Réalisation d'un faisceau d'ions-électrons monochromatiques à partir d'atomes refroidis par laser / Realisation of a monochromatic ion/electron beam based on laser-cooled atoms

Bruneau, Yoann

01 October 2014

Cette thèse porte sur l’étude d’une nouvelle source de particules chargées peu dispersive basée sur le refroidissement d’atomes par laser. Les technologies actuelles, basées sur des pointes fines de quelques nanomètres, sont limitées à des faisceaux de hautes énergies (champ d’accélération supérieur à 10 kV) et de fortes dispersions supérieures à 1 eV du fait des fortes interactions entre les particules se retrouvant très proches les unes des autres au moment de leur création. Une nouvelle source, basée sur un jet atomique refroidi transversalement et ionisé par lasers, permet d’étendre la zone de création des particules chargées à des dimensions de quelques centaines de micron et ainsi de limiter les intéractions entre les particules, tout en créant une source refroidie à 100 µK et ainsi très peu dispersive. Un guidage, utilisant la force dipolaire exercée par un laser appliqué le long de la propagation des atomes, est étudié expérimentalement et permet de piéger les atomes au centre du laser piégeur. En jouant sur la forme du laser, il est ainsi possible de concentrer les atomes dans une section de diamètre de l’ordre de 0,4 mm. Il est dès lors envisageable de créer une source de particules chargées avec des courants supérieurs au nA. L’ionisation des atomes du jet refroidi, basée sur l’ionisation d’atomes de Rydberg sous champ, est étudiée et comparée aux récentes expériences de photoionisation d’atomes refroidis dans un MOT-3D. / This thesis presents the creation of charged-particle beam based on a source with a low energy spread. Common sources, based on thin nanometer-size needle, allows to create charged-particles beams with a high energy (electric higher than 10 kV are used) and with a high energy spread (higher than 1 eV) due to interactions between particles created close to each other. A new source, based on an atomic beam cooled transversaly and ionized using lasers, allows to extend the size of the source until 100 µm and limit the interactions between particles while creating a cold source with temperatures as low as few 100 µK and thus with a low energy spread. A guiding laser applied along the propagation axis of the atomic beam uses the dipole force to concentrate the atoms in a area with a size as little as 0,4 mm while keeping the properties of low temperature of the atomic beam. With this kind of source, it is possible to create a charged-particle beam with a current greater than 1 nA. A new process of ionisation based Rydberg ionisation is studied in this thesis and compared to the early experiments based on photoionisation of cold atoms from a 3D-MOT.

Jet atomique

PMO

Laser pousseur-guideur

Rydberg

Photoionisation

Faisceau focalisable

Ions

Électrons

Brillance

Atomic beam

MOT

Pushing-guiding laser

Rydberg

Photoionisation

Focused beam

Ions

Electrons

Brightness

A high-intensity cold atom source

Borysow, Michael

27 September 2012

Presented in this thesis is the design and characterization of a new, high-flux source of cold atoms based on continuous, post-nozzle injection of lithium atoms into a cryogenic, supersonic helium jet. To date, experiments have been performed with lithium injection fractions up to [approximately equal to]10⁻⁶, where fluorescence spectroscopy reveals successful capture and thermalization of lithium atoms within the helium jet. The observed lithium beam copropagates with the helium jet and has a temperature of less than 10 mK, a brightness of 1.1x10¹⁹ m⁻² s⁻¹ sr⁻¹, and a brilliance of 3.1x10²⁰ m⁻² s⁻¹ sr⁻¹. Lithium atoms contained within a solid angle of [approximately equal to]0.018 sr are good candidates for future magnetic extraction. This results in a potentially capturable lithium flux of 1.1x10¹² s⁻¹, comparable to the existing record for a cold atomic beam. Also presented is preliminary data showing lithium fluorescence nearly 1 m downstream, demonstrating that the cold lithium beam can be successfully extracted from the seeding region. Numerical simulations reproduce capture efficiency to within 50%, suggesting that the process is well understood. We believe that successful seeding may be possible at a fraction up to 10⁻⁴. Seeding at this rate could produce an atomic beam with a flux as high as 1.3x10¹⁴ s⁻¹ at a phase-space density up to 1.6x10⁻⁷, corresponding to brightness and brilliance of order 10²² m⁻² s⁻¹ sr⁻¹ and 10²⁴ m⁻² s⁻¹ sr⁻¹ , respectively. If this novel cooling method performs as well at higher incident lithium flux, it could serve as a pump source and pave the way to the realization of the first truly continuous atom laser. / text

