built, validated, and governed.
As AI-assisted development accelerates, development teams need confidence that cryptographic patterns are applied correctly and consistently. This depends on visibility into how code is created and clear validation that secure practices are followed across workflows.
AI can assist in generating and reviewing code, but it does not guarantee secure outcomes. Validating implementations and reinforcing secure patterns still needs to be part of everyday development.
AI Software Governance connects visibility, risk correlation, and developer capability. Secure Code Warrior provides visibility into AI-generated code, correlates risk at commit, and strengthens developer capability through hands-on secure coding learning. Together, this enables organizations to adopt post-quantum cryptography while maintaining control as development becomes increasingly AI-assisted.
New post-quantum cryptography learning in Secure Code Warrior
To support this transition, Secure Code Warrior has introduced a new vulnerability category: Improper Post-Quantum Cryptography (PQC).
New learning topics are available across ten languages and frameworks, including Terraform (AWS and GCP), Python, Java, Java Spring, C# (.NET Core and Basic), JavaScript and TypeScript (Node.js Express), and Go. Cloud and backend infrastructure are where early PQC efforts are most urgent, and where most organizations will find their most critical cryptography components.
Each topic includes language-specific guidance, hands-on AI Challenges, and real-world scenarios that simulate PQC implementation risks. This gives developers practical experience with how quantum-safe cryptography is implemented and where it can fail.
Post-quantum readiness requires teams to understand where cryptography exists in their code, how PQC impacts implementation, and how to apply secure patterns consistently across development. As quantum-resistant approaches begin to appear in modern standards, teams must also validate how they are applied in real code. Clear visibility into development workflows, combined with reinforcement of secure practices, helps reduce software risk at the source and maintain control as development becomes increasingly AI-assisted.
You can find the new PQC topics in Secure Code Warrior across Quests, Learn, and Explore. Start building the developer capability required to secure what comes next.
Today’s encryption will not survive quantum computing. It was never designed to.
When large-scale quantum systems become viable, widely used algorithms like RSA and elliptic-curve cryptography will fail—not gradually, but all at once.
The risk is already in motion. Attackers can capture encrypted data today and decrypt it later when quantum capabilities catch up. It has a name: harvest now, decrypt later. Encryption that cannot be broken today is increasingly likely to be broken within the next decade, and much of the encrypted data being collected now will still be sensitive when that happens.
Why post-quantum cryptography matters now
Post-Quantum Cryptography (PQC) requires organizations to move to new, quantum-resistant algorithms. These are not simple or quick changes for most businesses. Cryptography is embedded into every layer of the software stack—from applications to infrastructure to core dependencies—and is often hard-coded into legacy systems that are difficult and costly to change. Updates can also have downstream impacts on performance and load calculations.
To prepare, organizations need to build a clear picture of where cryptography exists across their environments. That means creating a new kind of bill of materials to inventory and track cryptographic implementations, and becoming more crypto-agile so updates can happen more routinely as standards evolve.
Auditing where cryptography exists—and understanding the shelf lives of sensitive data—helps organizations prioritize their early efforts. Data that needs to remain secure for years is already exposed to harvest now, decrypt later attacks. In many cases, the algorithms protecting that data today will take time to replace, especially as changes need to propagate through complex systems and supply chains.
Regulatory pressure is accelerating the timeline
Regulators are setting concrete timelines that make post-quantum cryptography a near-term engineering concern—not a theoretical one.
In the U.S., the CNSA 2.0 program from the National Security Agency (NSA) mandates a phased transition to post-quantum cryptography, with key deadlines beginning in 2027 and major migration milestones by 2030.
In Europe, frameworks such as the NIS2 Directive and the Digital Operational Resilience Act (DORA) require organizations to assess cryptographic risk, enforce stronger cryptographic controls, and demonstrate readiness to evolve toward quantum-resistant approaches.
PQC is no longer a distant concern. It is already on compliance roadmaps.
