Nanowire transistors without junctions

Colinge, Jean–Pierre; Lee, Chi‐Woo; Afzalian, Aryan; Akhavan, Nima Dehdashti; Yan, Ran; Ferain, I.; Razavi, Pedram; O'Neill, B.; Blake, Alan; White, Mark H.; Kelleher, Ann; McCarthy, Brendan; Murphy, Richard J.

doi:10.1038/nnano.2010.15

Cited by 2,191 publications

(1,023 citation statements)

References 13 publications

Supporting

Mentioning

943

Contrasting

Unclassified

Order By: Relevance

“…However, work must continue into applications of the MLD process on new device architectures such as junction-less transistors and gate-all-around transistors. [65,66] Aside from microelectronics, the MLD process has also been successfully applied with great success to solar cell materials and optoelectronic materials. Concurrently, there is a need for innovative improvements to metrological techniques to be made in order for the ultra-shallow junctions to be characterised to ensure conformality and abruptness.…”

Section: Discussionmentioning

confidence: 99%

Chemical approaches for doping nanodevice architectures

et al. 2016

View full text Add to dashboard Cite

Access to the full text of the published version may require a subscription. after most spin-on-doping processes which are often difficult to remove. In-situ doping of nanostructures is especially common for bottom-up grown nanostructures but problems associated with concentration gradients and morphology changes are commonly experienced. Monolayer doping (MLD) has been shown to satisfy the requirements for extended defect-free, conformal and controllable doping on many materials ranging from traditional silicon and germanium devices to emerging replacement materials such as III-V compounds but challenges still remain, especially with regard to metrology and surface chemistry at such small feature sizes. This article summarises and critically assesses developments over the last number of years regarding the application of gas and solution phase techniques to dope silicon-, germanium-and III-V-based materials and nanostructures to obtain shallow diffusion depths coupled with high carrier concentrations and abrupt junctions. Rights3

show abstract

Section: Discussionmentioning

confidence: 99%

Chemical approaches for doping nanodevice architectures

et al. 2016

View full text Add to dashboard Cite

show abstract

“…The mechanism of the leakage current is discussed using the activation energy (E A The junctionless (JL) metal-oxide-semiconductor fieldeffect transistor (MOSFET) has been recently introduced and is a promising candidate for end-of-roadmap complementary metal-oxide-semiconductor (CMOS) circuit fabrication. 1,2 In a JL transistor, the doping concentration is constant through the source, and channel and drain are doped. Typical doping concentration is in the range of few 10 19 cm À3 .…”

mentioning

confidence: 99%

Characterization of a junctionless diode

Ferain

Akhavan

et al. 2011

Applied Physics Letters

Self Cite

View full text Add to dashboard Cite

A diode has been realised using a silicon junctionless (JL) transistor. The device contains neither PN junction nor Schottky junction. The device is measured at different temperatures. The characteristics of the JL diode are essentially identical to those of a regular PN junction diode. The JL diode has an on/off current ratio of 10(8), an ideality factor of 1.09, and a reverse leakage current of 1 x 10(-14) A at room temperature. The mechanism of the leakage current is discussed using the activation energy (E-A). The turn-on voltage of the device can be tuned by JL transistor threshold voltage. (C) 2011 American Institute of Physics. (doi: 10.1063/1.3608150

show abstract

“…To overcome the technological difficulties in the formation of ultra-sharp S/D extension regions in nanoscale devices, the concept of the junctionless (JL) MOS transistor in silicon-on-insulator (SOI) and bulk technologies has been recently reported [1][2][3]. The JL transistor is an MOS device where the channel doping is the same as that of heavily doped S/D regions.…”

Section: Junctionless 6t Sram Cellmentioning

confidence: 99%

Junctionless 6T SRAM cell

et al. 2010

View full text Add to dashboard Cite

The design of a 6T SRAM cell with 20 nm junctionless (JL) MOSFETs is reported. It is shown that a 6T SRAM cell designed with JL MOSFETs achieves a high static noise margin (SNM) of 185 mV, retention noise or hold margin (RNM) of 381 mV and writability current (I WR ) of 33 mA along with a low leakage current (I LEAK ) of 2 pA at a supply voltage (V DD ) of 0.9 V for cell and pullup ratios of 1. Results offer a new opportunity to design future SRAM cells with nanoscale JL MOSFETs.Introduction: Lateral doping gradient or abruptness of source/drain (S/D) extension regions is a key process/device parameter which significantly impacts the S/D series resistance as well as short-channel effects (SCEs) in nanoscale MOS devices and is a crucial technological factor limiting device scaling into the nanoscale regime. To overcome the technological difficulties in the formation of ultra-sharp S/D extension regions in nanoscale devices, the concept of the junctionless (JL) MOS transistor in silicon-on-insulator (SOI) and bulk technologies has been recently reported [1][2][3]. The JL transistor is an MOS device where the channel doping is the same as that of heavily doped S/D regions. The use of identical doping in the S/D and channel regions circumvents the necessity of controlling S/D gradients in the extension regions near the gate edge. In this work we analyse the performance of a 6T SRAM cell comprising JL MOSFETs and demonstrate its superiority over conventional 6T SRAM with inversion mode devices.

show abstract

Nanowire transistors without junctions

Cited by 2,191 publications

References 13 publications

Chemical approaches for doping nanodevice architectures

Chemical approaches for doping nanodevice architectures

Characterization of a junctionless diode

Junctionless 6T SRAM cell

Contact Info

Product

Resources

About