working on a codebook app (for creating simple codebooks and encoding / decoding messages with or without pre-modern encryption); a more ambitious codebook generator (up to 100,000-ish entries plus beaucoup homophones); and a codebook decryptor page that explains maybe a bit to much about how to attack code and code + encryption messages.

#cryptography #cryptanalysis #codes #JustForFun

Breaking codes: cryptanalysis
https://negativepid.blog/breaking-codes-cryptanalysis/

#cryptanalysis #cryptography #steganography #privacy #espionage #Cybersecurity #cyberattacks #cyberThreats #onlineSecurity #negativepid

Really have enjoyed The Code Book by Simon Singh #Cryptography #cryptanalysis

Have ordered the David Kahn first edition of The Codebreakers from eBay to read next.

How Quantum Computing Could Change Cybersecurity

1,043 words, 6 minutes read time.

Quantum computing is no longer a distant dream scribbled on whiteboards at research labs; it is a looming reality that promises to disrupt every corner of the digital landscape. For cybersecurity professionals, from the analysts sifting through logs at 2 a.m. to CISOs defending multimillion-dollar digital fortresses, the quantum revolution is both a threat and an opportunity. The very encryption schemes that secure our communications, financial transactions, and sensitive corporate data could be rendered obsolete by the computational power of qubits. This isn’t science fiction—it’s an urgent wake-up call. In this article, I’ll explore how quantum computing could break traditional cryptography, force the adoption of post-quantum defenses, and transform the way we model and respond to cyber threats. Understanding these shifts isn’t optional for security professionals anymore; it’s survival.

Breaking Encryption: The Quantum Threat to Current Security

The first and most immediate concern for anyone in cybersecurity is that quantum computers can render our existing cryptographic systems ineffective. Traditional encryption methods, such as RSA and ECC, rely on mathematical problems that classical computers cannot solve efficiently. RSA, for example, depends on the difficulty of factoring large prime numbers, while ECC leverages complex elliptic curve relationships. These are the foundations of secure communications, e-commerce, and cloud storage, and for decades, they have kept adversaries at bay. Enter quantum computing, armed with Shor’s algorithm—a method capable of factoring these massive numbers exponentially faster than any classical machine. In practical terms, a sufficiently powerful quantum computer could crack RSA-2048 in a matter of hours or even minutes, exposing sensitive data once thought safe. Grover’s algorithm further threatens symmetric encryption by effectively halving key lengths, making AES-128 more vulnerable than security architects might realize. In my years monitoring security incidents, I’ve seen teams underestimate risk, assuming that encryption is invulnerable as long as key lengths are long enough. Quantum computing demolishes that assumption, creating a paradigm where legacy systems and outdated protocols are no longer just inconvenient—they are liabilities waiting to be exploited.

Post-Quantum Cryptography: Building the Defenses of Tomorrow

As frightening as the threat is, the cybersecurity industry isn’t standing still. Post-quantum cryptography (PQC) is already taking shape, spearheaded by NIST’s multi-year standardization process. This isn’t just theoretical work; these cryptosystems are designed to withstand attacks from both classical and quantum computers. Lattice-based cryptography, for example, leverages complex mathematical structures that quantum algorithms struggle to break, while hash-based and code-based schemes offer alternative layers of protection for digital signatures and authentication. Transitioning to post-quantum algorithms is far from trivial, especially for large enterprises with sprawling IT infrastructures, legacy systems, and regulatory compliance requirements. Yet the work begins today, not tomorrow. From a practical standpoint, I’ve advised organizations to start by mapping cryptographic inventories, identifying where RSA or ECC keys are in use, and simulating migrations to PQC algorithms in controlled environments. The key takeaway is that the shift to quantum-resistant cryptography isn’t an optional upgrade—it’s a strategic imperative. Companies that delay this transition risk catastrophic exposure, particularly as nation-state actors and well-funded cybercriminal groups begin experimenting with quantum technologies in secret labs.

Quantum Computing and Threat Modeling: A Strategic Shift

Beyond encryption, quantum computing will fundamentally alter threat modeling and incident response. Current cybersecurity frameworks and MITRE ATT&CK mappings are built around adversaries constrained by classical computing limits. Quantum technology changes the playing field, allowing attackers to solve previously intractable problems, reverse-engineer cryptographic keys, and potentially breach systems thought secure for decades. From a SOC analyst’s perspective, this requires a mindset shift: monitoring, detection, and response strategies must anticipate capabilities that don’t yet exist outside of labs. For CISOs, the challenge is even greater—aligning board-level risk discussions with the abstract, probabilistic threats posed by quantum computing. I’ve observed that many security leaders struggle to communicate emerging threats without causing panic, but quantum computing isn’t hypothetical anymore. It demands proactive investment in R&D, participation in standardization efforts, and real-world testing of quantum-safe protocols. In the trenches, threat hunters will need to refine anomaly detection models, factoring in the possibility of attackers leveraging quantum-powered cryptanalysis or accelerating attacks that once required months of computation. The long-term winners in cybersecurity will be those who can integrate quantum risk into their operational and strategic planning today.

