Simulation Analysis in Sub-0.1 μm for Partial Isolation Field-Effect Transistors

Kim, Young Kwon; Lee, Jin Sung; Kim, Geon; Park, Tae‐Sik; Kim, Huijung; Cho, Young Pyo; Park, Young June; Lee, Myoung Jin

doi:10.3390/electronics7100227

Cited by 3 publications

(6 citation statements)

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“…In this paper, we proposed a new device with a partial isolation region under the storage node of conventional S-FinFET. This structure can be fabricated by using an isotropic dry etching technique for the buried insulator under the cell transistor [7,8]. We analyzed electrical characteristics of this proposed device and compared them with those of conventional S-FinFETs of the same size.…”

Section: Introductionmentioning

confidence: 99%

“…The proposed FinFET exhibited four times lower I off than modified S-FinFET, called RFinFET, with more improved drain-induced barrier lowering (DIBL) characteristics, while minimizing I on reduction compared to RFinFET. Our results also confirmed that the proposed device showed improved drain-induced barrier lowering (DIBL) and I off characteristics as gate channel length decreased.Keywords: gate-induced drain leakage (GIDL); drain-induced barrier lowering (DIBL); recessed channel array transistor (RCAT); on-current (I on ); off-current (I off ); subthreshold slope (SS); threshold voltage (V TH ); saddle FinFET (S-FinFET); potential drop width (PDW); shallow trench isolation (STI); technique for the buried insulator under the cell transistor [7,8]. We analyzed electrical characteristics of this proposed device and compared them with those of conventional S-FinFETs of the same size.…”

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confidence: 99%

“…Keywords: gate-induced drain leakage (GIDL); drain-induced barrier lowering (DIBL); recessed channel array transistor (RCAT); on-current (I on ); off-current (I off ); subthreshold slope (SS); threshold voltage (V TH ); saddle FinFET (S-FinFET); potential drop width (PDW); shallow trench isolation (STI); technique for the buried insulator under the cell transistor [7,8]. We analyzed electrical characteristics of this proposed device and compared them with those of conventional S-FinFETs of the same size.…”

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Partial Isolation Type Saddle-FinFET(Pi-FinFET) for Sub-30 nm DRAM Cell Transistors

et al. 2018

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In this paper, we proposed a novel saddle type FinFET (S-FinFET) to effectively solve problems occurring under the capacitor node of a dynamic random-access memory (DRAM) cell and showed how its structure was superior to conventional S-FinFETs in terms of short channel effect (SCE), subthreshold slope (SS), and gate-induced drain leakage (GIDL). The proposed FinFET exhibited four times lower I off than modified S-FinFET, called RFinFET, with more improved drain-induced barrier lowering (DIBL) characteristics, while minimizing I on reduction compared to RFinFET. Our results also confirmed that the proposed device showed improved drain-induced barrier lowering (DIBL) and I off characteristics as gate channel length decreased.Keywords: gate-induced drain leakage (GIDL); drain-induced barrier lowering (DIBL); recessed channel array transistor (RCAT); on-current (I on ); off-current (I off ); subthreshold slope (SS); threshold voltage (V TH ); saddle FinFET (S-FinFET); potential drop width (PDW); shallow trench isolation (STI); technique for the buried insulator under the cell transistor [7,8]. We analyzed electrical characteristics of this proposed device and compared them with those of conventional S-FinFETs of the same size. We also showed the optimized parameters of the buried insulator using a three-dimensional (3D) device simulator in sub-30 nm cell size [9]. The device described in this paper has reliable source/drain (S/D) doping concentration with a Gaussian profile. The simulator is well tuned to predict DRAM cell transistor leakage distribution [10,11]. Device StructureThe partial isolation type S-FinFET (Pi-FinFET) is a structure with a buried insulator at a certain depth from the storage node of a conventional S-FinFET. Figure 1a shows a 3D schematic of a Pi-FinFET. Silicon film thickness, buried insulator thickness, and L in , as shown in Figure 1a,b, are defined as the distance from the contact surface of the storage node to the buried insulator, the thickness of the buried insulator in the direction perpendicular to the channel, and the distance from the side gate oxide to the buried insulator, respectively. L g , L side , L ov_xj , and L ov_side represent gate channel length, the length of the side-gate in the direction parallel to the channel, the overlapped length of the side-gate and S/D doping region shown in Figure 1a, and the side-channel width shown in Figure 1c, respectively. When L side and L ov_xj are increased, the width of the overlap region of the gate and the S/D region will also increase. The n + poly gate with a gate work function of 4.2 eV was applied. L g , L side , L ov_side and the recessed depth are 30 nm, 42 nm, 10 nm, and 100 nm, respectively. RFinFET is the modified S-FinFET with a structure in which the overlap region between the side-gate and the S/D region is removed [5]. Therefore, the Pi-FinFETs proposed in this paper can be divided into Pi-SFinFET and Pi-RFinFET depending on the presence or absence of the overlap region between the side-gate and the S/D region. Namely, in...

