Your search keyword '"Saleh Ferwana"' showing total 15 results

1. Characterization of On-Foil Sensors and Ultra-Thin Chips for HySiF Integration

Author

Mohammed Alomari, Alessandro Ottaviani, Joachim N. Burghartz, Thomas Deuble, Christine Harendt, Bjorn Albrecht, Saleh Ferwana, and Mourad Elsobky

Subjects

Materials science, business.industry, Capacitive sensing, 010401 analytical chemistry, Integrated circuit, 01 natural sciences, 0104 chemical sciences, law.invention, Fall time, law, visual_art, Rise time, Electronic component, visual_art.visual_art_medium, Optoelectronics, Resistance thermometer, Sensitivity (control systems), Electrical and Electronic Engineering, business, Instrumentation, Temperature coefficient

Abstract

The characterization of multiple mechanically flexible passive and active electronic components, namely on-foil temperature sensor, relative humidity sensor, and ultra-thin microcontroller unit (MCU) integrated circuit (IC) is presented. These components are readily available for Hybrid System-in-Foil (HySiF) integration, which combines the merits of the high-performance silicon chips with the large-area electronics. The 60-nm thin-film resistance temperature detector (RTD) is fabricated on different substrates and the extracted temperature coefficient ranges from 0.002 to 0.003( $\Omega/\Omega$ )/°C. Furthermore, the capacitive relative humidity sensor is fabricated by utilizing a polymeric sensing dielectric material that is compatible with those polyimides used in ultra-thin chip embedding. The $1-\mu \text {m}$ thick sensor achieves a fast adsorption rise time of $\text {54 ms}$ and a spontaneous desorption fall time of $\text {750 ms}$ . For flexible ICs packaging and HySiF integration, microcontroller chips are back-thinned to a thickness of about ${30}~\mu \text {m}$ . The characterization of the MCU after the thinning process step showed undegraded performance of the integrated analog-to-digital converter in terms of linearity. However, a drop in the on-chip temperature sensor sensitivity is observed for the thin chips and significant degradation in the period jitter of the high-frequency RC oscillator is measured. Finally, continuity tests are performed to validate the functionality of the ultra-thin MCUs when embedded using the Chip-Film Patch (CFP) flexible package.

Published

2020

2. Hybrid Systems-in-Foil—Combining the Merits of Thin Chips and of Large-Area Electronics

Author

Saleh Ferwana, Harald Richter, Zili Yu, Christine Harendt, Bjorn Albrecht, Golzar Alavi, Yigit Mahsereci, Joachim N. Burghartz, Thomas Deuble, and Mourad Elsobky

Subjects

Flexibility (engineering), Computer science, Circuit design, Integrated circuit, Electronic, Optical and Magnetic Materials, law.invention, Form factor (design), law, visual_art, Hybrid system, Electronic component, Hardware_INTEGRATEDCIRCUITS, visual_art.visual_art_medium, Electronic engineering, Electronics, Electrical and Electronic Engineering, Actuator, Biotechnology

Abstract

This paper reports on the status of a comprehensive ten-year research and development effort toward hybrid system-in-foil (HySiF). In HySiF, the merits of high-performance integrated circuits on ultra-thin chips and of large-area and discrete electronic component implementation are combined in a complementary fashion in and on a flexible carrier substrate. HySiF paves the way to entirely new applications of electronic products where form factor, form adaptivity and form flexibility are key enablers. In this review paper the various aspects of thin-chip fabrication and embedding, device and circuit design under impact of unknown or variable mechanical stress, and the on- and off-chip implementation of sensor, actuator, microwave, and energy supply components are addressed.

