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111 results on '"Dechaumphai, P."'

1. Sub-nanowatt microfluidic single-cell calorimetry.

Author

Hong, Sahngki, Dechaumphai, Edward, Green, Courtney R, Lal, Ratneshwar, Murphy, Anne N, Metallo, Christian M, and Chen, Renkun

Subjects
Mitochondria, Tetrahymena thermophila, Basal Metabolism, Calorimetry, Microfluidic Analytical Techniques, Microfluidics, Temperature, Oxygen Consumption, Thermal Conductivity, Single-Cell Analysis
Abstract

Non-invasive and label-free calorimetry could become a disruptive technique to study single cell metabolic heat production without altering the cell behavior, but it is currently limited by insufficient sensitivity. Here, we demonstrate microfluidic single-cell calorimetry with 0.2-nW sensitivity, representing more than ten-fold enhancement over previous record, which is enabled by (i) a low-noise thermometry platform with ultralow long-term (10-h) temperature noise (80 μK) and (ii) a microfluidic channel-in-vacuum design allowing cell flow and nutrient delivery while maintaining a low thermal conductance of 2.5 μW K-1. Using Tetrahymena thermophila as an example, we demonstrate on-chip single-cell calorimetry measurement with metabolic heat rates ranging from 1 to 4 nW, which are found to correlate well with the cell size. Finally, we perform real-time monitoring of metabolic rate stimulation by introducing a mitochondrial uncoupling agent to the microchannel, enabling determination of the spare respiratory capacity of the cells.

Published
2020

2. Sub-nanowatt microfluidic single-cell calorimetry

Author

Sahngki Hong, Edward Dechaumphai, Courtney R. Green, Ratneshwar Lal, Anne N. Murphy, Christian M. Metallo, and Renkun Chen

Subjects
Science
Abstract

Calorimetrically measuring the heat of single cells is currently not possible due to the sensitivity of existing calorimeters. Here the authors present on-chip single cell calorimetry, with a sensitivity over ten-fold greater than the current gold-standard.

Published
2020
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4. High Resolution Calorimetry for Thermal and Biological Applications

Author

Dechaumphai, Edward

Subjects
Mechanical engineering, Nanotechnology, Biomedical engineering, Biocalorimeter, Calorimetry, Nanoscale heat transport, Single cell metabolic rate, Thermal engineering
Abstract

Calorimetry is a heat measuring process that quantifies heat generation, loss, and transport. Calorimetry holds significant values to a multitude of scientific disciplines such as nanoscale heat transfer, bolometer infrared detection, and drug discovery. This dissertation focuses on two aspects of calorimetry: 1) application of a calorimetry technique to investigate fundamentals of thermal transport at micro/nanoscale level, and 2) development of high-resolution microfluidic calorimeters for biological applications.A modulated calorimetry technique, namely, the 3ω method, was used to study thermal transport across highly mismatched interfaces, where Au/Si multilayers (MLs), were used as the model material. By leveraging thermal resistance at interfaces of Au and Si, which have highly dissimilar acoustic impedance, we experimentally demonstrated an ultralow thermal conductivity, κ, of 0.33 ± 0.04 W m-1K-1 at room temperature with a high interfacial density of ~0.2 interface nm-1. The measured κ was the lowest amongst inorganic MLs with similar interfacial density. The 3ω method was also applied to measure thermal conductivity of the near-surface regime of tungsten damaged by ion irradiation used in plasma facing components (PFCs) in fusion reactors. The measurement showed a nearly 60\% reduction in κ in comparison to pristine tungsten, which can be detrimental to the mechanical integrity of the PFCs under heat fluxesThe second thrust of the dissertation is focused on the development of high-resolution calorimeters. A high performance resistive thermometer material, NbNx, was developed and integrated into a suspended bridge calorimeter. When used with a modulated heating current and a differential instrumentation schemes, the NbNx-based calorimeter demonstrated an exceptional high power resolution of 0.26 pW at room temperature. Furthermore, the high-resolution calorimetry was extended to microfluidic platform for biological applications. Owing to the low parasitic heat loss and a long-term temperature stability platform, the biocalorimeters developed from this study possess a significant enhancement over the state-of-the-art long-term power detection limit, which enable the detection of metabolic rate of individual living cells in the microfluidic channels. Such a biocalorimetry technique will open up new opportunities in a biomedical field such as in cell and tissue metabolism, drug discovery and screening, and antibody-antigen detection.

Published
2016

19. Computational Fluid Dynamics Modeling to Improve Natural Flow Rate and Sweet Pepper Productivity in Greenhouse

Author

W. Limtrakarn, P. Boonmongkol, A. Chompupoung, K. Rungprateepthaworn, J. Kruenate, and P. Dechaumphai

Subjects
Mechanical engineering and machinery, TJ1-1570
Abstract

Natural flow rate and sweet peppers productivity in tropical greenhouse are improved by CFD simulation is the main objective of this research work. Most of the greenhouse types today are in the arch shape. To develop an improved greenhouse structure for the region, the arch type was built and used as the control model. Mae Sar Mai agriculture research station under the royal project foundation was selected as the field test site. Temperature sensors with data logger were installed to monitor variation of temperature inside the greenhouse. The measured temperature data were used as the boundary conditions for the CFD analysis. A new greenhouse model with two-step roof shape was designed and the air flow behavior was simulated by using CFD. Regarding CFD results the air flow rate of the new model is about 39% higher than that of old model. The maximum temperature of the new model is lower than that of the old one. The sweet paper growths in both greenhouse models were measured and compared. Results show that the new model obtains 4°C lower maximum temperature in day time, 97% in number and 90% in weight higher the first grade pepper productivity than the old one.

