Your search keyword '"heating methods"' showing total 21 results

1. The Effects of Heating Methods on Infrared Thermography.

Author

Mercer, A. Scott, Klinkhachorn, P., Halabe, Udaya B., and GangaRao, Hota V. S.

Subjects

*THERMOGRAPHY, *MATERIALS testing, *PROPANE, *TEMPERATURE measurements, *HEAT

Abstract

Infrared (IR) Thermography is a good way of detecting air filled defects in FRP decks. When heat is applied to the deck surface, the material over the air void heats up faster and becomes hotter than the surrounding area and an IR camera can distinguish this defective area from a sound area in the deck based on surface temperature measurements. Since this technique requires application of heat in order to produce results, it seems only logical that one should research the effects of different heating types on the defect analysis. For this study, various heat sources; such as the sun, a 5000 BTU quartz electric heater, a 9000 BTU propane convection heater, and a 35000 BTU forced air propane heater, were used to heat up an FRP deck specimen with built-in defects for IR analysis. Different heating times were used to determine the effects on the accuracy and the total elapsed time involved in seeing a defect in the resultant IR images. A few methods, such as CO2 cooling, for decreasing the time it takes to see the defect in the image were also explored. © 2007 American Institute of Physics [ABSTRACT FROM AUTHOR]

Published

2007

2. A Fabry-Perot fiber-optic ultrasonic hydrophone for the simultaneous measurement of temperature and acoustic pressure.

Author

Morris P, Hurrell A, Shaw A, Zhang E, and Beard P

Subjects

Algorithms, Equipment Design, Heating methods, Phantoms, Imaging, Time Factors, Acoustics instrumentation, Fiber Optic Technology instrumentation, Pressure, Temperature, Ultrasonics

Abstract

A dual sensing fiber-optic hydrophone that can make simultaneous measurements of acoustic pressure and temperature at the same location has been developed for characterizing ultrasound fields and ultrasound-induced heating. The transduction mechanism is based on the detection of acoustically- and thermally-induced thickness changes in a polymer film Fabry-Perot interferometer deposited at the tip of a single mode optical fiber. The sensor provides a peak noise-equivalent pressure of 15 kPa (at 5 MHz, over a 20 MHz measurement bandwidth), an acoustic bandwidth of 50 MHz, and an optically defined element size of 10 microm. As well as measuring acoustic pressure, temperature changes up to 70 degrees C can be measured, with a resolution of 0.34 degrees C. To evaluate the thermal measurement capability of the sensor, measurements were made at the focus of a high-intensity focused ultrasound (HIFU) field in a tissue mimicking phantom. These showed that the sensor is not susceptible to viscous heating, is able to withstand high intensity fields, and can simultaneously acquire acoustic waveforms while monitoring induced temperature rises. These attributes, along with flexibility, small physical size (OD approximately 150 microm), immunity to Electro-Magnetic Interference (EMI), and low sensor cost, suggest that this type of hydrophone may provide a practical alternative to piezoelectric based hydrophones.

Published

2009

3. Optimization of an algorithm for measurements of velocity vector components using a three-wire sensor.

Author

Ligeza P and Socha K

Subjects

Computer Simulation, Equipment Design, Equipment Failure Analysis, Heating instrumentation, Heating methods, Models, Theoretical, Reproducibility of Results, Sensitivity and Specificity, Algorithms, Rheology instrumentation, Rheology methods, Thermography instrumentation, Thermography methods, Transducers

Abstract

Hot-wire measurements of velocity vector components use a sensor with three orthogonal wires, taking advantage of an anisotropic effect of wire sensitivity. The sensor is connected to a three-channel anemometric circuit and a data acquisition and processing system. Velocity vector components are obtained from measurement signals, using a modified algorithm for measuring velocity vector components enabling the minimization of measurement errors described in this paper. The standard deviation of the relative error was significantly reduced in comparison with the classical algorithm.