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Partial Isolation Type Saddle-FinFET(Pi-FinFET) for Sub-30 nm DRAM Cell Transistors

et al. 2018

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“…This issue collected two approaches to achieve a steep SS: (1) using the insulator-metal phase transition of VO 2 to achieve a decent SS of 42 mV/dec [6]; (2) using an L-shaped tunneling FET to improve the SS [7]. In addition, the drain-induced barrier lowering (DIBL) effect and leakage of a partial isolation FET for sub-0.1 µm have been studied [8].…”

Section: The Current Research Trendsmentioning

confidence: 99%

Nanoelectronic Materials, Devices and Modeling: Current Research Trends

Zhu

2019

Electronics

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“…To address this issue, Pi-FinFETs (Pi-SFinFET, Pi-RFinFET) that have a partial isolation region under the storage node of S-FinFETs (SFinFET, RFinFET) have been proposed [12][13][14]. However, in Pi-FinFETs fabricated using an isotropic dry etching technique where the insulator is buried under the cell transistor [15,16], the buried insulator can cause an interface trap between itself and the drain region [17]. Consequently, this can have an adverse effect on leakage current.…”

Section: Introductionmentioning

confidence: 99%

S-TAT Leakage Current in Partial Isolation Type Saddle-FinFET (Pi-FinFET)s

Park¹,

Kim²,

Kim³

et al. 2021

IEEE Access

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In this paper, we compare conventional saddle type FinFETs to partial isolation type saddle FinFETs (Pi-FinFETs) using 3D TCAD simulations to examine the effect of single charge traps for proper prediction of leakage current. We simulated single charge traps at various locations in the drain region, and analyzed how the traps affect leakage current. Our results show that Pi-FinFETs enhanced the leakage current characteristics given the presence of a single charge trap. Also, it was found that Pi-FinFETs exhibit half the F TAT of S-FinFETs. Based on the results from our analysis method, where we use I off fluctuation, the F TAT , the σ F and the P F parameters to accurately compare performance, and present device design guidelines aimed at improving DRAM refresh characteristics. INDEX TERMSPartial isolation type FinFET (Pi-FinFET); Potential Drop Width (PDW); Band-to-Band Tunneling (BTBT); Trap-Assisted Tunneling (TAT); Gate-Induced Drain Leakage (GIDL); On current (I on ); Off current (I off );

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Simulation Analysis in Sub-0.1 μm for Partial Isolation Field-Effect Transistors

Cited by 3 publications

References 19 publications

Partial Isolation Type Saddle-FinFET(Pi-FinFET) for Sub-30 nm DRAM Cell Transistors

Partial Isolation Type Saddle-FinFET(Pi-FinFET) for Sub-30 nm DRAM Cell Transistors

Nanoelectronic Materials, Devices and Modeling: Current Research Trends

S-TAT Leakage Current in Partial Isolation Type Saddle-FinFET (Pi-FinFET)s

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