Published

2019

3. Ultra-thin Capacitors in Silicon for 3D-Integration and Flexible Electronics

Author

Saleh Ferwana, Christine Harendt, Mamta Pradhan, Harald Richter, and Joachim N. Burghartz

Subjects

Materials science, Silicon, business.industry, Capacitive sensing, chemistry.chemical_element, Substrate (electronics), Flexible electronics, law.invention, Capacitor, chemistry, law, visual_art, Electronic component, visual_art.visual_art_medium, Deep reactive-ion etching, Optoelectronics, business, Electronic circuit

Abstract

Current electronic systems and circuits possess approximately 80 % of passive components. Thus, high performance integrated silicon-based passive components with high density are required to reduce the overall cost and bulkiness of the systems. This paper presents the development of high-density ultra-thin 3D capacitors in silicon, one of the important passive components exploited in approximately all the circuits for SiP, 3D-integration and flexible systems. The 3D structure is achieved by using deep reactive ion etching (DRIE) process. The substrate and the polysilicon act as the two electrode plates with silicon dioxide as the dielectric. Two designs with different pitches are investigated with successful back-grinding of the substrate to 50$\mu$ m thin and 22$\mu$ m ultra-thin singulated capacitors. Capacitive densities of 36.25 nF/mm 2 and 28.75 nF/mm 2 over a frequency bandwidth of 100 KHz are presented. The reduced thickness and flexible nature of these ultra-thin capacitors (

Published

2019

4. Hybrid Systems-in-Foil - Combining Thin Chips with Large-Area Electronics

Author

Harald Richter, Mourad Elsobky, Saleh Ferwana, Thomad Deuble, Golzar Alavi, Yigit Mahsereci, Joachim N. Burghartz, Christine Harendt, Zili Yu, and Bjorn Albrecht

Subjects

Flexibility (engineering), Computer science, Circuit design, Integrated circuit, law.invention, Form factor (design), law, Hybrid system, visual_art, Electronic component, Hardware_INTEGRATEDCIRCUITS, Electronic engineering, visual_art.visual_art_medium, Electronics, Actuator

Abstract

This paper reports on the status of a comprehensive ten-year research and development effort towards Hybrid System-in-Foil (HySiF). In HySiF, the merits of high-performance integrated circuits on ultra-thin chips and of large-area and discrete electronic component implementation are combined in a complementary fashion attached on or laminated in a flexible carrier substrate. HySiF paves the way to entirely new applications of electronic products where form factor, form adaptivity or form flexibility are key enablers. In this review paper the various aspects of thin-chip fabrication and embedding, device and circuit design under impact of unknown or variable mechanical stress, and the on- and off-chip implementation of sensor, actuator, microwave and energy supply components are discussed.

Published

2018

5. RABI - An Acronym to Aid Critical Appraisal of Validity

Author

Mazen Saleh Ferwana

Subjects

Engineering management, Critical appraisal, Acronym, Psychology

Published

2013

6. Ultrathin chips for flexible electronics and 3D ICs

Author

Joachim N. Burghartz, Christine Harendt, and Saleh Ferwana

Subjects

Materials science, Subtractive color, Chip fabrication, Mechanical stability, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Hardware_INTEGRATEDCIRCUITS, Electronic engineering, Three-dimensional integrated circuit, Wafer, Hardware_PERFORMANCEANDRELIABILITY, Chip, Flexible electronics

Abstract

Ultrathin chip fabrication is an enabler of high-performance hybrid systems-in-foil (HySiF) for flexible electronics as well as 3D IC's. Minimum chip thickness, exact thickness control, uniformity and reproducibility as well as smoothness of chip surfaces and edges are important requirements in both applications. Most commonly, thinning is arranged at wafer level prior to chip singulation, which is classified as a subtractive method. In contrast, an additive thin-chip technology called ChipFilm™ is presented here, meeting all those requirements. It is shown that by using ChipFilm™ both wafer-level and chip-level thinning are feasible.

