Ion Trap Nobel

Ion Trap Nobel

The Nobel Prize in Physics 2012 Serge Haroche, David J. Wineland The Nobel Prize in Physics 2012 was awarded jointly to Serge Haroche and David J. Wineland "for ground-breaking experimental methods that enable measuring and manipulation of individual quantum systems" David J. Wineland, U.S. citizen. Born 1944 in Milwaukee, WI, USA. Ph.D. 1970 Serge Haroche, French citizen. Born 1944 in Casablanca, Morocco. Ph.D. from Harvard University, Cambridge, MA, USA. Group Leader and NIST Fellow at 1971 from Université Pierre et Marie Curie, Paris, France. Professor at National Institute of Standards and Technology (NIST) and University of Colorado Collège de France and Ecole Normale Supérieure, Paris, France. Boulder, CO, USA www.college-de-france.fr/site/en-serge-haroche/biography.htm www.nist.gov/pml/div688/grp10/index.cfm A laser is used to suppress the ion’s thermal motion in the trap, and to electrode control and measure the trapped ion. lasers ions Electrodes keep the beryllium ions inside a trap. electrode electrode Figure 2. In David Wineland’s laboratory in Boulder, Colorado, electrically charged atoms or ions are kept inside a trap by surrounding electric fields. One of the secrets behind Wineland’s breakthrough is mastery of the art of using laser beams and creating laser pulses. A laser is used to put the ion in its lowest energy state and thus enabling the study of quantum phenomena with the trapped ion. Controlling single photons in a trap Serge Haroche and his research group employ a diferent method to reveal the mysteries of the quantum world. In the laboratory in Paris microwave photons bounce back and forth inside a small cavity between two mirrors, about three centimetres apart. The mirrors are made of superconducting material and are cooled to a temperature just above absolute zero. These superconducting mirrors are the world’s shiniest. They are so refective that a single photon can bounce back and forth inside the cavity for almost a tenth of a second before it is lost or absorbed. This record-long life-time means that the photon will have travelled 40,000 kilometres, equivalent to about one trip around the Earth. During its long life time, many quantum manipulations can be performed with the trapped photon. Haroche uses specially prepared atoms, so-called Rydberg atoms (after the Swedish physicist Johannes Rydberg) to both control and measure the microwave photon in the cavity. A Rydberg atom has a radius of about 125 nanometers which is roughly 1,000 times larger than typical atoms. These gigantic doughnut-shaped Rydberg atoms are sent into the cavity one by one at a carefully chosen speed, so that the interaction with the microwave photon occurs in a well controlled manner. The Rydberg atom traverses and exits the cavity, leaving the microwave photon behind. But the interac- tion between the photon and the atom creates a change in the phase of quantum state of the atom: if you think of the atom’s quantum state as a wave, the peaks and the dips of the wave become shifted. This phase shift can be measured when the atom exits the cavity, thereby revealing the presence or absence of a photon inside the cavity. With no photon there is no phase shift. Haroche can thus measure a single photon without destroying it. THE NOBEL PRIZE IN PHYSICS 2012 THE ROYAL SWEDISH ACADEMY OF SCIENCES HTTP://KVA.SE 2(6) Photons bounce back and forth inside a small cavity between two mirrors for more than a tenth of a second. Before it disappears the photon will have travelled Rydberg atoms – roughly 1,000 times a distance of one trip around the Earth. larger than typical atoms – are sent through the cavity one by one. At the exit the atom can reveal the presence or absence of a photon inside the cavity. 2.7 cm superconducting niobium mirrors microwave photons Figure 3. In the Serge Haroche laboratory in Paris, in vacuum and at a temperature of almost absolute zero, the microwave photons bounce back and forth inside a small cavity between two mirrors. The mirrors are so reflective that a single photon stays for more than a tenth of a second before it is lost. During its long life time, many quantum manipulations can be performed with the trapped photon without destroying it. With a similar method Haroche and his group could count the photons inside the cavity, as a child counts marbles in a bowl. This may sound easy but requires extraordinary dexterity and skill because photons, unlike ordinary marbles, are destroyed immediately by contact with the world outside. Building on his photon counting methods, Haroche and collaborators devised methods to follow the evolution of an individual quantumReferences state, step-by-step, in real time. Paradoxes of quantum mechanics Quantum mechanics describes a microscopic world invisible to the naked eye, where events occur contrary NY Times: “French and U.S. Physicists Win Nobel Prize” to• our expectations and experiences with physical phenomena in the macroscopic, classical world. Physics