Innovative devices for electron spin resonance spectroscopy on small samples

Malika Bouterfas
EPFL, 2008
Thèse EPFL

Résumé

Within the past few years, the field of Electron Spin Resonance has become an important tool in physical, chemical and biological research. However, in many cases its usefulness is limited by the sensitivity of the experimental setup. A typical example is the study of very limited sample quantities such as tissues, cellular structures, single cells, and also thin films in microelectronic technologies. For such volume limited samples, the typical dimensions and/or spatial variations of the properties of interest range between 1 µm and 1 mm. Present X-band ESR spectrometers are optimized for samples having a volume between (1 mm)3 and (1 cm)3, and achieve a spin sensitivity of about 1010 spins/G√Hz at room temperature. Setting up new high sensitivity ESR spectrometers would overcome this limitation and open the way to numerous new applications. The goal of the present work is to study and develop innovative devices in combination with modern continuous ESR detection method to achieve a spin sensitivity of 109 spins/G√Hz or better at room temperature, specifically conceived for samples having dimensions and/or spatial variations in the range between 1 µm and 1 mm. We mainly focus our investigation efforts on the design of ESR-setups based on miniaturized sensitive devices. Miniaturization concerns size reduction of the sensitive volume where the sample will be placed, i.e., the region in which the microwave magnetic field is generated. In this work two approaches will be investigated. Inductive transverse magnetization detection by means of planar structures based on coplanar waveguide (CPW) resonator design. Single turn coils and straight trace constrictions with different dimensions are designed as sensitive regions to accommodate the appropriate sample size. These constrictions are built with open-ended half-wavelength and shorted (or shunted) quarter-wavelength lines related to the working resonance frequency. Appropriate microfabrication technologies are also developed based on two substrate candidates, SU-8 and RO4003C, with Aluminum and Copper metals, respectively. Performance of the RO4003C based-resonators proves to be better than that for the SU-8 based ones in terms of the conversion factor describing the efficiency of conversion of microwave power to magnetic field strength. The analysis we have performed shows that the dielectric losses induced in the RO4003C substrate are much lower than those induced in SU-8 one. This improves the Q-factor by almost a factor 10. Since the conversion factor varies as Q1/2, this, in turn, enhances the power conversion efficiency by almost a factor 3. Detection efficiency is also improved by almost the same factor. As a result, a spin sensitivity of about 109 spins/G√Hz is achieved at room temperature for sensitive volumes of about (100 µm)3. This result is one order of magnitude better than that of existing X-band spectrometers. Longitudinal magnetization detection using a Hall-based probe. A resonant cavity and a CPW-resonator are used to generate the microwave field. Rather than a large rectangular cavity and its disperse field lines, the CPW-resonator offers a smaller structure. Its compact geometry is suitable for small volumes, since it concentrates the microwave magnetic field precisely at the sample. This approach eliminates several experimental difficulties of cavity-employed ESR spectroscopy and better controls the electromagnetic environment of the sample, avoiding the properties of the cavity resonator which suffer from thermal drifts and background instabilities. In addition, thanks to their greater sensitivity, the CPW-resonators require much less microwave power than waveguide cavities, to generate the same microwave magnetic field. The achieved spin sensitivity is about 109 spins/G√Hz at room temperature for sensitive volumes of about (10 µm)3 . This result is, once more, one order of magnitude better than that of conventional X-band spectrometers. The obtained results confirm the effectiveness of the combination of the CPW-resonators for small sample analysis for practical enhancement of the ESR spectrometer sensitivity at X-band frequencies. Furthermore, a key aspect of the present work is the ability to go further in miniaturization: the concept of coplanar waveguide structures is very simple and easy to implement for the required ESR measurements without too much additional design complexity and change to fabrication procedures. This should be very promising, and especially highly motivating to achieve in-vivo ESR measurements inside living organism and to perform high spatial resolution ESR-imaging.