Published

2007

4. Honeycomblike large area LaB6 plasma source for Multi-Purpose Plasma facility.

Author

Woo HJ, Chung KS, You HJ, Lee MJ, Lho T, Choh KK, Yoon JS, Jung YH, Lee B, Yoo SJ, and Kwon M

Subjects

Electrochemistry methods, Equipment Design, Equipment Failure Analysis, Heating methods, Hot Temperature, Reproducibility of Results, Sensitivity and Specificity, Electrochemistry instrumentation, Electrodes, Gases chemistry, Heating instrumentation

Abstract

A Multi-Purpose Plasma (MP(2)) facility has been renovated from Hanbit mirror device [Kwon et al., Nucl. Fusion 43, 686 (2003)] by adopting the same philosophy of diversified plasma simulator (DiPS) [Chung et al., Contrib. Plasma Phys. 46, 354 (2006)] by installing two plasma sources: LaB(6) (dc) and helicon (rf) plasma sources; and making three distinct simulators: divertor plasma simulator, space propulsion simulator, and astrophysics simulator. During the first renovation stage, a honeycomblike large area LaB(6) (HLA-LaB(6)) cathode was developed for the divertor plasma simulator to improve the resistance against the thermal shock fragility for large and high density plasma generation. A HLA-LaB(6) cathode is composed of the one inner cathode with 4 in. diameter and the six outer cathodes with 2 in. diameter along with separate graphite heaters. The first plasma is generated with Ar gas and its properties are measured by the electric probes with various discharge currents and magnetic field configurations. Plasma density at the middle of central cell reaches up to 2.6 x 10(12) cm(-3), while the electron temperature remains around 3-3.5 eV at the low discharge current of less than 45 A, and the magnetic field intensity of 870 G. Unique features of electric property of heaters, plasma density profiles, is explained comparing with those of single LaB(6) cathode with 4 in. diameter in DiPS.

Published

2007

5. A hot-wire probe for thermal measurements of nanowires and nanotubes inside a transmission electron microscope.

Author

Dames C, Chen S, Harris CT, Huang JY, Ren ZF, Dresselhaus MS, and Chen G

Subjects

Equipment Design, Equipment Failure Analysis, Heating methods, Materials Testing methods, Microscopy, Electron, Transmission methods, Reproducibility of Results, Sensitivity and Specificity, Temperature, Thermography methods, Computer-Aided Design, Heating instrumentation, Materials Testing instrumentation, Microscopy, Electron, Transmission instrumentation, Nanotubes chemistry, Thermography instrumentation

Abstract

A hot wire probe has been developed for use inside a transmission electron microscope to measure the thermal resistance of individual nanowires, nanotubes, and their contacts. No microfabrication is involved. The probe is made from a platinum Wollaston wire and is pretensioned to minimize the effects of thermal expansion, intrinsic thermal vibrations, and Lorentz forces. An in situ nanomanipulator is used to select a particular nanowire or nanotube for measurement, and contacts are made with liquid metal droplets or by electron-beam induced deposition. Detailed thermal analysis shows that for best sensitivity, the thermal resistance of the hot-wire probe should be four times that of the sample, but a mismatch of more than two orders of magnitude may be acceptable. Data analysis using the ratio of two ac signals reduces the experimental uncertainty. The range of detectable sample thermal resistances spans from approximately 10(3) to 10(9) KW. The probe can also be adapted for measurements of the electrical conductance and Seebeck coefficient of the same sample. The probe was used to study a multiwalled carbon nanotube with liquid Ga contacts. The measured thermal resistance of 3.3 x 10(7) KW had a noise level of approximately +/-3% and was repeatable to within +/-10% upon breaking and re-making the contact.

Published

2007

6. Optimally accurate thermal-wave cavity photopyroelectric measurements of pressure-dependent thermophysical properties of air: theory and experiments.

