1,988 research outputs found
Fine-grained EPR-steering inequalities
We derive a new steering inequality based on a fine-grained uncertainty
relation to capture EPR-steering for bipartite systems. Our steering inequality
improves over previously known ones since it can experimentally detect all
steerable two-qubit Werner state with only two measurement settings on each
side. According to our inequality, pure entangle states are maximally
steerable. Moreover, by slightly changing the setting, we can express the
amount of violation of our inequality as a function of their violation of the
CHSH inequality. Finally, we prove that the amount of violation of our steering
inequality is, up to a constant factor, a lower bound on the key rate of a
one-sided device independent quantum key distribution protocol secure against
individual attacks. To show this result, we first derive a monogamy relation
for our steering inequality.Comment: 5 pages, Accepted for publication as a Rapid Communication in
Physical Review
Quantum attacks against iterated block ciphers
We study the amplification of security against quantum attacks provided by
iteration of block ciphers. In the classical case, the Meet-in-the-middle
attack is a generic attack against those constructions. This attack reduces the
time required to break double iterations to only twice the time it takes to
attack a single block cipher, given that the attacker has access to a large
amount of memory. More abstractly, it shows that security by composition does
not achieve exact multiplicative amplification. We present a quantized version
of this attack based on an optimal quantum algorithm for the Element
Distinctness problem. We then use the generalized adversary method to prove the
optimality of the attack. An interesting corollary is that the time-space
tradeoff for quantum attacks is very different from what classical attacks
allow. This first result seems to indicate that composition resists better to
quantum attacks than to classical ones because it prevents the quadratic
speedup achieved by quantizing an exhaustive search.
We investigate security amplification by composition further by examining the
case of four iterations. We quantize a recent technique called the dissection
attack using the framework of quantum walks. Surprisingly, this leads to better
gains over classical attacks than for double iterations, which seems to
indicate that when the number of iterations grows, the resistance against
quantum attacks decreases.Comment: 14 page
A Simple Bargaining Mechanism That Elicits Truthful Reservation Prices
We describe a simple 2-stage mechanism that induces two bargainers to be truthful in reporting their reservation prices in a 1st stage. If these prices criss-cross, the referee reports that they overlap, and the bargainers proceed to make offers in a 2nd stage. The average of the 2nd-stage offers becomes the settlement if both offers fall into the overlap interval; if only one offer falls into this interval, it is the settlement, but is implemented with probability 1/2; if neither offer falls into the interval, there is no settlement. Thus, if the bargainers reach the 2nd stage, they know their reservation prices overlap even if they fail to reach a settlement, possibly motivating them to try again.Bargaining; truth-telling mechanisms; probabilistic implementation
Demonstrating genuine multipartite entanglement and nonseparability without shared reference frames
Multipartite nonlocality is of great fundamental interest and constitutes a
useful resource for many quantum information protocols. However, demonstrating
it in practice, by violating a Bell inequality, can be difficult. In
particular, standard experimental setups require the alignment of distant
parties' reference frames, which can be challenging or impossible in practice.
In this work we study the violation of certain Bell inequalities, namely the
Mermin, Mermin-Klyshko and Svetlichny inequalities, without shared reference
frames, when parties share a Greenberger-Horne-Zeilinger (GHZ) state.
Furthermore, we analyse how these violations demonstrate genuine multipartite
features of entanglement and nonlocality. For 3, 4 and 5 parties, we show that
it is possible to violate these inequalities with high probability, when the
parties choose their measurements from the three Pauli operators, defined only
with respect to their local frames. Moreover, the probability of violation, and
the amount of violation, are increased when each party chooses their
measurements from the four operators describing the vertices of a tetrahedron.
We also consider how many randomly chosen measurement directions are needed to
violate the Bell inequalities with high probability. We see that the obtained
levels of violation are sufficient to also demonstrate genuine multipartite
entanglement and nonseparability. Finally, we show analytically that choosing
from two measurement settings per party is sufficient to demonstrate the
maximum degree of genuine multipartite entanglement and nonseparability with
certainty when the parties' reference frames are aligned in one direction so
that they differ only in rotations around one axis
A Simple Bargaining Mechanism That Elicits Truthful Reservation Prices
We describe a simple 2-stage mechanism that induces two bargainers to be truthful in reporting their reservation prices in a 1st stage. If these prices criss-cross, the referee reports that they overlap, and the bargainers proceed to make offers in a 2nd stage. The average of the 2nd-stage offers becomes the settlement if both offers fall into the overlap interval; if only one offer falls into this interval, it is the settlement, but is implemented with probability 1/2; if neither offer falls into the interval, there is no settlement. Thus, if the bargainers reach the 2nd stage, they know their reservation prices overlap even if they fail to reach a settlement, possibly motivating them to try again.Bargaining; truth-telling mechanisms; probabilistic implementation; incomplete information.
The Potentate of P.I.O. : [Judith Schwartz]
Rockefeller University Research Profiles are a series of scientific profiles that were published quarterly, from 1980-1990, by the Rockefeller University. Each issue features the research and achievements of an individual Rockefeller University scientist.https://digitalcommons.rockefeller.edu/research_profiles/1037/thumbnail.jp
Experimental detection of steerability in Bell local states with two measurement settings
Steering, a quantum property stronger than entanglement but weaker than
non-locality in the quantum correlation hierarchy, is a key resource for
one-sided device-independent quantum key distribution applications, in which
only one of the communicating parties is trusted. A fine-grained steering
inequality was introduced in [PRA 90 050305(R) (2014)], enabling for the first
time the detection of steering in all steerable two-qubit Werner states using
only two measurement settings. Here we numerically and experimentally
investigate this inequality for generalized Werner states and successfully
detect steerability in a wide range of two-photon polarization-entangled Bell
local states generated by a parametric down-conversion source.Comment: 9 pages, 7 figures (including Appendix
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