Published

2015

7. Ultra-thin Si chips for flexible electronics Process technology, characterization, assembly and applications

Author

Harald Richter, Mahadi-Ul Hassan, Horst Rempp, Wolfgang Appel, Joachim N. Burghartz, Stefan Endler, Saleh Ferwana, Evangelos A. Angelopoulos, Christine Harendt, and Martin Zimmermann

Subjects

Materials science, Fabrication, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Process (computing), Nanotechnology, Hardware_PERFORMANCEANDRELIABILITY, Chip, Flexible electronics, Characterization (materials science), ComputingMethodologies_PATTERNRECOGNITION, CMOS, Stack (abstract data type), Hardware_GENERAL, Hardware_INTEGRATEDCIRCUITS, Integrated circuit packaging

Abstract

Various aspects of ultra-thin chip technology for flexible electronics are presented and discussed, including ultra-thin-chip fabrication, mechanical and electrical characterization, as well as chip assembly and imbedding. A stress sensor based on a stack of two ultra-thin, flexible CMOS chips indicates the particular advantages of the Chipfilm™ process technology, which is subject of this paper, when compared to other kinds of thin-chip fabrication.

Published

2013

8. A flexible stress sensor using a sub-10μm silicon chip technology

Author

Christine Harendt, Saleh Ferwana, Stefan Endler, Evangelos A. Angelopoulos, and Joachim N. Burghartz

Subjects

Materials science, Stress sensor, Silicon, business.industry, Process (computing), Electrical engineering, chemistry.chemical_element, Thermal contact, Chip, Flexible electronics, chemistry, Stack (abstract data type), Silicon chip, business

Abstract

Here, we present a flexible sensor based on a stack of two ultra-thin IC-chips, exploiting the excellent chip thickness control in Chipfilm™ technology. The sensor consists of an almost stress-compensated bottom chip and a stress-sensitive top chip that are in good mechanical and thermal contact. Moreover, for the first time, we demonstrate that the chip thickness can be reduced to 10 μm, with the bulk Si body measuring only 7 μm, thus allowing for flexible chipstacks measuring only 20 μm in height. Furthermore, we demonstrate a self-aligned Through-Silicon Via (TSV) process in Chipfilm™ enabling 3D integration of such ultra-thin flexible chip pairs.

Published

2013

9. Ultra-thin chips for flexible electronics

Author

Harald Richter, Joachim N. Burghartz, Horst Rempp, Wolfgang Appel, Mahadi-Ul Hassan, Christine Harendt, Evangelos A. Angelopoulos, Saleh Ferwana, Stefan Endler, and Martin Zimmermann

Subjects

Materials science, Fabrication, business.industry, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Electrical engineering, Nanotechnology, Chip, Flexible electronics, Characterization (materials science), ComputingMethodologies_PATTERNRECOGNITION, Hardware_GENERAL, Hardware_INTEGRATEDCIRCUITS, System on a chip, business, Flip chip

Abstract

Various aspects of ultra-thin chip technology for flexible electronics based on Chipfilm™ technology are presented and discussed, including ultra-thin-chip fabrication, mechanical and electrical characterization, as well as chip assembly and imbedding.

Published

2013

10. Self-aligned through silicon vias in ultra-thin chips for 3D-integration

Author

Christine Harendt, Saleh Ferwana, Joachim N. Burghartz, and Florian Letzkus

Subjects

Thermal oxidation, Materials science, Through-silicon via, Silicon, business.industry, High selectivity, Oxide, chemistry.chemical_element, Substrate (electronics), Chip, chemistry.chemical_compound, chemistry, Etching (microfabrication), Electronic engineering, Optoelectronics, business

Abstract

Here, we present a new concept for enabling the formation of TSVs in ultra-thin chips fabricated by using the ChipfilmTM technology. In this technology a buried cavity is created underneath a Si-membrane which is attached to the substrate by vertical silicon anchors. By applying thermal oxidation, the side walls of these anchors and the narrow cavity are passivated. Due to the high selectivity of the silicon via etching process the oxidized silicon anchors and chip backside can be exploited for creating self-aligned TSVs. Accordingly, a seamless oxide isolation at the chip backside and inside the TSVs is provided.