Author

Kwan CH, Matvienko A, and Mandelis A

Subjects

Physics methods, Pressure, Reproducibility of Results, Sensitivity and Specificity, Temperature, Air analysis, Heating methods, Manometry methods, Materials Testing methods, Thermography methods

Abstract

An experimental technique for the measurement of thermal properties of air at low pressures using a photopyroelectric (PPE) thermal-wave cavity (TWC) was developed. In addition, two theoretical approaches, a conventional one-dimensional thermal-wave model and a three-dimensional theory based on the Hankel integral, were applied to interpret the thermal-wave field in the thermal-wave cavity. The importance of radiation heat transfer mechanisms in a TWC was also investigated. Radiation components were added to the purely conductive model by linearizing the radiation heat transfer component at the cavity boundary. The experimental results indicate that the three-dimensional model is necessary to describe the PPE signal, especially at low frequencies where thermal diffusion length is large and sideways propagation of the thermal-wave field becomes significant. Radiation is found to be the dominant contributor of the PPE signal at high frequencies and large cavity lengths, where heat conduction across the TWC length is relatively weak. The three-dimensional theory and the Downhill Simplex algorithm were used to fit the experimental data and extract the thermal diffusivity of air and the heat transfer coefficient in a wide range of pressures from 760 to 2.6 Torr. It was shown that judicious adjustments of cavity length and computational best fits to frequency-scanned data using three-dimensional photopyroelectric theory lead to optimally accurate value measurements of thermal diffusivity and heat transfer coefficient at various pressures.

Published

2007

7. XUV laser-plasma source based on solid Ar filament.

Author

Peth C, Kalinin A, Barkusky F, Mann K, Toennies JP, and Rusin LY

Subjects

Equipment Design, Equipment Failure Analysis, Heating methods, Reproducibility of Results, Sensitivity and Specificity, Spectrophotometry, Ultraviolet methods, X-Rays, Argon chemistry, Electrodes, Heating instrumentation, Lasers, Spectrophotometry, Ultraviolet instrumentation

Abstract

We present a laser driven soft x-ray source based on a novel solid argon filament. The continuously flowing micron-sized filament (diameter approximately 56 microm, flow speed approximately 5 mms) was used as a laser target in order to generate a plasma source of high brightness in the "water window" (2.2-4.4 nm) spectral range. The emission properties of the source were characterized in detail with respect to crucial parameters such as positional and energy stability using an extreme ultraviolet (XUV) sensitive pinhole camera and an XUV spectrometer. The results are compared with an argon plasma based on a gas puff target operated under the same experimental conditions showing an increase of the brilliance by a factor of 84. By changing the capillary geometry from a constant diameter to a convergent shape the flow speed of the filament was significantly increased up to 250 mms, facilitating the operation at higher repetition rates.

Published

2007

8. A ground-based radio frequency inductively coupled plasma apparatus for atomic oxygen simulation in low Earth orbit.

Author

Huang Y, Tian X, Yang S, and Chu PK

Subjects

Diathermy methods, Equipment Design, Equipment Failure Analysis, Heating methods, Radio Waves, Reproducibility of Results, Sensitivity and Specificity, Vacuum, Atmosphere chemistry, Diathermy instrumentation, Environment, Heating instrumentation, Oxygen chemistry, Oxygen radiation effects

Abstract

A radio frequency (rf) inductively coupled plasma apparatus has been developed to simulate the atomic oxygen environment encountered in low Earth orbit (LEO). Basing on the novel design, the apparatus can achieve stable, long lasting operation, pure and high density oxygen plasma beam. Furthermore, the effective atomic oxygen flux can be regulated. The equivalent effective atomic oxygen flux may reach (2.289-2.984) x 10(16) at.cm(2) s at an oxygen pressure of 1.5 Pa and rf power of 400 W. The equivalent atomic oxygen flux is about 100 times than that in the LEO environment. The mass loss measured from the polyimide sample changes linearly with the exposure time, while the density of the eroded holes becomes smaller. The erosion mechanism of the polymeric materials by atomic oxygen is complex and involves initial reactions at the gas-surface interface as well as steady-state material removal.

