Second Harmonic Generation characterization of SOI wafers: Impact of layer thickness and interface electric field

Damianos, Dimitrios; Vitrant, G.; Lei, Ming; Changala, J.; Kaminski‐Cachopo, Anne; Blanc-Pélissier, D.; Cristoloveanu, S.; Ionica, I.

doi:10.1016/j.sse.2017.12.006

Cited by 7 publications

(2 citation statements)

References 12 publications

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“…Therefore when thin Si films are used, SHG measurements allow accessing the interfacial electric field partially due to the interface trap density. Note that the interface of interest is the film-BOX, while the one that dominates the SHG is the top one (film-passivation or native oxide) (29). However if the SOI film thickness is below the absorption limit at the double frequency (~70 nm thickness for 380 nm wavelength of SHG), it is possible to develop a strategy to access the buried interface.…”

Section: Soi With T Box = 145nmmentioning

confidence: 99%

(Invited) Second Harmonic Generation: A Powerful Non-Destructive Characterization Technique for Dielectric-on-Semiconductor Interfaces

et al. 2020

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The second harmonic generation (SHG) proved to be a very promising characterization technique for dielectric-semiconductor interfaces because it is sensitive, non-destructive, can be applied directly on wafer, at different stages of wafer processing. The method, based on non-linear optics effects, is measuring a signal encompassing the "static" electric field at the dielectricsemiconductor interface which is directly related to the oxide charges Q ox and to the interface state density D it. A general methodology for Q ox and D it extraction from SHG measurements requires (i) calibration based on parameters obtained by classical electrical methods and (ii) modeling to capture the optical propagation phenomena that impact the SHG signal. In this paper, we discuss these issues based on a review of our recent advances on how to exploit SHG for dielectrics on semiconductor characterization.

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Section: Soi With T Box = 145nmmentioning

confidence: 99%

(Invited) Second Harmonic Generation: A Powerful Non-Destructive Characterization Technique for Dielectric-on-Semiconductor Interfaces

et al. 2020

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“…Optical second harmonic generation (SHG) is a nonlinear optical phenomenon that serves as a sensitive probe for studying buried solids and interfacial properties [11]. The sensitivity of SHG to interfacial electrical properties, such as charge traps [12] and doping levels [13,14], makes it as a unique characterization technique. In the centrosymmetric materials, dipole contributions at the lowest order are typically prohibited, except the dipole contribution at the interface where inversion symmetry is disrupted due to material discontinuity as well as the interfacial electric field.…”

Section: Introductionmentioning

confidence: 99%

The study of interface quality in HfO₂/Si films probed by second harmonic generation

Ye,

Zhang,

Wang

et al. 2024

J. Phys. D: Appl. Phys.

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Time-dependent second harmonic generation (TD-SHG) is an emergent sensitive and non-contact method to qualitatively/quantitively characterize the semiconductor materials, which is closely related to the interfacial electric field. Here, the TD-SHG technique is used to study the interface quality of atomic layer deposited 15 nm HfO2/Si (n-type/p-type) samples, which is compared to the conventional electrical characterization method. A relation between the interface state density and the time constant extracted from TD-SHG is revealed, indicating that TD-SHG is an effective method to evaluate the interface state density. In addition, the dopant type and dopant density can be disclosed by resolving the dynamic process of TD-SHG. The scenario of interfacial electric field between the initial electric field and the laser-induced electric field is proposed to explain the time-dependent evolution of SHG signal. In conclusion, the TD-SHG is a sensitive and non-contact method as well as simple and fast to characterize the semiconductor materials, which may facilitate the semiconductor in-line testing.

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The pseudo-MOSFET

Cristoloveanu¹

2021

Fully Depleted Silicon-on-Insulator

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Second Harmonic Generation characterization of SOI wafers: Impact of layer thickness and interface electric field

Cited by 7 publications

References 12 publications

(Invited) Second Harmonic Generation: A Powerful Non-Destructive Characterization Technique for Dielectric-on-Semiconductor Interfaces

(Invited) Second Harmonic Generation: A Powerful Non-Destructive Characterization Technique for Dielectric-on-Semiconductor Interfaces

The study of interface quality in HfO₂/Si films probed by second harmonic generation

The pseudo-MOSFET

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Second Harmonic Generation characterization of SOI wafers: Impact of layer thickness and interface electric field

Cited by 7 publications

References 12 publications

(Invited) Second Harmonic Generation: A Powerful Non-Destructive Characterization Technique for Dielectric-on-Semiconductor Interfaces

(Invited) Second Harmonic Generation: A Powerful Non-Destructive Characterization Technique for Dielectric-on-Semiconductor Interfaces

The study of interface quality in HfO2/Si films probed by second harmonic generation

The pseudo-MOSFET

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Product

Resources

About

The study of interface quality in HfO₂/Si films probed by second harmonic generation