Covalent organic frameworks comprising cobalt porphyrins for catalytic carbon dioxide reduction in water

YairA self-interfering clock as a "which path" witness Margalit; Zhifan Zhou; Shimon Machluf; Daniel Rohrlich; Yonathan Japha; Ron Folman

Covalent organic frameworks comprising cobalt porphyrins for catalytic carbon dioxide reduction in water

YairA self-interfering clock as a "which path" witness Margalit, Zhifan Zhou, Shimon Machluf, Daniel Rohrlich, Yonathan Japha, Ron Folman

Department of Physics

Research output: Contribution to journal › Article › peer-review

Abstract

We experimentally demonstrate a new interferometry paradigm: a self-interfering clock. We split a clock into two spatially separated wave packets, and observe an interference pattern with a stable phase showing that the splitting was coherent, i.e., the clock was in two places simultaneously. We then make the clock wave packets "tick" at different rates to simulate a proper time lag. The entanglement between the clock's time and its path yields "which path" information, which affects the visibility of the clock's self-interference. By contrast, in standard interferometry, time cannot yield "which path" information. As a clock we use an atom prepared in a superposition of two spin states. This first proof-of-principle experiment may have far-reaching implications for the study of time and general relativity and their impact on fundamental quantum effects such as decoherence and wave packet collapse.

Original language	English
Pages (from-to)	1208-1212
Number of pages	5
Journal	Science
Volume	349
Issue number	6253
State	Published - 2015

Cite this

@article{9e9212b519804068bc41d9703f158481,

title = "Covalent organic frameworks comprising cobalt porphyrins for catalytic carbon dioxide reduction in water",

abstract = "We experimentally demonstrate a new interferometry paradigm: a self-interfering clock. We split a clock into two spatially separated wave packets, and observe an interference pattern with a stable phase showing that the splitting was coherent, i.e., the clock was in two places simultaneously. We then make the clock wave packets {"}tick{"} at different rates to simulate a proper time lag. The entanglement between the clock's time and its path yields {"}which path{"} information, which affects the visibility of the clock's self-interference. By contrast, in standard interferometry, time cannot yield {"}which path{"} information. As a clock we use an atom prepared in a superposition of two spin states. This first proof-of-principle experiment may have far-reaching implications for the study of time and general relativity and their impact on fundamental quantum effects such as decoherence and wave packet collapse.",

author = "Margalit, {YairA self-interfering clock as a {"}which path{"} witness} and Zhifan Zhou and Shimon Machluf and Daniel Rohrlich and Yonathan Japha and Ron Folman",

year = "2015",

language = "English",

volume = "349",

pages = "1208--1212",

journal = "Science",

issn = "0036-8075",

publisher = "American Association for the Advancement of Science",

number = "6253",

}

TY - JOUR

T1 - Covalent organic frameworks comprising cobalt porphyrins for catalytic carbon dioxide reduction in water

AU - Margalit, YairA self-interfering clock as a "which path" witness

AU - Zhou, Zhifan

AU - Machluf, Shimon

AU - Rohrlich, Daniel

AU - Japha, Yonathan

AU - Folman, Ron

PY - 2015

Y1 - 2015

N2 - We experimentally demonstrate a new interferometry paradigm: a self-interfering clock. We split a clock into two spatially separated wave packets, and observe an interference pattern with a stable phase showing that the splitting was coherent, i.e., the clock was in two places simultaneously. We then make the clock wave packets "tick" at different rates to simulate a proper time lag. The entanglement between the clock's time and its path yields "which path" information, which affects the visibility of the clock's self-interference. By contrast, in standard interferometry, time cannot yield "which path" information. As a clock we use an atom prepared in a superposition of two spin states. This first proof-of-principle experiment may have far-reaching implications for the study of time and general relativity and their impact on fundamental quantum effects such as decoherence and wave packet collapse.

AB - We experimentally demonstrate a new interferometry paradigm: a self-interfering clock. We split a clock into two spatially separated wave packets, and observe an interference pattern with a stable phase showing that the splitting was coherent, i.e., the clock was in two places simultaneously. We then make the clock wave packets "tick" at different rates to simulate a proper time lag. The entanglement between the clock's time and its path yields "which path" information, which affects the visibility of the clock's self-interference. By contrast, in standard interferometry, time cannot yield "which path" information. As a clock we use an atom prepared in a superposition of two spin states. This first proof-of-principle experiment may have far-reaching implications for the study of time and general relativity and their impact on fundamental quantum effects such as decoherence and wave packet collapse.

UR - https://www.mendeley.com/catalogue/e3888dcf-7edc-3f5d-b3f4-323a49cec116/

M3 - Article

SN - 0036-8075

VL - 349

SP - 1208

EP - 1212

JO - Science

JF - Science

IS - 6253

ER -

Covalent organic frameworks comprising cobalt porphyrins for catalytic carbon dioxide reduction in water

Abstract

Other files and links

Fingerprint

Cite this