Published

2007

9. Measuring two-dimensional components of a flow velocity vector using a hot-wire probe.

Author

Kiełbasa J

Subjects

Equipment Design, Equipment Failure Analysis, Heating methods, Reproducibility of Results, Rheology methods, Sensitivity and Specificity, Thermography methods, Computer-Aided Design, Heating instrumentation, Rheology instrumentation, Thermography instrumentation, Transducers

Abstract

The article presents a single-hot-wire probe adapted to detect the direction of flow velocity. The modification consists of the introduction of a third support which allows to measure voltage at the central point of the wire. The sign of voltage difference DeltaU between both parts of the wire is the measure of the direction of flow velocity in a system of coordinates associated with the probe.

Published

2007

10. Thermoluminescence apparatus using PT100 resistors as the heating and sensing elements.

Author

Quilty JW, Robinson J, Appleby GA, and Edgar A

Subjects

Computer-Aided Design, Electric Impedance, Equipment Design, Equipment Failure Analysis, Heating methods, Luminescent Measurements methods, Reproducibility of Results, Sensitivity and Specificity, Thermography methods, Heating instrumentation, Luminescent Measurements instrumentation, Thermography instrumentation, Transducers

Abstract

A novel apparatus for obtaining thermoluminescence glow curves is described. Two standard PT100 precision resistors, which have a well-known dependence of resistance on temperature, are connected back to back to provide a sensing and heating element. The resulting hot finger has very low thermal mass, is nonreactive, and is inexpensive. With dry nitrogen gas-flow cooling, an operational range of -50 to 450 degrees C is achievable. A tailored control circuit which is easily calibrated drives the heating element, and temperature ramps are implemented in software. The simple design permits the use of modularly interchangeable hot fingers for rapid measurement of many samples.

Published

2007

11. Optical cell with periodic resistive heating for the measurement of heat, mass, and thermal diffusions in liquid mixtures.

Author

Hartung M and Köhler W

Subjects

Complex Mixtures analysis, Computer-Aided Design, Diffusion, Electric Impedance, Equipment Design, Equipment Failure Analysis, Heating methods, Materials Testing methods, Microfluidic Analytical Techniques methods, Refractometry methods, Reproducibility of Results, Sensitivity and Specificity, Solutions, Thermal Conductivity, Complex Mixtures chemistry, Heating instrumentation, Materials Testing instrumentation, Microfluidic Analytical Techniques instrumentation, Optics and Photonics instrumentation, Refractometry instrumentation

Abstract

A new technique for the measurement of heat, mass, and thermal diffusions in liquids has been developed. Similar to laser induced dynamic gratings, a temperature grating is created in the sample. Thermal expansion transforms the temperature into a refractive-index grating, which is read by diffraction of a readout laser beam. In a multicomponent mixture an additional concentration grating is formed by thermal diffusion driven by the temperature gradients of the temperature grating. Differently to laser induced dynamic grating experiments we use Joule heating instead of optical heating. For that purpose we have built cuvettes which have a grating of transparent conducting strips on the inner side of one of their windows. If heated by an electric current a temperature grating will build up in the sample. Both the heat equation and the extended diffusion equation have been solved in two dimensions to allow for quantitative data analysis. Our apparatus and method of analysis have been validated by measurements of heat, mass, and thermal diffusions in pure and binary liquids. Heat diffusion can be correctly determined as was shown for pure toluene, pure dodecane, and the symmetric mixture of isobutylbenzene dodecane. Mass and thermal diffusions were studied in the three symmetric mixtures of dodecane, isobutylbenzene, and tetralin. The obtained diffusion and Soret coefficients agree with the literature values within the experimental errors. Uncompensated transient heating effects limit the resolution of the experimental technique.

