Nanocrystal growth in alkali halides observed by exciton spectroscopy

Haselhoff, M.; Weber, Helmut

doi:10.1103/physrevb.58.5052

Cited by 40 publications

(22 citation statements)

References 38 publications

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“…Experimental investigations of the kinetics of nucleation on model solutions were also performed at a fixed temperature [4][5][6][7][8][9] or with a temperature jump [10,11]. Under nonisothermal conditions, changes in the supersatu ration and critical radius are caused by both the nucle ation and variation in the temperature, which makes it possible to control the growth of a new phase and to obtain new data for the development of the nucleation theory.…”

Section: Introductionmentioning

confidence: 99%

Nonisothermal nucleation in the CuCl solid solution in glass: Nucleation under continuous cooling of the solid solution

Leiman¹,

Valov²,

Maksimov³

et al. 2015

Phys. Solid State

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The processes of nonisothermal nucleation in the CuCl solid solution in glass under continuous cooling from 700 to 500°C have been investigated. It has been shown that, in the studied cooling modes, regardless of the cooling rate, two distributions of CuCl nanoparticles with radii in the ranges of 8-20 and 2.5-3.5 nm in the absence of particles with intermediate radii are formed. The simulation of the nucleation under continuous cooling of the solid solution has revealed some features in the kinetics of the formation of two distributions of nanoparticles that differ significantly in size. It has been found that, under specific con ditions, there can arise one wide distribution (strongly overlapping distributions). The role of a change in the critical radius during the nonisothermal nucleation (cooling of the solid solution) in the formation of a binary distribution has been demonstrated.

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Section: Introductionmentioning

confidence: 99%

Nonisothermal nucleation in the CuCl solid solution in glass: Nucleation under continuous cooling of the solid solution

Leiman¹,

Valov²,

Maksimov³

et al. 2015

Phys. Solid State

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“…Образование новой фазы в твердом растворе при изо-термическом отжиге теоретически и экспериментально достаточно хорошо изучено [1][2][3][4][5][6]. Процессы выделения новой фазы в твердых растворах на стадии их разогрева до температуры изотермического отжига представляют собой важную и недостаточно изученную проблему.…”

Section: Introductionunclassified

Неизотермическая нуклеация в твердом растворе CuCl в стекле: концентрационный эффект при нагреве твердого раствора

Лейман¹,

Ашкалунин²,

Деркачева³

et al. 2017

Физика Твердого Тела

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Изучено влияние скорости нагрева твердого раствора CuCl в стекле на распределение по размерам образующихся наночастиц CuCl. Кривые распределений нанокристаллов CuCl определялись методом экситонно-термического анализа. Установлено, что при замедлении нагрева образца от 2 до 60 min концентрация наночастиц CuCl возрастает в десятки раз, а средний радиус частиц уменьшается почти в два раза. В процессе нагрева образца концентрация образующихся наночастиц CuCl проходит через максимум. Численное моделирование нуклеации при медленном нагреве твердого раствора показало, что образование максимума концентрации кластеров новой фазы обусловлено быстрым ростом критического радиуса из-за роста температуры и уменьшения пересыщения раствора. В результате при некоторой температуре прекращается образование зародышей новой фазы, а часть ранее образовавшихся кластеров растворяется. DOI: 10.21883/FTT.2017.09.44856.273

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“…However, both techniques do not have the capability to follow the reaction of nanoparticle formation continuously from the nucleation to final growth stages. Unlike known structural techniques, the optical absorption method, worked out by Hasselhoff and Weber [9], allows us to analyze different states of precursors, in particular metal ions in matrix molecules and semiconductor nanocrystals. Moreover, this method permits us to determine the nanocrystal size changing during the growth process.…”

Section: Introductionmentioning

confidence: 99%

PbS nanoparticles in Langmuir–Blodgett films: kinetics of formation and growth

Savin¹,

Vitushkina

2004

Physica Status Solidi (b)

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The formation and growth of lead sulfide nanocrystals in lead stearate Langmuir-Blodgett (LB) films are investigated by optical absorption spectroscopy. Kinetics of the concentration changes of lead ions in the different states formed during the growth process, as well as the evolution of the nanocrystal average size versus growth time, are studied. A nonlinear dependence of the nanoparticle growth rate versus time is found. The idea of diffusive decomposition of solid solutions is used to analyze the experimental results. It is shown that high concentrations of metal ions at the interfaces of monolayers of LB films, as well as diffusion restrictions of mass-transfer processes, play a decisive role in the formation and growth of nanocrystals in ordered organic matrices.

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Nanocrystal growth in alkali halides observed by exciton spectroscopy

Cited by 40 publications

References 38 publications

Nonisothermal nucleation in the CuCl solid solution in glass: Nucleation under continuous cooling of the solid solution

Nonisothermal nucleation in the CuCl solid solution in glass: Nucleation under continuous cooling of the solid solution

Неизотермическая нуклеация в твердом растворе CuCl в стекле: концентрационный эффект при нагреве твердого раствора

PbS nanoparticles in Langmuir–Blodgett films: kinetics of formation and growth

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