Published

2012

11. Manufacturing aspects of an ultra-thin chip technology

Author

Horst Rempp, Saleh Ferwana, Wolfgang Appel, Christine Harendt, Stefan Endler, Evangelos A. Angelopoulos, Muhammad Alshahed, Mahadi-Ul Hassan, Martin Zimmermann, and Joachim N. Burghartz

Subjects

Thermal oxidation, Materials science, Silicon, business.industry, Oxide, chemistry.chemical_element, Substrate (electronics), Deformation (meteorology), Chip, Stress (mechanics), chemistry.chemical_compound, chemistry, Electronic engineering, Optoelectronics, Wafer, business

Abstract

Ultra-thin silicon (Si) chips fabricated using the recently developed ChipfilmTM technology feature three distinct manufacturing issues, which are discussed in this paper. In Chipfilm™ technology a thin Si membrane is firmly attached to a conventional bulk Si wafer by vertical Si micro-anchors which, however, in the end are controllably fractured to make the thin chips detachable. The associated mechanical stability window is widened by adjusting the arrangement of the micro-anchors, so that chip detachment yields exceeding 99% are achieved. Another not yet reported issue relates to the process temperature and temperature uniformity within the membrane areas, which are thermally connected to the bulk substrate only by the anchors and at the chip edges during processing. Using rapid thermal oxidation and the local oxide thickness as a temperature monitor an on-chip oxide thickness variation of ±3 % is determined. Finally, the inherent deformation (warpage) of free-standing ultra-thin chips due to internal stresses is analyzed and their surface height variation is reduced to only ±4 μm using stress compensation techniques.

Published

2012

12. Low-cost CMOS compatible sintered porous silicon technique for microbolometer manufacturing

Author

Franz Xaver Hutter, Daniel B. Etter, Saleh Ferwana, Martin Zimmermann, and Joachim N. Burghartz

Subjects

Materials science, Fabrication, Pixel, business.industry, Silicon dioxide, Bolometer, Microbolometer, Porous silicon, law.invention, chemistry.chemical_compound, CMOS, chemistry, law, Electronic engineering, Optoelectronics, Profilometer, business

Abstract

This paper reports about the development of a low-cost, CMOS compatible process technology to create thermally insulated pixel regions for integrated microbolometers. The enabling technology is based on a modified sintered porous silicon (sPS) technique. An array of 280 × 240 thermally isolated pixels with lateral dimensions of 30 × 30 μm2 and epitaxial silicon (Si) thickness down to 500 nm is presented. In the final design the pixel is suspended by silicon dioxide (SiO 2 ) arms. The design and fabrication process is described and mechanical deformation properties subtracted from profilometer images are presented.

Published

2012

13. Point of Care Literature Review: Oseltamivir for prevention and treatment of H1N1 Influenza A infection

Author

Mazen Saleh Ferwana

Subjects

Social stress, Descriptive statistics, business.industry, Disease, Overweight, medicine.disease, Obesity, Virology, Weight loss, Environmental health, medicine, Descriptive research, Overeating, medicine.symptom, business