Securing the transition to post-quantum cryptography
The shift to post-quantum cryptography goes beyond a technology upgrade, and introduces a fundamental change in how software is built, validated, and governed.
As AI-assisted development accelerates, development teams need confidence that cryptographic patterns are applied correctly and consistently. This depends on visibility into how code is created and clear validation that secure practices are followed across workflows.
AI can assist in generating and reviewing code, but it does not guarantee secure outcomes. Validating implementations and reinforcing secure patterns still needs to be part of everyday development.
AI Software Governance connects visibility, risk correlation, and developer capability. Secure Code Warrior provides visibility into AI-generated code, correlates risk at commit, and strengthens developer capability through hands-on secure coding learning. Together, this enables organizations to adopt post-quantum cryptography while maintaining control as development becomes increasingly AI-assisted.
New post-quantum cryptography learning in Secure Code Warrior
To support this transition, Secure Code Warrior has introduced a new vulnerability category: Improper Post-Quantum Cryptography (PQC).
New learning topics are available across ten languages and frameworks, including Terraform (AWS and GCP), Python, Java, Java Spring, C# (.NET Core and Basic), JavaScript and TypeScript (Node.js Express), and Go. Cloud and backend infrastructure are where early PQC efforts are most urgent, and where most organizations will find their most critical cryptography components.
Each topic includes language-specific guidance, hands-on AI Challenges, and real-world scenarios that simulate PQC implementation risks. This gives developers practical experience with how quantum-safe cryptography is implemented and where it can fail.
Post-quantum readiness requires teams to understand where cryptography exists in their code, how PQC impacts implementation, and how to apply secure patterns consistently across development. As quantum-resistant approaches begin to appear in modern standards, teams must also validate how they are applied in real code. Clear visibility into development workflows, combined with reinforcement of secure practices, helps reduce software risk at the source and maintain control as development becomes increasingly AI-assisted.
You can find the new PQC topics in Secure Code Warrior across Quests, Learn, and Explore. Start building the developer capability required to secure what comes next.
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セキュアコードウォリアーは、ソフトウェア開発ライフサイクル全体を通じてコードを保護し、サイバーセキュリティを最優先とする文化を組織に根付かせるために存在します。AppSec管理者、開発者、CISO、あるいはセキュリティに関わるあらゆる立場の方々に対し、組織が安全でないコードに関連するリスクを軽減できるよう支援します。
レポートを見るデモ予約
Shannon Holt は、アプリケーション セキュリティ、クラウド セキュリティ サービス、PCI-DSS や HITRUST などのコンプライアンス標準に関する経験を持つサイバー セキュリティ製品のマーケティング担当者です。
シャノン・ホルトは、アプリケーションセキュリティ、クラウドセキュリティサービス、そしてPCI-DSSやHITRUSTといったコンプライアンス標準に精通したサイバーセキュリティ製品マーケターです。彼女は、セキュリティに対する期待と現代のソフトウェア開発の現実とのギャップを埋め、技術チームにとって安全な開発とコンプライアンスをより実践的で身近なものにすることに情熱を注いでいます。
Today’s encryption will not survive quantum computing. It was never designed to.
When large-scale quantum systems become viable, widely used algorithms like RSA and elliptic-curve cryptography will fail—not gradually, but all at once.
The risk is already in motion. Attackers can capture encrypted data today and decrypt it later when quantum capabilities catch up. It has a name: harvest now, decrypt later. Encryption that cannot be broken today is increasingly likely to be broken within the next decade, and much of the encrypted data being collected now will still be sensitive when that happens.
Why post-quantum cryptography matters now
Post-Quantum Cryptography (PQC) requires organizations to move to new, quantum-resistant algorithms. These are not simple or quick changes for most businesses. Cryptography is embedded into every layer of the software stack—from applications to infrastructure to core dependencies—and is often hard-coded into legacy systems that are difficult and costly to change. Updates can also have downstream impacts on performance and load calculations.
