Feasibility study of cadmium zinc telluride growth using a submerged heater in a vertical bridgman system

Yeckel, Andrew; Derby, Jeffrey J.

doi:10.1007/s11664-004-0036-7

Cited by 12 publications

(5 citation statements)

References 34 publications

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“…The simulations were conducted using CdTe properties, because CdTe and CZT are particularly difficult to grow, in part due to their low thermal conductivity ( λ CZT ≈ 1 W m‐K −1 ). [ 12,26 ] Thus, in the VB configuration without a baffle, the s/l interface of CZT is usually concave. [ 26 ]…”

Section: Numerical Model and Methodologymentioning

confidence: 99%

“…Numerous further papers discussed this approach. [6,[11][12][13][14] The former approach involves also VB growth techniques with permanent magnetic fields, [15,16] while the latter includes rotating/oscillating/vibrating baffle/ampoule [10,11,17,18] and magnetic stirring by unsteady rotating [19] and traveling magnetic fields. [20] The vibrational techniques are well known as accelerated crucible rotation technique, the angular vibration technique, the coupled vibrational stirring of the ampoule, and ultrasonic vibrations.…”

Section: Introductionmentioning

confidence: 99%

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Interface Shape under the Insulating Baffle in Vertical Bridgman Systems

Dropka

Ostrogorsky

2022

Crystal Research and Technology

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In the vertical Bridgman (VB) configuration, the shape of the solid–liquid (s/l) interface controls the yield and quality of single crystals. The two key effects for growing CdTe in VB configuration with the baffle is are considered: i) the thermal conductivity of the baffle and 2) baffle/crystal rotation. The baffle has a dominating effect on heat transfer to the s/l interface. The low thermal conductivity baffle (λ = 0.3 W m‐K−1) shields the s/l interface from the hot zones of the furnace above the baffle, so that the furnace temperature has to be increased, thus enforcing convex interface. The insulating baffle is expected to be particularly useful for growth of low conductivity crystals such as CdTe or CZT because heat conduction through the crystal is slow. The flow driven by the rotating crystal (i.e., ampoule) makes the interface less convex. By rotating the crystal relative to the baffle, the undesirable, unsteady natural convection can be made negligible compared to forced convection, thus providing steady laminar flow at the s/l interface.

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Section: Numerical Model and Methodologymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Interface Shape under the Insulating Baffle in Vertical Bridgman Systems

Dropka

Ostrogorsky

2022

Crystal Research and Technology

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“…Our initial studies focused on infrared detector material grown by both vertical [59,[126][127][128][129][130] and horizontal [131][132][133] Bridgman techniques. Yeckel and Derby [137,138] studied the influences of transient flows driven by the accelerated crucible rotation technique (ACRT) on zinc segregation; in [139], they considered the effects of a submerged heater on shaping the interface during CZT growth. Yeckel and Derby [137,138] studied the influences of transient flows driven by the accelerated crucible rotation technique (ACRT) on zinc segregation; in [139], they considered the effects of a submerged heater on shaping the interface during CZT growth.…”

Section: Motivationmentioning

confidence: 99%

Heat Transfer Analysis and Design for Bulk Crystal Growth: Perspectives on the Bridgman Method

Derby

Yeckel

2015

Handbook of Crystal Growth

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“…The end result is that typical yields of useable material from a crystalline boule remain at 10% or lower, resulting in very high materials costs. Our modeling efforts have been directed to better understand the difficulties of CZT growth and suggest improvements [66][67][68][69][70][71][72][73][74][75][76][77][78].…”

Section: Examples Of Numerical Modeling: Growth Of Cztmentioning

confidence: 99%

Modeling and bulk crystal growth processes: What is to be learned?

Derby¹,

Wang²,

Tsukamoto³

et al. 2010

AIP Conference Proceedings

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Modeling is an important tool to better understand crystal growth. This assertion is discussed via examples of classical models that have proven to be enlightening. The discussion continues with a brief primer on the mathematical governing equations of continuum and interfacial phenomena important in crystal growth processes and several techniques that can be applied to these equations for analysis, including scaling and numerical methods. Finally, some examples of modeling a melt growth system are presented to illustrate modern applications.

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Feasibility study of cadmium zinc telluride growth using a submerged heater in a vertical bridgman system

Cited by 12 publications

References 34 publications

Interface Shape under the Insulating Baffle in Vertical Bridgman Systems

Interface Shape under the Insulating Baffle in Vertical Bridgman Systems

Heat Transfer Analysis and Design for Bulk Crystal Growth: Perspectives on the Bridgman Method

Modeling and bulk crystal growth processes: What is to be learned?

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