in• theNobelprize.org… quantum world has some inherent uncertainty or randomness to it. One example of this contrary behaviour is superposition, where a quantum particle can be in several diferent states simultaneously. We do not• normallyParticle think control of a marble in asa beingquantum both ‘here’ world and ‘there’ at the same time, but such is the case if it were a quantum marble. The superposition state of this marble tells us exactly what probability the marble has of •beingMeasuring here or there, and if we Manipulating were to measure Individualexactly where Quantumit is. Systems Why• Phys do we Rev. never A become(1979): aware“Laser of theseCooling strange of Atoms”facets of our world? Why can we not observe a superposition of quantum marble in our every-day life? The Austrian physicist and Nobel Laureate (Physics• Phys 1933 Rev) Erwin Lett Schrödinger(1989): “Laser battled Cooling with this to question. the Zero Like Point many otherEnergy pioneers of Motion” of quantum theory, he struggled to understand and interpret its implications. As late as 1952, he wrote: “We never experiment• Phys Rev with Lett just one (1995): electron “Demonstration or atom or (small) of molecule. a Fundamental In thought-experiments Quantum weLogic sometimes Gate” assume that we do; this invariably entails ridiculous consequences...”. • Rev. Mod Phys (2003): “Quantum Dynamics of Single Trapped Ions” In• orderSci Americanto illustrate the(2008): absurd “Quantum consequences Computing of moving between with Ions” the micro-world of quantum physics and our every-day macro-world, Schrödinger described a thought experiment with a cat: Schröding- er’s cat is completely isolated from the outside world inside a box. The box also contains a bottle of deadly cyanide which is released only after the decay of some radioactive atom, also inside the box. THE NOBEL PRIZE IN PHYSICS 2012 THE ROYAL SWEDISH ACADEMY OF SCIENCES HTTP://KVA.SE 3(6) Science French and U.S. Physicists Win Nobel Prize By DENNIS OVERBYE Published: October 9, 2012 Now scientists are able to direct experiments and catch nature in the act of being quantum and thus explore the boundary between quantum reality and normal life. Their work involves isolating the individual nuggets of nature — atoms and the particles that transmit light, known as photons — and making them play with each other. 1522Dr. Wineland’sD. workJ. WINKLAND has focusedAND WA onYNE theM. materialITAN 0 side of where20 matter meets light. His prize is the fourth Nobel awarded to a scientist associated with the excited electronic states, but we assume that we a resonant electric dipole transition (frequency, haveNationala narrow-band Institutelaser which can ofexcite Standardsthe andv,) in someTechnologyconvenient spectral overregion thewith pastradia- 15 years for work atom from one of the ground states to only one tive linewidth y/2w (full width at half-intensity excitedinvolvingelectronic state. the Thetrappingrelevant levels andare measuringpoints). Now of supposeatoms.that Dr.we irradiate Winelandthese and his showncolleaguesin Fig. 1. trap charged berylliumatoms atoms,with monochromatic, or ions, directed,in an electriclow intensi- field and cool Without laser. irradiation, the atoms eventually ty radiation tuned near, ' but slightly lower than, reachthemthermal withequilibrium speciallyby collisions tunedor inter- lasersthe soresonance that theyfrequency. are Webarelyassume thatmoving,the in- which is action with the background blackbody radiation. tensity is well below that which would cause satu- Therefore,anotherthe ratio wayof the ofnumber sayingof atoms theyin are very,ration (theverycase cold.of saturation is treated in Ref. state 2 to those in state 1 is given by the Boltz- 10), and that the thermalizing collision rate y, mann law: between atoms is much less than the natural line- width y, but is larger than the optical absorption N2/N~ = exp —(E, — )/As T [ E, j, 1522 rate (y»y, » absorptionD. J. rate,WINKLANDsee Sec.ANDVF).WA YNE M. ITAN 0 20 where k& = Boltzmann's constant, T = temperature, Those atoms of a particular velocity class moving excited electronic states, but we assume that we a resonant electric dipole and and N„N, are the respective energies against the radiation are Doppler shifted toward transition (frequency, E„E, have a narrow-band laser which can excite the v, in some convenient spectral region with radia- and numbers of atoms in the For sim- the resonant ) states. atom from one of the frequencyground statesv,toandonlyscatterone the incomingtive linewidth y/2w (full width at half-intensity plicity we assume that the ground state has only excitedlightelectronicat a higherstate. rateThe relevantthan thoselevelsatomsare movingpoints).with Now suppose that we irradiate these two nondegenerate energy levels; hence statistical shown thein Fig.radiation1. which are Doppler shifted awayatomsfromwith monochromatic, directed, low intensi- ' weight factors are absent in Eq.

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