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https://infoscience.epfl.ch/record/114771?ln=fr

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Malika Bouterfas
EPFL, 2008
Thèse EPFL

Résumé

Official source

https://infoscience.epfl.ch/record/114771?ln=fr

À propos de ce résultat

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Concepts associés

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Publications associées (9)

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Piezoelectric acoustic sensors and ultrasonic transducers based on textured PZT thin films

Nicolas Ledermann

This work dealt with the establishment of a reproducible and industrially exploitable fabrication technology for piezoelectric MEMS based on PZT thin films. {100}-textured piezoelectric 1-4 μm thick films were found to be the most suited materials for MEMS applications where a strong transverse e31,f coefficient is required. Values of 11.5 to 12.5 C/m2 throughout the investigated thickness range have been obtained. PZT MEMS requires some special microfabrication processes. The patterning of platinum electrodes in ICP reactor with an Ar/Cl2 gas mixture gave satisfying results. For 1 μm PZT films, excellent results were achieved with dry etching in an ECR/RF low-pressure reactor. Above 1 μm thickness, wet etching technique was used. The chosen process flow was such that all layers up the top electrode were first deposited, and then sequentially patterned. In this way, the functional properties were completely maintained. Finally, the process flow related to PZT was successfully combined with deep silicon etching techniques to produce free standing structures. The applicability of the processes has been demonstrated by means of two piezoelectric micro-electro-mechanical devices. First, a cantilever acoustic sensor for low frequency applications (< 50 Hz) has been developed for integration in photoacoustic gas detectors. A high device sensitivity of up to 150 mV/Pa has been obtained with noise level corresponding to a few mPa, mainly due to the preamplifier. The second device was based on a silicon/PZT diaphragm to produce a vibrating structure in view of fabricating ultrasonic transducers for position sensors and non-destructive testing probes. The study of the basic properties of such structures has shown excellent results as coupling factors k2 up to 5% for PZT 2 μm / Si 4 μm SOI membranes held with four small bridges. Ultrasonic wave transmission between two devices has been achieved up to a distance of 200 mm. The microfabrication of piezoelectric MEMS was found to be a complex task where all aspects from materials, microfabrication, and device design to assessment of performance are closely interconnected. Piezoelectric MEMS can offer exciting opportunities to fabricate innovative and performing devices.

EPFL2003

Chargement

Copper / low-k technological platform for the fabrication of high quality factor above-IC passive devices

Modern communication devices demand challenging specifications in terms of miniaturization, performance, power consumption and cost. Every new generation of radio frequency integrated circuits (RF-ICs) offer better functionality at reduced size, power consumption and cost per device and per integrated function. Passive devices (resistors, inductors, capacitors, antennas and transmission lines) represent an important part of the cost and size of RF circuits. These components have not evolved at the same level of the transistor devices, especially because their performance is strongly degenerated when they scale down in size. The low resistivity silicon used to build the transistors also imposes prohibitive levels of RF losses to these passive devices. Radio frequency microelectromechanical systems (RF MEMS) are enabling technologies capable to bring significant improvement in the electrical performances and expressive size and cost reduction of these functions, with unparallel introduction of new functionalities, unimaginable to attain when using bulky, externally connected discrete components. High quality factor (Q) inductors are amongst ones of the most needed components in RF circuits and at the same time ones that are most affected by thin metallization and substrate related losses, demanding considerable research effort. This thesis presents a contribution toward the development of thick metal fabrication technologies, covering also the design, modeling and characterization of high quality factor and high self-resonant frequency (SRF) RF MEMS passive devices, with a special emphasis on spiral inductors. A new approach using damascene-like interconnect fabrication steps associated to low κ dielectrics (polyimide), highly-conductive thick copper electroplating, chemical mechanical polishing (CMP) and tailored substrate properties delivered quality factors in excess of 40 and self resonant frequencies in excess of 10 GHz, performances in the current state-of-the-art for integrated spiral inductors built on top of silicon wafers. Furthermore, the developed process steps are compatible with back-end processing used to fabricate modern IC interconnects and have a low thermal budget (< 250 °C), what makes it a good choice to build above-IC passives without degenerating the performance of passivated RF-CMOS circuits. Deep reactive ion etching (DRIE) of quartz substrates was also studied for the fabrication of spiral inductors, offering excellent RF performances (Q exceeding 40 and SRF exceeding 7 GHz). A new doubly-functional quartz packaging concept for RF MEMS devices was developed. This technique process both sides of the packaging wafer: the top is used to embed high quality factor copper inductors while the bottom is thermo-mechanically bonded to another RF MEMS wafer, offering a semi-hermetic SU-8 epoxy-based seal. The bonding process was optimized for high yield, to be compatible with SF6-plasma-released MEMS and to present low level of RF losses. Band pass filters for the GSM (1.8 GHz) and WLAN (5.2 GHz) standards were fabricated and characterized by RF measurements and full wave electromagnetic simulations. Although further development is need in order to predict the frequency response accurately, insertion losses as low as 1.2 dB were demonstrated, levels that cannot be usually attained using on-chip passives. Systematic analysis, RF measurements, electromagnetic simulations and equivalent circuit extraction were used to model the behavior of the fabricated devices and establish a methodology to deliver optimum performances for a given technological profile and specified performance targets (quality factor, inductance and frequency bandwidth). A simple yet accurate physics-based analytical model for spiral inductors was developed and proved to be accurate in terms of loss estimation for thick metal layers. This model is capable to accurately describe the frequency-dependent behavior of the device below its first resonant frequency over a large device design space. The model was validated by both measurements and full wave electromagnetic simulations and is well suited to perform numeric optimization of designs. The proposed models were also systematized in a Matlab® toolbox.

