Crystal orientation dependence of ionization rates in germanium

Matsukawa, Takashi; Kagawa, S.; Kaneda, T.; Toyama, Y.; Mikami, Osamu

doi:10.1063/1.91932

Cited by 52 publications

(25 citation statements)

References 7 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The multiplication process is initiated by electrons and holes, and both are multiplied within the intrinsic region. According to the impact ionization theory [21][22][23][24] , a high excess noise factor should then be obtained as electrons and holes have quite similar impact ionization coefficients in Ge 25 . However, a narrow width multiplication region (500 nm) was chosen in the design to promote a large dead space effect 23,26 contribution favouring an efficient reduction of the excess noise factor.…”

Section: Resultsmentioning

confidence: 99%

Germanium avalanche receiver for low power interconnects

et al. 2014

View full text Add to dashboard Cite

Recent advances in silicon photonics have aided the development of on-chip communications. Power consumption, however, remains an issue in almost all integrated devices. Here, we report a 10 Gbit per second waveguide avalanche germanium photodiode under low reverse bias. The avalanche photodiode scheme requires only simple technological steps that are fully compatible with complementary metal oxide semiconductor processes and do not need nanometre accuracy and/or complex epitaxial growth schemes. An intrinsic gain higher than 20 was demonstrated under a bias voltage as low as À 7 V. The Q-factor relating to the signal-to-noise ratio at 10 Gbit per second was maintained over 20 dB without the use of a trans-impedance amplifier for an input optical power lower than À 26 dBm thanks to an aggressive shrinkage of the germanium multiplication region. A maximum gain over 140 was also obtained for optical powers below À 35 dBm. These results pave the way for low-powerconsumption on-chip communication applications.

show abstract

Section: Resultsmentioning

confidence: 99%

Germanium avalanche receiver for low power interconnects

et al. 2014

View full text Add to dashboard Cite

show abstract

“…Germanium (Ge) was chosen as the material of choice in the I-MOS because its for both electrons and holes are much higher than in Si [14], [15]. In Si, is much lower than [16].…”

Section: Device Simulations: Basics Of Device Operationmentioning

confidence: 99%

“…Impact-ionization coefficients were calibrated to available experimental data on Ge devices [14], [15]. Fig.…”

Section: Device Simulations: Basics Of Device Operationmentioning

confidence: 99%

Impact Ionization MOS (I-MOS)—Part I: Device and Circuit Simulations

Gopalakrishnan

Griffin

Plummer

2005

IEEE Trans. Electron Devices

286

127

View full text Add to dashboard Cite

Abstract-One of the fundamental problems in the continued scaling of transistors is the 60 mV/dec room temperature limit in the subthreshold slope. In part I this work, a novel transistor based on the field-effect control of impact-ionization (I-MOS) is explored through detailed device and circuit simulations. The I-MOS uses gated-modulation of the breakdown voltage of a p-i-n diode to switch from the OFF state to the ON state and vice-versa. Device simulations using MEDICI show that the I-MOS has a subthreshold slope of 5 mV/dec or lower and ON 1 mA m at 400 K. Simulations were used to further explore the characteristics of the I-MOS including the transients of the turn-on mechanism, the short-channel effect, scalability, and other important device attributes. Circuit mode simulations were also used to explore circuit design using I-MOS devices and the design of an I-MOS inverter. These simulations indicated that the I-MOS has the potential to replace CMOS in high performance and low power digital applications. Part II of this work focuses on I-MOS experimental results with emphasis on hot carrier effects, germanium p-i-n data and breakdown in recessed structure devices.Index Terms-Avalanche, avalanche photodiode (APD), gate control of impact ionization, impact-ionization avalanche transit-time (IMPATT), germanium, hot carriers, impactionization (I-MOS), kT/q, low static power, modulated breakdown, MOSFET, nonlinearity, p-i-n, silicon, subthreshold slope, 5 mV/dec.

show abstract

“…The materials parameters of both the materials are taken from recent experimental reports [8][9][10] are shown in Table 1 The ionization rate in Ge is observed to be higher by an order of magnitude than Si at the same electric field. The gap in the values of carrier ionization rate in Si and Ge further widens as the Ge layer remains near the high field junction plane where as Si layer is considered away from the junction.…”

Section: Resultsmentioning

confidence: 99%

“…Material parameters like the ionization rate, drift velocities etc., of all the materials have been taken from the recently reported published literature [8][9][10]. The diode active layer width is divided into large number of space steps of 1 nm per micron or less.…”

Section: Analysis Under Static Conditionsmentioning

confidence: 99%

Possible Realization of Near Optimum Efficiency from n-Si-Ge/p-Ge-Si DDR Hetero Structure IMPATT Diode

Tripathy¹,

Mukherjee²,

Pati³

2012

IJME

View full text Add to dashboard Cite

Avalanche breakdown in a p-n junction can generate rf negative resistance due to twin delay mechanism (Avalanche Delay associated with growth of charge bump and transit time delay caused due to time elapsed for the grown charge bump drifting through the depletion zone) leading to generation of high frequency power in IMPATT mode. With the advancement of device technology and with the motive of furtherance of device performance,

show abstract

Crystal orientation dependence of ionization rates in germanium

Cited by 52 publications

References 7 publications

Germanium avalanche receiver for low power interconnects

Germanium avalanche receiver for low power interconnects

Impact Ionization MOS (I-MOS)—Part I: Device and Circuit Simulations

Possible Realization of Near Optimum Efficiency from n-Si-Ge/p-Ge-Si DDR Hetero Structure IMPATT Diode

Contact Info

Product

Resources

About