Quantum key distribution via pulse position modulation

What is claimed is: 1. A system, comprising: a quantum channel; a public channel; a first node connected to the public channel, wherein the first node includes a pulse position modulation encoder connected to the quantum channel; and a second node connected to the public channel, wherein the second node includes a pulse position modulation decoder connected to the quantum channel, wherein the pulse position modulation encoder is configured to: encode a quantum state 10> by producing a first light pulse that occurs in a first time bin and transmitting the first light pulse; encode a quantum state |1> by producing a first light pulse that occurs in the first time bin, producing a second light pulse that occurs in a second time bin, and transmitting the first and second light pulses together as a pseudo-light pulse having a precise time separation defined by a temporal separation of the first and second time bins; and transmit the encoded quantum states |0> and |1> via the quantum channel to the second node; wherein the pulse position modulation encoder includes a beam splitter and three mirrors, wherein the three mirrors are positioned to delay the beam from the beam splitter by the temporal separation of the first and second time bins. 2. The system of claim 1 , wherein the first and second nodes are synchronized via separate reference signals formed by interrogating Rubidium (Rb) cells with stabilized laser outputs of cavity-stabilized reference lasers. 3. The system of claim 1 , wherein the pulse position modulation decoder includes a beam splitter and three mirrors, wherein one of the three mirrors only reflects light during the first time bin. 4. The system of claim 1 , wherein the second node determines a shared secret key from the quantum states |0> and |1> received from the first node and uses the shared secret key to encrypt data transferred on the public channel. 5. The system of claim 4 , wherein the second node detects eavesdropping as a function of the quantum states |0> and |1> received from the first node. 6. A pulse position modulation encoder configured to: encode a quantum state |0> by producing a first light pulse that occurs in a first time bin and transmitting the first light pulse: encode a quantum state |1> by producing the first light pulse that occurs in the first time bin, producing a second light pulse that occurs in a second time bin, and transmitting the first and second light pulses together as a pseudo-light pulse having a precise time separation defined by a temporal separation of the first and second time bins; and transmit the encoded quantum states |0> and |1> out through a quantum channel interface; wherein the pulse position modulation encoder includes a beam splitter and three mirrors, wherein the three mirrors are positioned to delay the beam from the beam splitter by the temporal separation of the first and second time bins. 7. The encoder of claim 6 , wherein the pulse position modulation encoder is synchronized to a pulse position modulation decoder via separate reference signals formed by interrogating Rubidium (Rb) cells with stabilized laser outputs of cavity-stabilized reference lasers. 8. A pulse position modulation decoder configured to: decode quantum states 10> and |1> received through a quantum channel interface; decode the quantum state 10> by receiving a first light pulse that occurs in a first time bin; and decode the quantum state |1> by receiving a first light pulse that occurs in a second time bin, the first and second light pulses together forming a pseudo-light pulse having a precise time separation defined by a temporal separation of the first and second time bins; wherein the pulse position modulation decoder includes a beam splitter and three mirrors, wherein one of the three mirrors only reflects light during the first time bin. 9. The decoder of claim 8 , wherein the pulse position modulation decoder is synchronized to a pulse position modulation encoder via separate reference signals formed by interrogating Rubidium (Rb) cells with stabilized laser outputs of cavity-stabilized reference lasers. 10. A method of distributing; a quantum key from first party to a second party, the method comprising: encoding a quantum state |0> by producing a first light pulse that occurs in a first time bin and transmitting the first light pulse; encoding a quantum state |1> by producing the first light pulse that occurs in the first bin, producing a second light pulse that occurs in a second time bin, and transmitting the first and second light pulses together as a pseudo-light pulse having a precise time separation defined by a temporal separation of the first and second time bins; transmitting a random string of quantum states |0> and |1> from the first party to the second party; measuring the quantum states by the second party, wherein measuring includes applying projections on the random string of quantum states |0> and |1>; publicly announcing the projections; privately constructing, by the first party, a substring, wherein the substring includes bits sent in he random string of quantum states with indices that match indices in the projections; privately constructing, by the second party, a string, wherein the string is a function of the projections; publicly revealing a portion of the substring; publicly revealing a portion of the string; comparing the revealed portion of the substring to the revealed portion of the string; if the revealed portion of the substring is identical to the revealed portion of the string, using remaining unrevealed bits of the string and substring as a shared secret key; and if the revealed portion of the substring is not identical to the revealed portion of the string, noting eavesdropping. 11. The method of claim 10 , wherein the first and second parties synchronize via separate reference signals formed by interrogating Rubidium (Rb) cells with stabilized laser outputs of cavity-stabilized reference lasers. 12. An article comprising a nontransitory computer-readable medium having instructions thereon, wherein the instructions, when executed in a computer, create a system for executing a method of distributing a quantum key from a first party to a second party, the method comprising: encoding a quantum state |0> by producing a first light pulse that occurs in a first time bin and transmitting the first light pulse; encoding a quantum state |1> by producing the first light pulse that occurs in the first time bin, producing a second light pulse that occurs in a second time bin, and transmitting the first and second light pulses together as a pseudo-light pulse having a precise time separation defined by a temporal separation of the first and second time bins; transmitting a random string of quantum states |0> and |1> from the first party to the second party; measuring the quantum states by the second party, wherein measuring includes applying projections on the random string of quantum states |0> and |1>; publicly announcing the projections; privately constructing, by the first party, a substring, wherein the substring includes bits sent in the random string of quantum states with indices that match indices in the projections; privately constructing, by the second party, a string, wherein the string is a function of the projections; publicly revealing a portion of the substring; publicly revealing a portion of the string; comparing the revealed portion of the substring to the revealed portion of the string; if the revealed portion of the substring is identical to the revealed portion of the string, using remaining unrevealed bits of the string and substring