To prepare, organizations need to build a clear picture of where cryptography exists across their environments. That means creating a new kind of bill of materials to inventory and track cryptographic implementations, and becoming more crypto-agile so updates can happen more routinely as standards evolve.
Auditing where cryptography exists—and understanding the shelf lives of sensitive data—helps organizations prioritize their early efforts. Data that needs to remain secure for years is already exposed to harvest now, decrypt later attacks. In many cases, the algorithms protecting that data today will take time to replace, especially as changes need to propagate through complex systems and supply chains.
Regulatory pressure is accelerating the timeline
Regulators are setting concrete timelines that make post-quantum cryptography a near-term engineering concern—not a theoretical one.
In the U.S., the CNSA 2.0 program from the National Security Agency (NSA) mandates a phased transition to post-quantum cryptography, with key deadlines beginning in 2027 and major migration milestones by 2030.
In Europe, frameworks such as the NIS2 Directive and the Digital Operational Resilience Act (DORA) require organizations to assess cryptographic risk, enforce stronger cryptographic controls, and demonstrate readiness to evolve toward quantum-resistant approaches.
PQC is no longer a distant concern. It is already on compliance roadmaps.
Securing the transition to post-quantum cryptography
The shift to post-quantum cryptography goes beyond a technology upgrade, and introduces a fundamental change in how software is built, validated, and governed.
As AI-assisted development accelerates, development teams need confidence that cryptographic patterns are applied correctly and consistently. This depends on visibility into how code is created and clear validation that secure practices are followed across workflows.
AI can assist in generating and reviewing code, but it does not guarantee secure outcomes. Validating implementations and reinforcing secure patterns still needs to be part of everyday development.
AI Software Governance connects visibility, risk correlation, and developer capability. Secure Code Warrior provides visibility into AI-generated code, correlates risk at commit, and strengthens developer capability through hands-on secure coding learning. Together, this enables organizations to adopt post-quantum cryptography while maintaining control as development becomes increasingly AI-assisted.
New post-quantum cryptography learning in Secure Code Warrior
To support this transition, Secure Code Warrior has introduced a new vulnerability category: Improper Post-Quantum Cryptography (PQC).
New learning topics are available across ten languages and frameworks, including Terraform (AWS and GCP), Python, Java, Java Spring, C# (.NET Core and Basic), JavaScript and TypeScript (Node.js Express), and Go. Cloud and backend infrastructure are where early PQC efforts are most urgent, and where most organizations will find their most critical cryptography components.
Each topic includes language-specific guidance, hands-on AI Challenges, and real-world scenarios that simulate PQC implementation risks. This gives developers practical experience with how quantum-safe cryptography is implemented and where it can fail.
Post-quantum readiness requires teams to understand where cryptography exists in their code, how PQC impacts implementation, and how to apply secure patterns consistently across development. As quantum-resistant approaches begin to appear in modern standards, teams must also validate how they are applied in real code. Clear visibility into development workflows, combined with reinforcement of secure practices, helps reduce software risk at the source and maintain control as development becomes increasingly AI-assisted.
You can find the new PQC topics in Secure Code Warrior across Quests, Learn, and Explore. Start building the developer capability required to secure what comes next.
目次
Shannon Holt は、アプリケーション セキュリティ、クラウド セキュリティ サービス、PCI-DSS や HITRUST などのコンプライアンス標準に関する経験を持つサイバー セキュリティ製品のマーケティング担当者です。
セキュアコードウォリアーは、ソフトウェア開発ライフサイクル全体を通じてコードを保護し、サイバーセキュリティを最優先とする文化を組織に根付かせるために存在します。AppSec管理者、開発者、CISO、あるいはセキュリティに関わるあらゆる立場の方々に対し、組織が安全でないコードに関連するリスクを軽減できるよう支援します。
デモ予約ダウンロード始めるのに役立つリソース
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