Conclusion: Preparing for the Quantum Era

Quantum computing promises to be the most disruptive force in cybersecurity since the advent of the internet itself. The risks are tangible: encryption once considered unbreakable may crumble, exposing sensitive data; organizations that ignore post-quantum cryptography will face immense vulnerabilities; and threat modeling will require a fundamental reevaluation of attacker capabilities. But this is not a reason for despair—it is a call to action. Security professionals who begin preparing now, by inventorying cryptographic assets, adopting post-quantum strategies, and updating threat models, will turn the quantum challenge into a competitive advantage. In my years in the field, I’ve learned that the edge in cybersecurity always belongs to those who anticipate the next wave rather than react to it. Quantum computing is that next wave, and the time to surf it—or be crushed—is now. For analysts, architects, and CISOs alike, embracing this reality is the only way to ensure our digital fortresses remain unbreachable in a world that quantum computing is poised to redefine.

Call to Action

If this breakdown helped you think a little clearer about the threats out there, don’t just click away. Subscribe for more no-nonsense security insights, drop a comment with your thoughts or questions, or reach out if there’s a topic you want me to tackle next. Stay sharp out there.

D. Bryan King

Sources

NIST: Post-Quantum Cryptography Standardization
NISTIR 8105: Report on Post-Quantum Cryptography
CISA Cybersecurity Advisories
Mandiant Annual Threat Report
MITRE ATT&CK Framework
Schneier on Security Blog
KrebsOnSecurity
Verizon Data Breach Investigations Report
Shor, Peter W. (1994) Algorithms for Quantum Computation: Discrete Logarithms and Factoring
Grover, Lov K. (1996) A Fast Quantum Mechanical Algorithm for Database Search
Black Hat Conference Materials
DEF CON Conference Archives

Disclaimer:

The views and opinions expressed in this post are solely those of the author. The information provided is based on personal research, experience, and understanding of the subject matter at the time of writing. Readers should consult relevant experts or authorities for specific guidance related to their unique situations.

#advancedPersistentThreat #AES #boardLevelCybersecurity #CISO #cloudSecurity #codeBasedCryptography #cryptanalysis #cryptographyMigration #cyberAwareness #cyberDefense #cyberDefenseStrategy #cyberInnovation #cyberPreparedness #cyberResilience #cyberRisk #cyberStrategy #cyberattack #cybersecurity #cybersecurityChallenges #cybersecurityFrameworks #cybersecurityTrends #dataProtection #digitalFortresses #digitalSecurity #ECC #emergingThreats #encryption #encryptionKeys #futureProofSecurity #GroverSAlgorithm #hashingAlgorithms #incidentResponse #ITSecurityLeadership #latticeBasedCryptography #legacySystems #MITREATTCK #nationStateThreat #networkSecurity #NISTPQC #postQuantumCryptography #quantumComputing #quantumComputingImpact #quantumEraSecurity #quantumReadiness #quantumRevolution #quantumThreat #quantumResistantCryptography #quantumSafeAlgorithms #quantumSafeProtocols #RSA #secureCommunications #securityBestPractices #securityPlanning #ShorSAlgorithm #SOCAnalyst #threatHunting #threatIntelligence #ThreatModeling #zeroTrust

So I just found something weird.
There's a suggested hashtag I found trying to tag [#]h3x0r which looks like some cryptographic stuff. My first thought was that it may be some encrypted traffic with a hash that split this part off. Perhaps something like PGP or a hash to whatever.

Please kind internet find what this is!

#cryptanalysis #hivemind

Lost and found: Codebreakers decipher 50+ letters of Mary, Queen of Scots - Ars Technica

I just discovered this story from 2023 and it's amazing - both the life of Mary Stuart than how the coded letters were discovered and decoded, or the sheer number of encoded letters

https://arstechnica.com/science/2023/02/lost-and-found-code-breakers-decipher-50-letters-of-mary-queen-of-scots/

The cache of letters sheds new light on Mary Stuart’s years of captivity in England.

#history #cryptanalysis #cypher

New Cryptanalysis of the Fiat-Shamir Protocol

A couple of months ago, a new paper demonstrated some new attacks against the Fiat-Shamir transformation. Quanta published a <a href="https://www.quantamagazine.org/computer-scientists-figure-o... https://www.schneier.com/blog/archives/2025/09/new-cryptanalysis-of-the-fiat-shamir-protocol.html

#academicpapers #Uncategorized #cryptanalysis #protocols #hashes

1965 Cryptanalysis Training Workbook Released by the NSA

In the early 1960s, National Security Agency cryptanalyst and cryptanalysis instructor Lambros D. Callimahos coined the term “Stethoscope” to describe a diagnostic computer program used to unravel the internal structure of pre-computer... https://www.schneier.com/blog/archives/2025/09/1965-cryptanalysis-training-workbook-released-by-the-nsa.html

#historyofcryptography #Uncategorized #cryptanalysis #NSA

35 years ago, Jim Sanborn presented the cryptographic sculpture Kryptos to the Central Intelligence Agency in Langley, Virginia. Made from copper, granite, quartz and petrified wood, it has four sections, each of which holds a message in code. Over the years, three of the sections have been solved — by CIA code breakers, a California computer scientist, and the National Security Agency. Now, 79-year-old Sanborn says he's going to auction off the solution to the final message, with the company arranging the sale estimating a winning bid between $300,000 and $500,000. Here's @newyorktimes's story on why he's doing it now, and what he hopes the winning bidder will do with the secret.

https://flip.it/_TN3II

#Science #Technology #Mathematics #Codebreaking #Kryptos #JimSanborn #Art #Sculpture #Cryptology #Cryptography #Cryptanalysis