Nadia Heninger (born 1982)[1] is an American cryptographer, computer security expert, and computational number theorist at the University of California, San Diego.

Nadia Heninger 2013 at Chaos Communication Congress

Contributions

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Heninger is known for her work on freezing powered-down security devices to slow their fading memories and allow their secrets to be recovered via a cold boot attack,[2][A] for her discovery that weak keys for the RSA cryptosystem are in widespread use by internet routers and other embedded devices,[3][B] for her research on how failures of forward secrecy in bad implementations of the Diffie–Hellman key exchange may have allowed the National Security Agency to decrypt large amounts of internet traffic via the Logjam vulnerability,[4][C] and for the DROWN attack, which uses servers supporting old and weak cryptography to decrypt traffic from modern clients to modern servers.[5][D]

Heninger's other research contributions include a variant of the RSA cryptosystem that would be secure against quantum computers,[6] an attack on implementations of the ANSI X9.31 cryptographically secure pseudorandom number generator that use hard-coded seed keys to initialize the generator,[7] and the discovery of a side-channel attack against some versions of the libgcrypt cryptography library.[8]

In 2015, Heninger was part of a team of proponents that included Matt Blaze, Steven M. Bellovin, J. Alex Halderman, and Andrea M. Matwyshyn who successfully proposed a security research exemption to Section 1201 of the Digital Millennium Copyright Act.[9]

Education and career

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Heninger graduated from the University of California, Berkeley in 2004, with a bachelor's degree in electrical engineering and computer science.[10] She completed her doctorate in 2011 at Princeton University; her dissertation, Error Correction and the Cryptographic Key, was supervised by Bernard Chazelle.[10][11] After postdoctoral research at the University of California, San Diego and Microsoft Research in New England, she became Magerman Term Assistant Professor at the University of Pennsylvania in 2013.[12] In 2019, she returned to the University of California, San Diego.

Recognition

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Heninger's work on weak keys and on forward secrecy of Diffie–Hellman won best paper awards at the conferences at which they were presented, as have several of Heninger's other publications.[10] She is one of the 2016 recipients of the Applied Networking Research Prize of the Internet Research Task Force.[13]

She was an invited speaker at Asiacrypt 2016, speaking on "The reality of cryptographic deployments on the internet".[14]

Selected publications

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A.
Halderman, J. Alex; Schoen, Seth D.; Heninger, Nadia; Clarkson, William; Paul, William; Calandrino, Joseph A.; Feldman, Ariel J.; Appelbaum, Jacob; Felten, Edward W. (May 2009), "Lest we remember: Cold-boot attacks on encryption keys", Communications of the ACM, 52 (5): 91–98, doi:10.1145/1506409.1506429, S2CID 7770695
B.
Heninger, Nadia; Durumeric, Zakir; Wustrow, Eric; Halderman, J. Alex (2012), "Mining your Ps and Qs: Detection of widespread weak keys in network devices" (PDF), Proceedings of the 21st USENIX Conference on Security Symposium (Security'12), Berkeley, CA, USA: USENIX Association, pp. 35:1–35:16
C.
Adrian, David; Bhargavan, Karthikeyan; Durumeric, Zakir; Gaudry, Pierrick; Green, Matthew; Halderman, J. Alex; Heninger, Nadia; Springall, Drew; Thomé, Emmanuel; Valenta, Luke; VanderSloot, Benjamin; Wustrow, Eric; Zanella-Béguelin, Santiago; Zimmermann, Paul (2015), "Imperfect forward secrecy: How Diffie-Hellman fails in practice", Proceedings of the 22nd ACM SIGSAC Conference on Computer and Communications Security (CCS '15), New York, NY, USA: ACM, pp. 5–17, doi:10.1145/2810103.2813707, ISBN 978-1-4503-3832-5
D.
Aviram, Nimrod; Schinzel, Sebastian; Somorovsky, Juraj; Heninger, Nadia; Dankel, Maik; Steube, Jens; Valenta, Luke; Adrian, David; Halderman, J. Alex; Dukhovni, Viktor; Käsper, Emilia; Cohney, Shaanan; Engels, Susanne; Paar, Christof; Shavitt, Yuval (August 2016), "DROWN: Breaking TLS with SSLv2" (PDF), 25th USENIX Security Symposium

References

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  1. ^ Birth year from Library of Congress catalog entry, retrieved December 9, 2018.
  2. ^ Mills, Elinor (July 30, 2008), Disk encryption is no silver bullet, researchers say: Researchers tell how to steal disk encryption key and sensitive data off memory in laptops in cold-boot attack on hibernating computer, CNET
  3. ^ Leyden, John (February 16, 2012), "'Predictably random' public keys can be cracked - crypto boffins: Battling researchers argue over whether you should panic", The Register
  4. ^ Doctorow, Cory (October 16, 2015), "Now we know the NSA blew the black budget breaking crypto, how can you defend yourself?", Boing Boing
  5. ^ Mott, Nathaniel (March 2, 2016), "Drown attack: how weakened encryption jeopardizes 'secure' sites: Researchers warn sites such as Yahoo, BuzzFeed and Flickr would be susceptible to attack, and credit card info, passwords and other data could be compromised", The Guardian
  6. ^ Kim, Mark H. (May 15, 2017), "Why quantum computers might not break cryptography", Quanta Magazine
  7. ^ Chirgwin, Richard (October 25, 2017), "Holy DUHK! Boffins name bug that could crack crypto wide open: Hard-coded keys and pseudorandom numbers flay Fortinet first, other vendors probably also in play", The Register
  8. ^ Chirgwin, Richard (July 4, 2017), "GnuPG crypto library cracked, look for patches: Boffins bust libgcrypt via side-channel", The Register
  9. ^ "Section 1201 Rulemaking: Sixth Triennial Proceeding to Determine Exemptions to the Prohibition on Circumvention" (PDF).
  10. ^ a b c Curriculum vitae (PDF), University of Pennsylvania, retrieved September 18, 2018
  11. ^ Nadia Heninger at the Mathematics Genealogy Project
  12. ^ Rosenbloom, Stephanie (June 4, 2014), "How not to pay the price for free Wi-Fi", The New York Times
  13. ^ Applied Networking Research Prize, Internet Research Task Force, retrieved September 18, 2018
  14. ^ "Program", Asiacrypt 2016, retrieved September 18, 2018
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