Abstract

Background: Obesity is a serious and chronic medical condition associated with a wide range of lifethreatening disease and resulting in enormous financial costs being born by health-care systems and the community itself. In an effort to reverse the current global epidemic of overweight and obesity, strategies to encourage healthy eating have been promoted in many countries. In order to develop appropriate and effective obesity prevention strategies for young women it is important to understand the barriers they perceive in attempting to reduce their weight and to examine perceptions of a range of personal, social and environmental barriers to healthy eating. Objectives: To identify the range of perceived personal, social and environmental barriers to healthy eating for weight reduction among young Saudi overweight and obese women and to determine how these barriers varied by socio-demographic status and socio-economic status. Design: Cross sectional descriptive study. Method: 302 patients were requested to fill in a questionnaire. It identified personal data, body weight and barriers for healthy diet among adult overweight and obese women. Results: Questionnaires were filled in by 302 overweight and obese patients. We examined 10 barriers. The main barriers reported by women related to a need of special prepared, separated food from family (62.3%), lack of information, skills to plan and prepare a healthy diet (61.2%), easy availability of fast food (56%), lack of time to prepare healthy food because of family commitments (55%), lack of motivation to eat healthy diet accounted for 56.6%, cost of healthy food accounting for 48%, lack of family, friends encouragement and support (49.4%) and 42.7% of ladies consider overeating was related to social stressors, as important barriers. Conclusion: Overall, the study showed a descriptive analysis to the perceived barriers to healthy diet among adult overweight and obese women. Such barriers can be overcome by development of individualized healthy diet programs and implementation of behavioral and social approaches for encouragement of a healthy diet.

Published

2011

14. Ultra-thin chip technology for system-in-foil applications

Author

Saleh Ferwana, Christine Harendt, Joachim N. Burghartz, Stefan Endler, Wolfgang Appel, Evangelos A. Angelopoulos, Martin Zimmermann, Andreas Pruemm, and Tu Hoang

Subjects

Materials science, Silicon, business.industry, chemistry.chemical_element, Hardware_PERFORMANCEANDRELIABILITY, Substrate (electronics), Integrated circuit, Chip, Flexible electronics, law.invention, chemistry, Etching (microfabrication), law, Hardware_INTEGRATEDCIRCUITS, Electronic engineering, Optoelectronics, Process window, Wafer, business

Abstract

A new additive ultra-thin chip fabrication process is presented, utilizing an array of vertical anchors that mechanically connect silicon membrane chips to a standard silicon wafer. The process is demonstrated down to 8 µm silicon chip thickness, with a chip thickness control better than ±0.2 µm and a surface topography with average roughness < 7 nm. Such pre-processed wafers can be used for CMOS manufacturing like any conventional silicon substrate. A wide process window with yield figures exceeding 99% is achieved by proper management of the built-in and externally applied stress on the anchors. The excellent mechanical flexibility and stability of these ultra-thin chips make them particularly suitable for system-in-foil applications.

Published

2010

15. All-silica fiber with low or medium OH-content for broadband applications in astronomy

Author

Gary W. Nelson, Valery Kh. Khalilov, Thorsten Simon, Saleh Ferwana, Roger Haynes, Karl-Friedrich Klein, and H. S. Eckhardt

Subjects

All-silica fiber, Materials science, business.industry, Attenuation, Near-infrared spectroscopy, Radiation, Core (optical fiber), symbols.namesake, Optics, Broadband, symbols, Optoelectronics, Degradation (geology), Rayleigh scattering, business

Abstract

For astronomical applications, different types of step-index all-silica fibers with high-transparency in the whole spectral region from UV (300 nm) to NIR (1100 nm) will be introduced. The light-guiding core-material consists of high-purity silica, especially with low or medium OH-content. In UV region, the losses are mainly influenced by Rayleigh scattering, while the losses in the IR region are limited by traces of OH-groups (in the order of approx. 2 ppm) and fundamental vibration-bands. Due to processing, typical UV-defects below 280 nm can be suppressed significantly within fibers with medium or low OH-content. Especially, one fiber-type with low-OH content in the core possess high resistance against UV radiation in the DUV-region down to 200 nm, which is comparable to high-OH all-silica fibers specially developed for UV-application below 250 nm. In addition, a medium-OH will be presented. The properties of these new fibers in respect to basic attenuation and spectral damage in the UV-region will be discussed, in comparison to high-OH fibers, based on the same measurement-technique. In addition, first results on focal ratio degradation (FRD) and additional loss related to higher propagation angles will be shown, in comparison to standard high-OH fibers.

Published

2004