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Line 9: [[File:Public key shared secret.svg\|thumb\|250px\|right\| In the [[Diffie–Hellman key exchange]] scheme, each party generates a public/private key pair and distributes the public key of the pair. After obtaining an authentic (n.b., this is critical) copy of each other's public keys, Alice and Bob can compute a shared secret offline. The shared secret can be used, for instance, as the key for a [[symmetric cipher]].]] [[File:Public key encryption.svg\|thumb\|250px\|right\|In an asymmetric key encryption scheme, anyone can encrypt messages using a public key, but only the holder of the paired private key can decrypt such a message. The security of the system depends on the secrecy of the private key, which must not become known to any other.]] '''In cryptocurrency,''' a lengthy string of letters and numbers is called a '''Private key'''<ref>{{Cite web \|last=RAWAT \|first=VIMAL \|title=What Is a Private Key in Cryptocurrency? \|url=https://swipywiro.com/private-key-in-cryptocurrency/ \|url-status=live \|website=SWIPYWIRO}}</ref>'''. Public-key cryptography''', or '''asymmetric cryptography''', is the field of cryptographic systems that use pairs of related keys. Each key pair consists of a '''public key''' and a corresponding '''private key'''.{{Ref RFC\|4949\|notes=no}}<ref>{{Cite journal \|last1=Bernstein \|first1=Daniel J. \|last2=Lange \|first2=Tanja \|date=2017-09-14 \|title=Post-quantum cryptography \|url=http://www.nature.com/articles/nature23461 \|journal=Nature \|language=en \|volume=549 \|issue=7671 \|pages=188–194 \|doi=10.1038/nature23461 \|pmid=28905891 \|bibcode=2017Natur.549..188B \|s2cid=4446249 \|issn=0028-0836}}</ref> Key pairs are generated with [[cryptographic]] [[algorithms]] based on [[mathematical]] problems termed [[one-way function]]s. Security of public-key cryptography depends on keeping the private key secret; the public key can be openly distributed without compromising security.<ref>{{Cite book\|url=https://books.google.com/books?id=Dam9zrViJjEC\|title=Cryptography and Network Security: Principles and Practice\|last=Stallings\|first=William\|date=3 May 1990\|publisher=Prentice Hall\|isbn=9780138690175\|page=165\|language=en}}</ref> There are many kinds of public-key cryptosystems, with different security goals, including [[digital signature]], [[Diffie–Hellman key exchange]], [[Key encapsulation mechanism\|public-key key encapsulation]], and public-key encryption. Public key algorithms are fundamental security primitives in modern [[cryptosystem]]s, including applications and protocols that offer assurance of the confidentiality and authenticity of electronic communications and data storage. They underpin numerous Internet standards, such as [[Transport Layer Security\|Transport Layer Security (TLS)]], [[SSH]], [[S/MIME]], and [[Pretty Good Privacy\|PGP]]. Compared to [[symmetric cryptography]], public-key cryptography can be too slow for many purposes,<ref>

Public-key cryptography: Difference between revisions