Published

2007

12. Design and construction of microclimate monitoring system.

Author

Kamunda C, Carelse XF, Mathuthu M, and Makarau A

Subjects

Air Conditioning methods, Computer-Aided Design, Environmental Monitoring methods, Equipment Design, Equipment Failure Analysis, Heating methods, Reproducibility of Results, Sensitivity and Specificity, Air Conditioning instrumentation, Environmental Monitoring instrumentation, Heating instrumentation, Microcomputers, Signal Processing, Computer-Assisted instrumentation

Abstract

A portable and user-friendly weather monitoring system based on the PIC16F876 microcontroller is described. This instrument measures three parameters: temperature in the range from -10 to +70 degrees C within +/-1 degrees C using an LM335 temperature sensor, wind speed from 0 to 10 m/s within +/-0.1 m/s using a heated bead thermistor, and solar radiation from 0 to 1000 W/m(2) within +/-10 W/m(2) using a solar cell. These variables are displayed digitally, one at a time, with a 5 s separation. The values are stored on EEPROM at 2 min intervals. The instrument is intended for use in agriculture and for educational purposes.

Published

2007

13. 3omega method to measure thermal properties of electrically conducting small-volume liquid.

Author

Choi SR, Kim J, and Kim D

Subjects

Computer-Aided Design, Electric Conductivity, Electrochemistry methods, Equipment Design, Equipment Failure Analysis, Heating methods, Plethysmography, Impedance methods, Reproducibility of Results, Sensitivity and Specificity, Thermal Conductivity, Thermography methods, Electrochemistry instrumentation, Heating instrumentation, Plethysmography, Impedance instrumentation, Solutions chemistry, Thermography instrumentation, Transducers

Abstract

This work presents a method to measure the thermal conductivity and heat capacity of electrically conducting small-volume liquid samples using the 3omega technique. A mathematical model of heat transfer is derived to determine the thermal properties from the 3omega signal considering the device geometry. In order to validate the model, an experimental apparatus has been designed and set up to measure the thermal properties (thermal conductivity and heat capacity) of seven different liquid samples. The results show good agreement with other literature values, demonstrating that the suggested method is effective for measuring the thermal properties of electrically conducting liquids. More importantly, the result with a sample volume of 1 microl demonstrates the resolution of the thermal conductivity as precise as 0.01% which corresponds to a thermal-conductivity change of 10(-4) Wm K in the case of water-based solutions.

Published

2007

14. Small plasma source for materials application.

Author

Vizir A, Oks EM, Salvadori MC, Teixeira FS, and Brown IG

Subjects

Equipment Design, Equipment Failure Analysis, Heating methods, Materials Testing methods, Microfluidics methods, Miniaturization, Reproducibility of Results, Sensitivity and Specificity, Gases chemistry, Heating instrumentation, Materials Testing instrumentation, Microfluidics instrumentation

Abstract

We describe a small hollow-cathode plasma source suitable for small-scale materials synthesis and modification application. The supporting electrical system is minimal. The gaseous plasma source delivers a plasma ion current of up to about 1 mA. Here we outline the source construction and operation, and present some of its basic performance characteristics.

Published

2007

15. Apparatus for studies of high-temperature chemical reactions in single particle systems.

Author

Andrzejak TA, Shafirovich E, Taylor DG, and Varma A

Subjects

Chemistry Techniques, Analytical methods, Computer-Aided Design, Equipment Design, Equipment Failure Analysis, Heating methods, Hot Temperature, Materials Testing methods, Nanoparticles ultrastructure, Particle Size, Reproducibility of Results, Sensitivity and Specificity, Specimen Handling methods, Thermography methods, Weightlessness Simulation methods, Chemistry Techniques, Analytical instrumentation, Heating instrumentation, Materials Testing instrumentation, Nanoparticles chemistry, Specimen Handling instrumentation, Thermography instrumentation, Weightlessness Simulation instrumentation

Abstract

We report a compact microgravity flight apparatus for characterization of high-temperature chemical reactions in single particle systems. The apparatus employs an infrared CO(2) laser to ignite 1-5 mm samples while video images, thermocouple measurements, laser on/off status, and XYZ accelerometer signals are synchronously recorded. Different operating modes permit preignition quenching, ignition, and combustion experiments to be performed. The apparatus was successfully utilized during microgravity experiments on board NASA research aircraft.

Published

2007

16. Suspended heated silicon platform for rapid thermal control of surface reactions with application to carbon nanotube synthesis.

