Wafer-Level Vacuum Packaging of Smart Sensors

Hilton, Allan; Temple, Dorota

doi:10.3390/s16111819

Cited by 58 publications

(48 citation statements)

References 147 publications

(174 reference statements)

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“…Most wearables with heart rate monitors today use a method called Photoplethysmography (PPG) to measure heart rate. [3] PPG is a technical term for shining light into skin and measuring amount of light that is scattered by blood flow. That's an over simplification, but PPG sensors are based on the fact that light entering body will scatter in a predictable manner as the blood flow dynamics change, such as changes in blood pulse rates (heart rate) or with changes in blood volume (cardiac output).…”

Section: Discussion: Optical Heart Rate Sensormentioning

confidence: 99%

Smart Sensors: Analyzing Efficiency of Smart Sensors in Public Domain

Rawat¹,

Pathak²

2019

IJEMR

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The paper gives the brief idea of smart sensors, structure and its application. Smart sensor as compare to other sensors can sensor anything with the special computing devices connected with each other in sensor network. These smart sensors first convert the digital signals to analog signals and then communicate the message to the device. Now a days smart sensors are used almost everywhere around us but very few people know its working and future applications. So here is a small review on smart sensors. This paper will help you gain knowledge and its applications in daily life.

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Section: Discussion: Optical Heart Rate Sensormentioning

confidence: 99%

Smart Sensors: Analyzing Efficiency of Smart Sensors in Public Domain

Rawat¹,

Pathak²

2019

IJEMR

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“…Eutectic bonding is a technique employed to permanently bond devices and wafers through the use of intermediate metallic film layers. This has been employed in hermetic or wafer‐level vacuum packaging and fabrication of heat sinks in packaged microelectromechanical systems (MEMS) and smart sensing devices . Unlike other conventional bonding techniques such as fusion, anodic, solder, and adhesive bonding, eutectic binding allows for less stringent conditions such as low temperature, tolerance to surface topology, and surface cleanliness.…”

Section: Lossless Dielectric Materialsmentioning

confidence: 99%

“…Unlike other conventional bonding techniques such as fusion, anodic, solder, and adhesive bonding, eutectic binding allows for less stringent conditions such as low temperature, tolerance to surface topology, and surface cleanliness. More so, tens of nanometers at the interface of the two materials undergo liquid phase formation and alloying that creates a permanent bond with high mechanical stability …”

Section: Lossless Dielectric Materialsmentioning

confidence: 99%

Dielectrics for Terahertz Metasurfaces: Material Selection and Fabrication Techniques

Ako

Upadhyay

Withayachumnankul

et al. 2019

Advanced Optical Materials

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on distinctive spectral signatures resulting from vibrational modes of covalent and hydrogen bonds. [8,[13][14][15][16] The focus on this spectrally rich region is attributed to the highly coherent and nonionizing nature of terahertz radiation, wide unallocated frequency bands, distinctive wavelengths, and their penetration through a significant depth of dielectric materials. Terahertz technology is geared toward realizing devices that can efficiently manipulate the phase, amplitude, and polarization of terahertz radiations for the above-mentioned myriad of applications.However, progress in this domain is held back by low terahertz power available from compact sources, high free-space path loss, and limited choice of materials that exhibit less absorption of terahertz waves. [17] Owing to the fact that natural materials demonstrate weak wave-matter interaction at terahertz frequencies, terahertz devices with engineered subwavelength resonant metallic inclusions on dielectric spacers have been realized, to interact strongly with an incident electromagnetic wave.In the past, metamaterials have been a promising route to building terahertz devices. These devices have in essence been engineered as 3D resonating elements that effectively manipulate both permittivity and permeability of an effective medium to couple to free space. The underlining disadvantage of these structures is the difficulty involved in the fabrication of 3D geometrical structures using standard semiconductor fabrication techniques. Standard fabrication techniques are generally amenable to 2D design with extrusion of these structures into thickness (the third, vertical dimension). Moreover, the choice and availability of dielectric materials and metals that provide sufficient interaction while retaining device efficiency has proved challenging. [13,[18][19][20] Recently, effective manipulation of electromagnetic wave has been widely demonstrated with 2D metasurfaces, which were originally employed as building blocks for 3D metamaterials. In these lower-dimension designs, effective manipulation of terahertz waves for various applications is achieved by carefully designing sub-wavelength resonant structures as is evident in published review articles. [21,22] Metasurfaces present high degree of compactness that enhances radiation efficiency. Additionally, the planar form factor of metasurfaces enables Manipulation of terahertz radiation opens new opportunities that underpin application areas in communication, security, material sensing, and characterization. Metasurfaces employed for terahertz manipulation of phase, amplitude, or polarization of terahertz waves have limitations in radiation efficiency which is attributed to losses in the materials constituting the devices. Metallic resonators-based terahertz devices suffer from high ohmic losses, while dielectric substrates and spacers with high relative permittivity and loss tangent also reduce bandwidth and efficiency. To overcome these issues, a proper choice of low loss and low relative permittivi...

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“…Wafer-level bonding and thin film encapsulation are the most common wafer-level packaging methods. In the first case, a ring is applied around the switch and a capping wafer is sealed by solder, glass frit, or friction [4,5]. The bonding ring causes a significant increase in the device footprint, and the capping wafer may create a high aspect ratio device.…”

Section: Introductionmentioning

confidence: 99%

Thin Film Encapsulation for RF MEMS in 5G and Modern Telecommunication Systems

Persano

Quaranta

Taurino

et al. 2020

Sensors

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In this work, SiNx/a-Si/SiNx caps on conductive coplanar waveguides (CPWs) are proposed for thin film encapsulation of radio-frequency microelectromechanical systems (RF MEMS), in view of the application of these devices in fifth generation (5G) and modern telecommunication systems. Simplification and cost reduction of the fabrication process were obtained, using two etching processes in the same barrel chamber to create a matrix of holes through the capping layer and to remove the sacrificial layer under the cap. Encapsulating layers with etch holes of different size and density were fabricated to evaluate the removal of the sacrificial layer as a function of the percentage of the cap perforated area. Barrel etching process parameters also varied. Finally, a full three-dimensional finite element method-based simulation model was developed to predict the impact of fabricated thin film encapsulating caps on RF performance of CPWs.

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Wafer-Level Vacuum Packaging of Smart Sensors

Cited by 58 publications

References 147 publications

Smart Sensors: Analyzing Efficiency of Smart Sensors in Public Domain

Smart Sensors: Analyzing Efficiency of Smart Sensors in Public Domain

Dielectrics for Terahertz Metasurfaces: Material Selection and Fabrication Techniques

Thin Film Encapsulation for RF MEMS in 5G and Modern Telecommunication Systems

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