Physics

Cold atoms

Atomic beam

Supersonic jet

Post-nozzle

Seeded jet

Atom laser

Helium jet

Lithium source

Atomic oven

Cryopump

Cryosorption pump

MD simulations of atomic hydrogen scattering from zero band-gap materials

Kammler, Marvin

05 July 2019

No description available.

540

potential energy surface

genetic algorithm

surface scattering

graphene

atomic beam

molecular dynamics

ring polymer

nuclear quantum effect

nonadiabatic energy loss

Chemie  (PPN62138352X)

Comprehensive study on the low-energy atomic hydrogen beam : from production to velocity distribution measurement / 低エネルギー原子源の包括的研究 : 生成から速度分布測定まで / テイエネルギー ゲンシゲン ノ ホウカツテキ ケンキュウ : セイセイ カラ ソクド ブンプ ソクテイ マデ

島袋 祐次, Yuji Shimabukuro

22 March 2020

博士(工学) / Doctor of Philosophy in Engineering / 同志社大学 / Doshisha University

水素原子

原子源

速度分布関数

Atomic Hydrogen

Atomic beam source

Velocity distribution function

Co-desaceleração de dois alcalinos via laser e aumento de eficiência e novas formas de aprisionamento em armadilhas magneto-ópticas. / Simultaneous slowing of two alkali through laser and frequency enhancing and new ways of trapping in magneto-optical traps

Flemming Neto, Julio

03 May 1995

Nós demonstramos, pela primeira vez, o resfriamento via laser de um feixe atômico duplo. Ao se carregar um forno a 650oC com uma liga de Li179Na obtêm-se uma destilação efusiva que produz um feixe com fluxos idênticos de Li e de Na. Este feixe formado por duas espécies é desacelerado pela técnica Zeeman utilizando-se dessintonias iguais a Li = -850 MHz e Na = +150 MHz das respectivas transições atômicas 2S1/2 F = 2 2P3/2 F = 3. Em um segundo experimento, mostramos uma nova armadilha magneto-óptica bicromática, em cela de vapor. Obtivemos um incremento de ~10 vezes no número de átomos resfriados utilizando uma armadilha de Na do tipo I circundada por uma armadilha do tipo II, que não se superpõe à primeira. Isto ocorre quando temos o laser de captura a 12 MHz para o vermelho da transição 32S1/2 F = 2 32P3/2 F = 2. Em um terceiro experimento, observamos a primeira armadilha magneto-óptica para alcalinos operando na transição 2S1/2 2P1/2 (linha D1). Para o caso escolhido de átomos de sódio, obtêm-se quatro armadilhas diferentes dentro desta linha D1, contendo de 105 a 107 átomos resfriados. Para duas delas, é necessário inverter-se o sinal das polarizações circulares usuais dos lasers de resfriamento, devido aos desvios Zeeman negativos dos níveis hiperfinos inferiores / We demonstrate, for the first time, a laser cooling of a double atomic beam. By loading an oven at 650oC with a Li179Na alloy we get an effusive distillation producing a beam with equal fluxes of Li and Na. This two-species beam was laser cooled by Zeeman technique with Li = -850 MHz and Na = +150 MHz detunings from the corresponding 2S1/2 F = 2 2P3/2 F = 3 atomic transitions. In a second experiment, we show a new two-color vapor-cell magneto-optical trap. By surrounding type-I Na trap with a non-overlaping type-II trap we achieve a ~10-fold improvement in the number of cooled atoms. This is achieved when the capture laser is detuned 12 MHz to the red of the 32S1/2 F = 2 32P3/2 F = 2 transition. In a third experiment, we observe the first alkaline magneto-optical trap operating on 2S1/2 2P1/2 transition (D1 line). For the choosen sodium atoms, we have four different traps within D1 line, with 105 to 107 cooled atoms. For two of them, one has to revert the usual sign of circular polarizations of the cooling lasers, due to negative Zeeman shift of the lower hyperfine levels

