Integration of RF-MEMS resonators on submicrometric commercial CMOS technologies

Lopez, J.L.; Verd, J.; Teva, J.; Murillo, Gonzalo; Giner, J.; Torres, F.; Uranga, A.; Abadal, G.; Barniol, N.

doi:10.1088/0960-1317/19/1/015002

Cited by 80 publications

(48 citation statements)

References 21 publications

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“…Previous attempts to extend the photoresponse of silicon-based devices into the short-wavelength infrared regime (l ¼ 1,400-3,000 nm) at room temperature focused on forming heterostructures with SiGe alloys [6][7][8] or microstructures of thermally absorbing material 9,10 , and modifying the intrinsic band structure via intentional introduction of defects [11][12][13][14][15][16][17] . Growing microstructures of foreign materials on top of silicon results in processing complexities that can compromise CMOS compatibility 18,19 . Furthermore, integration of thermally absorbing materials can be effective for short-wavelength infrared response but results in slow pixel response times intrinsically limited by the thermal time constant, which hinders applications in array-based real-time imaging systems at room temperature 10 .…”

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Room-temperature sub-band gap optoelectronic response of hyperdoped silicon

et al. 2014

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Room-temperature infrared sub-band gap photoresponse in silicon is of interest for telecommunications, imaging and solid-state energy conversion. Attempts to induce infrared response in silicon largely centred on combining the modification of its electronic structure via controlled defect formation (for example, vacancies and dislocations) with waveguide coupling, or integration with foreign materials. Impurity-mediated sub-band gap photoresponse in silicon is an alternative to these methods but it has only been studied at low temperature. Here we demonstrate impurity-mediated room-temperature sub-band gap photoresponse in single-crystal silicon-based planar photodiodes. A rapid and repeatable laser-based hyperdoping method incorporates supersaturated gold dopant concentrations on the order of 10 20 cm À 3 into a single-crystal surface layer B150 nm thin. We demonstrate room-temperature silicon spectral response extending to wavelengths as long as 2,200 nm, with response increasing monotonically with supersaturated gold dopant concentration. This hyperdoping approach offers a possible path to tunable, broadband infrared imaging using silicon at room temperature.

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Room-temperature sub-band gap optoelectronic response of hyperdoped silicon

et al. 2014

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“…However developing a MEMS resonator with high quality factor in MHz frequency ranges, which would be compatible with CMOS integrated circuits (Dragoi et al 2012) is very important in view of different applications. In integrated circuits, applications such as filters (Bannon et al 2000;Lopez et al 2009), timing and reference frequency devices (Lin et al 2004;Nguyen 2007), microprocessors (Abdelsalam et al 2010) and sensors such as pressure and humidity sensors (Shi et al 2013;Muniraj 2011) facing an important challenge either from scientific or engineering viewpoint that must be well addressed. As an important property, Quality factor (Q) is a scaled ratio between stored energy and damped energy per cycle, which is associated with frequency.…”

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Effects of slots on thermoelastic quality factor of a vertical beam MEMS resonator

Asadi

Sheikholeslami

2015

Microsyst Technol

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the resonance occurs in the mechanical domain. MEMS resonators have already started to use in various applications from wrist watches to the state of the art communications, due to their extremely features. However developing a MEMS resonator with high quality factor in MHz frequency ranges, which would be compatible with CMOS integrated circuits (Dragoi et al. 2012) is very important in view of different applications. In integrated circuits, applications such as filters (Bannon et al. 2000;Lopez et al. 2009), timing and reference frequency devices (Lin et al. 2004;Nguyen 2007), microprocessors (Abdelsalam et al. 2010) and sensors such as pressure and humidity sensors (Shi et al. 2013;Muniraj 2011) facing an important challenge either from scientific or engineering viewpoint that must be well addressed. As an important property, Quality factor (Q) is a scaled ratio between stored energy and damped energy per cycle, which is associated with frequency. In a MEMS resonator, Q is an indication of mechanical energy damping in the system that directly influences sensitivity and resolution of the device Hao et al. 2003). Theoretically, quality factor can be calculated for every frequency, whereas in practice, it is obtained for a specific resonance.In a beam type MEMS resonator, to understand and analyze the energy loss mechanisms, it is important to know the sources of energy loss. The latter could be consisted of support loss, thermoelastic loss and surface loss (Hao et al. 2003). Compression and decompression of an oscillating structure results an irreversible heat flow that is called thermoelastic damping (TED). In Clamped-Clamped (C-C) beam MEMS resonator, the beam in bending experiences a variation on temperature which causes a thermal gradient through the beam. The latter should be well adjusted to maintain the thermal equilibrium. To do this, energy must be intelligently dissipated while the quality factor of the Abstract Thermoelastic damping is one of the dominant mechanisms of structural damping in vacuum-operated microresonators. A three dimensional numerical model based on the finite element method is used for simulating thermoelastic damping in clamped-clamped microelectromechanical beam resonators. In this regards, both simple and slotted beam are considered. To understand the effect of slot positions and sizes on the resonator performance, resonant frequency and thermoelastic quality factor are calculated for both simple and slotted beams for a wide range of beam length from 10 to 400 µm. Punching slots in the resonator beam reduces the stiffness and mass of the beam which affect the resonant frequency. In addition thermomechanical coupling mechanisms of the resonator are affected by the slots which improve the thermoelastic quality factor. For most of the beam lengths, it is shown that the slots at the beam-anchor interface region, where the strain is high, are more effectively enhanced the thermoelastic quality factor than one at the centre of the beam region. However, the highest resonance frequency i...

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“…MEMS-first devices are typically designed in the front-end-of-line (FEOL) stack with access to high performance materials such as Silicon and high-k dielectrics with a high thermal budget. However, these MEMS devices require a release etch at the end of the CMOS process which can affect the performance and yield of the surrounding circuitry while increasing overall process complexity [9,10].…”

Section: B Cmos Integration Of Mems Resonatorsmentioning

confidence: 99%