EPFL2007

Chargement

Wireless communication systems and handset devices are showing a rapid growth in consumer and military applications. Applications using wireless communication standards such as personal connectivity devices (Bluetooth), mobile systems (GSM, UMTS, WCDMA) and wireless sensor network are the opportunities and challenges for the semi-conductor industry. The trend towards size and weight reduction, low power consumption and increased functionalities induces major technological issues. Today, the wireless circuit size is limited by the use of lots of external or "off-chip" components. Among them, quartz crystal, used as the time reference in any wireless systems, is the bottleneck of the miniaturization. Microelectromechanical systems (MEMS) is an emerging technology which has the capability of replacing the quartz. Based on similar technology than the Integrated Circuit (IC), MEMS are referred as electrostatically, thermally or piezoelectrically actuated mechanical structures. In this thesis, a new MEMS device based on the hybridization of a mechanical vibrating structure and a solid-sate MOS transistor has been developed. The Resonant Suspended-Gate MOSFET (RSG-MOSFET) device combines both advantages of a high mechanical quality factor and the transistor intrinsic gain. The physical mechanisms behind the actuation and the behavior of this device were deeply investigated and a quasi-static model was developed and validated, based on measured characteristics. Furthermore, the dynamic model of the RSG-MOSFET was created, taking into account the non-linear mechanical vibrations of the gate and the EKV model, used for MOSFET modeling. Two fabrication processes were successfully developed to demonstrate the proof of concept of such a device and to optimize the performances respectively. Aluminum-silicon (Al-Si1%) and pure silicon-based RSG-MOSFETs were successfully fabricated. DC and AC characterizations on both devices enabled to understand, extract and evaluate the mechanical and MOSFET effects. A specifically developed RF characterization methodology was used to measure the linear and non-linear behaviors of the resonator and to evaluate the influence of each polarization voltages on the signal response. RSG-MOSFET with resonant frequencies ranging from 5MHz to 90MHz and quality factor up to 1200 were measured. Since MEMS resonator quality factor is strongly degraded by air damping, a 0-level thin film vacuum packaging (10-7 mBar) process was developed, compatible with both AlSi-based and silicon-based RSG-MOSFET. The technology has the unique advantage of being done on already released structure and the room temperature process makes it suitable for above-IC integration. In parallel, a front-end compatible process was defined and major build blocks were developed in industrial environment at STMicroelectronics. This technology is based on the Silicon-On-Nothing technology, originally developed for advanced transistor, and therefore making the MEMS resonator process compatible with CMOS co-integration. DC characterizations of SG-MOSFET had shown interesting performances of this device for current switch and memory applications. Mechanical contact of the gate with the MOSFET channel induces a current switching slope greater than 0.8mV/decade, much better than the theoretical MOSFET limit of 60mV/decade. Maximum switch isolations of -37dB at 2 GHz and -27dB at 10GHz were measured on these devices. A novel MEMS-memory has been demonstrated, based on the direct charge injection to the storage media by the mechanical contact of the metal gate. Charge injection and retention mechanisms were investigated based on measured devices. Cycling study of up to 105 cycles were performed without noticing major degradations of the electrical behavior neither mechanical fatigue of the suspended gate. The measured retention time places this memory in between the DRAM and the FLASH memories. A scaling study has shown integration and compatibilities capabilities with existing CMOS.

EPFL2007

Chargement

Copper / low-k technological platform for the fabrication of high quality factor above-IC passive devices

EPFL2007

Piezoelectric acoustic sensors and ultrasonic transducers based on textured PZT thin films

Nicolas Ledermann

EPFL2003

EPFL2007