Armadilha magneto-óptica

Atomic beam

D1 line

Destilação efusiva

Desvio Zeeman

Doppler cooling

Effusive distillation

Feixe atômico

Laser cooling

Linha D1

Lithium

Lítio

Magneto-optical trap

Near-absolute-zero temperatures

Pressão de radiação

Resfriamento Doppler

Resfriamento via laser

Rradiation pressure

Sódio

Sodium

Temperaturas próximas ao zero absoluto

Zeeman shift

Co-desaceleração de dois alcalinos via laser e aumento de eficiência e novas formas de aprisionamento em armadilhas magneto-ópticas. / Simultaneous slowing of two alkali through laser and frequency enhancing and new ways of trapping in magneto-optical traps

Julio Flemming Neto

03 May 1995

Nós demonstramos, pela primeira vez, o resfriamento via laser de um feixe atômico duplo. Ao se carregar um forno a 650oC com uma liga de Li179Na obtêm-se uma destilação efusiva que produz um feixe com fluxos idênticos de Li e de Na. Este feixe formado por duas espécies é desacelerado pela técnica Zeeman utilizando-se dessintonias iguais a Li = -850 MHz e Na = +150 MHz das respectivas transições atômicas 2S1/2 F = 2 2P3/2 F = 3. Em um segundo experimento, mostramos uma nova armadilha magneto-óptica bicromática, em cela de vapor. Obtivemos um incremento de ~10 vezes no número de átomos resfriados utilizando uma armadilha de Na do tipo I circundada por uma armadilha do tipo II, que não se superpõe à primeira. Isto ocorre quando temos o laser de captura a 12 MHz para o vermelho da transição 32S1/2 F = 2 32P3/2 F = 2. Em um terceiro experimento, observamos a primeira armadilha magneto-óptica para alcalinos operando na transição 2S1/2 2P1/2 (linha D1). Para o caso escolhido de átomos de sódio, obtêm-se quatro armadilhas diferentes dentro desta linha D1, contendo de 105 a 107 átomos resfriados. Para duas delas, é necessário inverter-se o sinal das polarizações circulares usuais dos lasers de resfriamento, devido aos desvios Zeeman negativos dos níveis hiperfinos inferiores / We demonstrate, for the first time, a laser cooling of a double atomic beam. By loading an oven at 650oC with a Li179Na alloy we get an effusive distillation producing a beam with equal fluxes of Li and Na. This two-species beam was laser cooled by Zeeman technique with Li = -850 MHz and Na = +150 MHz detunings from the corresponding 2S1/2 F = 2 2P3/2 F = 3 atomic transitions. In a second experiment, we show a new two-color vapor-cell magneto-optical trap. By surrounding type-I Na trap with a non-overlaping type-II trap we achieve a ~10-fold improvement in the number of cooled atoms. This is achieved when the capture laser is detuned 12 MHz to the red of the 32S1/2 F = 2 32P3/2 F = 2 transition. In a third experiment, we observe the first alkaline magneto-optical trap operating on 2S1/2 2P1/2 transition (D1 line). For the choosen sodium atoms, we have four different traps within D1 line, with 105 to 107 cooled atoms. For two of them, one has to revert the usual sign of circular polarizations of the cooling lasers, due to negative Zeeman shift of the lower hyperfine levels

Armadilha magneto-óptica

Destilação efusiva

Desvio Zeeman

Feixe atômico

Linha D1

Lítio

Pressão de radiação

Resfriamento Doppler

Resfriamento via laser

Sódio

Temperaturas próximas ao zero absoluto

Atomic beam

D1 line

Doppler cooling

Effusive distillation

Laser cooling

Lithium

Magneto-optical trap

Near-absolute-zero temperatures

Rradiation pressure

Sodium

Zeeman shift