Author

van Laake L, Hart AJ, and Slocum AH

Subjects

Computer Systems, Computer-Aided Design, Crystallization methods, Equipment Design, Equipment Failure Analysis, Heating methods, Nanotechnology methods, Reproducibility of Results, Sensitivity and Specificity, Specimen Handling methods, Surface Properties, Crystallization instrumentation, Heating instrumentation, Nanotechnology instrumentation, Nanotubes, Carbon chemistry, Nanotubes, Carbon ultrastructure, Silicon, Specimen Handling instrumentation

Abstract

Rapid continuous thermal control of chemical reactions such as those for chemical vapor deposition (CVD) growth of nanotubes and nanowires cannot be studied using traditional reactors such as tube furnaces, which have large thermal masses. We present the design, modeling, and verification of a simple, low-cost reactor based on resistive heating of a suspended silicon platform. This system achieves slew rates exceeding 100 degrees C/s, enabling studies of rapid heating and thermal cycling. Moreover, the reaction surface is available for optical monitoring. A first-generation CVD apparatus encapsulates the heated silicon platform inside a sealed quartz tube, and initial experiments demonstrate growth of films of tangled single-wall and aligned multiwall carbon nanotubes using this system. The reactor can be straightforwardly scaled to larger or smaller substrate sizes and may be extended for a wide variety of reactions, for performing in situ reaction diagnostics, for chip-scale growth of nanostructures, and for rapid thermal processing of microelectronic and micromechanical devices.

Published

2007

17. Precise thermodynamic control of high pressure jet expansions.

Author

Christen W, Krause T, and Rademann K

Subjects

Equipment Design, Equipment Failure Analysis, Flow Injection Analysis methods, Heating methods, Manometry methods, Microfluidics methods, Pressure, Reproducibility of Results, Sensitivity and Specificity, Thermodynamics, Thermography methods, Flow Injection Analysis instrumentation, Heating instrumentation, Manometry instrumentation, Microfluidics instrumentation, Thermography instrumentation

Abstract

We describe an experimental setup for supersonic jet expansions of supercritical fluids. It is characterized by well-defined thermodynamic values to allow systematic investigations of pressure and temperature effects on molecular beam parameters. The design permits stagnation temperatures T(0)=225-425 K with a thermal stability DeltaT(0)<30 mK and stagnation pressures p(0)=0.2-12 MPa that are measured with 0.05% precision. For optimum stability, gas reservoir, pressure transducer, and gauge amplifier are temperature-controlled, and a feedback loop permits active pressure stabilization using a pulseless syringe pump. With this approach stagnation pressures can be reproduced and kept constant to Deltap(0)<2.9 kPa. As a result, flow velocity and kinetic energy of molecular beams can be controlled with maximum accuracy.

Published

2007

18. High-throughput reactor system with individual temperature control for the investigation of monolith catalysts.

Author

Dellamorte JC, Vijay R, Snively CM, Barteau MA, and Lauterbach J

Subjects

Catalysis, Combinatorial Chemistry Techniques methods, Equipment Design, Equipment Failure Analysis, Heating methods, Materials Testing methods, Thermography methods, Combinatorial Chemistry Techniques instrumentation, Heating instrumentation, Materials Testing instrumentation, Thermography instrumentation

Abstract

A high-throughput parallel reactor system has been designed and constructed to improve the reliability of results from large diameter catalysts such as monoliths. The system, which is expandable, consists of eight quartz reactors, 23.5 mm in diameter. The eight reactors were designed with separate K type thermocouples and radiant heaters, allowing for the independent measurement and control of each reactor temperature. This design gives steady state temperature distributions over the eight reactors within 0.5 degrees C of a common setpoint from 50 to 700 degrees C. Analysis of the effluent from these reactors is performed using rapid-scan Fourier transform infrared (FTIR) spectroscopic imaging. The integration of this technique to the reactor system allows a chemically specific, truly parallel analysis of the reactor effluents with a time resolution of approximately 8 s. The capabilities of this system were demonstrated via investigation of catalyst preparation conditions on the direct epoxidation of ethylene, i.e., on the ethylene conversion and the ethylene oxide selectivity. The ethylene, ethylene oxide, and carbon dioxide concentrations were calibrated based on spectra from FTIR imaging using univariate and multivariate chemometric techniques. The results from this analysis showed that the calcination conditions significantly affect the ethylene conversion, with a threefold increase in the conversion when the catalyst was calcined for 3 h versus 12 h at 400 degrees C.

