# Difference between revisions of "Quantum Computing Threat"

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− | + | [[Public Key Cryptography]] has many benefits over [[Secret Key Cryptography]], the effort to create new algorithm to preserve the current PK protocols is underway now. | |

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*[https://csrc.nist.gov/publications/detail/nistir/8105/final "Report on Post-Quantum Cryptography"] | *[https://csrc.nist.gov/publications/detail/nistir/8105/final "Report on Post-Quantum Cryptography"] | ||

*[https://www.imperialviolet.org/ ImperialViolet: Post-quantum confidentiality for TLS (2018-04-11)] | *[https://www.imperialviolet.org/ ImperialViolet: Post-quantum confidentiality for TLS (2018-04-11)] | ||

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==References== | ==References== |

## Latest revision as of 07:24, 25 September 2018

## Full Title or Meme

Successful **Quantum Computing** creates an existential threat to existing algorithms since quantum computing algorithms exist to crack traditionally intractable solutions like RSA.

## Context

Public key cryptography relies on certain mathematical problems that are very hard to solve, such as factoring large numbers that are the product of large prime numbers or finding the discrete logarithm of a random elliptic curve element with respect to a publicly known base point. If you know the private key components, you can sign the document or decrypt the data. If you don't have the private key and cannot solve the math, you cannot sign the document or decrypt the data.

## Problem

## Solutions

Public Key Cryptography has many benefits over Secret Key Cryptography, the effort to create new algorithm to preserve the current PK protocols is underway now.

- "Report on Post-Quantum Cryptography"
- ImperialViolet: Post-quantum confidentiality for TLS (2018-04-11)