Published

2007

19. Constant-bandwidth constant-temperature hot-wire anemometer.

Author

Ligeza P

Subjects

Equipment Design, Equipment Failure Analysis, Heating methods, Reproducibility of Results, Rheology methods, Sensitivity and Specificity, Computer-Aided Design, Electronics instrumentation, Heating instrumentation, Rheology instrumentation, Transducers

Abstract

A constant-temperature anemometer (CTA) enables the measurement of fast-changing velocity fluctuations. In the classical solution of CTA, the transmission band is a function of flow velocity. This is a minor drawback when the mean flow velocity does not significantly change, though it might lead to dynamic errors when flow velocity varies over a considerable range. A modification is outlined, whereby an adaptive controller is incorporated in the CTA system such that the anemometer's transmission band remains constant in the function of flow velocity. For that purpose, a second feedback loop is provided, and the output signal from the anemometer will regulate the controller's parameters such that the transmission bandwidth remains constant. The mathematical model of a CTA that has been developed and model testing data allow a through evaluation of the proposed solution. A modified anemometer can be used in measurements of high-frequency variable flows in a wide range of velocities. The proposed modification allows the minimization of dynamic measurement errors.

Published

2007

20. Design and construction of uniform glow discharge plasma system operating under atmospheric condition.

Author

Koçum C and Ayhan H

Subjects

Atmospheric Pressure, Electrochemistry methods, Equipment Design, Equipment Failure Analysis, Heating methods, Reproducibility of Results, Sensitivity and Specificity, Electrochemistry instrumentation, Electronics, Gases chemistry, Heating instrumentation

Abstract

The design of a uniform glow discharge plasma system operating without vacuum is presented. A full-bridge switching circuit was used to switch the transformers. The primary windings of transformers were connected in parallel, but in opposite phase to double the output voltage. Theoretically, 20 000 V(pp) was obtained. Rectangle copper electrodes were used, and placed parallel to each other. To prevent the spark production that is, to obtain uniformity, two 2 mm Teflon sheets were glued to the electrodes. However, it was observed that the operating frequency also affected the uniformity. For the system presented here, the frequency at which more uniformity was obtained was found to be 14 kHz.

Published

2007

21. Design of a scanning probe microscope with advanced sample treatment capabilities: An atomic force microscope combined with a miniaturized inductively coupled plasma source.

Author

Hund M and Herold H

Subjects

Equipment Design, Equipment Failure Analysis, Heating methods, Miniaturization, Pilot Projects, Reproducibility of Results, Sensitivity and Specificity, Specimen Handling methods, Systems Integration, Gases chemistry, Heating instrumentation, Materials Testing instrumentation, Microscopy, Atomic Force instrumentation, Specimen Handling instrumentation, Transducers

Abstract

We describe the design and performance of an atomic force microscope (AFM) combined with a miniaturized inductively coupled plasma source working at a radio frequency of 27.12 MHz. State-of-the-art scanning probe microscopes (SPMs) have limited in situ sample treatment capabilities. Aggressive treatments such as plasma etching or harsh treatments such as etching in aggressive liquids typically require the removal of the sample from the microscope. Consequently, time consuming procedures are required if the same sample spot has to be imaged after successive processing steps. We have developed a first prototype of a SPM which features a quasi in situ sample treatment using a modified commercial atomic force microscope. A sample holder is positioned in a special reactor chamber; the AFM tip can be retracted by several millimeters so that the chamber can be closed for a treatment procedure. Most importantly, after the treatment, the tip is moved back to the sample with a lateral drift per process step in the 20 nm regime. The performance of the prototype is characterized by consecutive plasma etching of a nanostructured polymer film.

Published

2007