Published
2012
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32. Resonant frequency of gold/polycarbonate hybrid nano resonators fabricated on plastics via nano-transfer printing

Author

Siwak Nathan, Ghodssi Reza, Dechaumphai Edward, Zhang Zhao, and Li Teng

Subjects
Materials of engineering and construction. Mechanics of materials, TA401-492
Abstract

Abstract We report the fabrication of gold/polycarbonate (Au/PC) hybrid nano resonators on plastic substrates through a nano-transfer printing (nTP) technique, and the parametric studies of the resonant frequency of the resulting hybrid nano resonators. nTP is a nanofabrication technique that involves an assembly process by which a printable layer can be transferred from a transfer substrate to a device substrate. In this article, we applied nTP to fabricate Au/PC hybrid nano resonators on a PC substrate. When an AC voltage is applied, the nano resonator can be mechanically excited when the AC frequency reaches the resonant frequency of the nano resonator. We then performed systematic parametric studies to identify the parameters that govern the resonant frequency of the nano resonators, using finite element method. The quantitative results for a wide range of materials and geometries offer vital guidance to design hybrid nano resonators with a tunable resonant frequency in a range of more than three orders of magnitude (e.g., 10 KHz-100 MHz). Such nano resonators could find their potential applications in nano electromechanical devices. Fabricating hybrid nano resonators via nTP further demonstrates nTP as a potential fabrication technique to enable a low-cost and scalable roll-to-roll printing process of nanodevices.

Published
2011

37. A finite element approach for prediction of aerothermal loads

Author

Thornton, E. A, Dechaumphai, P, and Vemaganti, G

Subjects
Aerodynamics
Abstract

A Taylor-Galerkin finite element approach is presented for analysis of high speed viscous flows with an emphasis on predicting heating rates. Five computational issues relevant to the computation of steady flows are examined. Numerical results for supersonic and hypersonic problems address the computational issues and demonstrate the validity for the approach for analysis of high speed flows.

Published
1986

38. A Taylor-Galerkin finite element algorithm for transient nonlinear thermal-structural analysis

Author

Thornton, E. A and Dechaumphai, P

Subjects
Structural Mechanics
Abstract

A Taylor-Galerkin finite element method for solving large, nonlinear thermal-structural problems is presented. The algorithm is formulated for coupled transient and uncoupled quasistatic thermal-structural problems. Vectorizing strategies ensure computational efficiency. Two applications demonstrate the validity of the approach for analyzing transient and quasistatic thermal-structural problems.

Published
1986

39. A finite element approach for solution of the 3D Euler equations

Author

Thornton, E. A, Ramakrishnan, R, and Dechaumphai, P

Subjects
Fluid Mechanics And Heat Transfer
Abstract

Prediction of thermal deformations and stresses has prime importance in the design of the next generation of high speed flight vehicles. Aerothermal load computations for complex three-dimensional shapes necessitate development of procedures to solve the full Navier-Stokes equations. This paper details the development of a three-dimensional inviscid flow approach which can be extended for three-dimensional viscous flows. A finite element formulation, based on a Taylor series expansion in time, is employed to solve the compressible Euler equations. Model generation and results display are done using a commercially available program, PATRAN, and vectorizing strategies are incorporated to ensure computational efficiency. Sample problems are presented to demonstrate the validity of the approach for analyzing high speed compressible flows.

Published
1986

40. A New Finite Element Approach for Prediction of Aerothermal Loads: Progress in Inviscid Flow Computations

Author

Bey, K. S, Thornton, E. A, Dechaumphai, P, and Ramakrishnan, R

Subjects
Fluid Mechanics And Heat Transfer
Abstract

Recent progress in the development of finite element methodology for the prediction of aerothermal loads is described. Two dimensional, inviscid computations are presented, but emphasis is placed on development of an approach extendable to three dimensional viscous flows. Research progress is described for: (1) utilization of a commerically available program to construct flow solution domains and display computational results, (2) development of an explicit Taylor-Galerkin solution algorithm, (3) closed form evaluation of finite element matrices, (4) vector computer programming strategies, and (5) validation of solutions. Two test problems of interest to NASA Langley aerothermal research are studied. Comparisons of finite element solutions for Mach 6 flow with other solution methods and experimental data validate fundamental capabilities of the approach for analyzing high speed inviscid compressible flows.

Published
1985

41. Finite element thermal-structural analyses of a cable-stiffened orbiting antenna

Author

Thornton, E. A, Dechaumphai, P, and Pandey, A. K

Subjects
Structural Mechanics
Abstract

Finite element thermal-structural analyses of a cable-stiffened orbiting antenna are presented. The determination of prestresses in the antenna is described first. Heating and thermal analyses for orbiting space structures are then discussed briefly. Structural deformations and stresses are presented for three finite element structural analysis approaches: (1) small deflections, (2) stress-stiffening, and (3) large deflections. The accuracy of the three analysis approaches is evaluated for the orbiting antenna at different prestress levels.

Published
1985

42. Finite element thermal-structural analysis of cable-stiffened space structues

Author

Thornton, E. A, Dechaumphai, P, and Pandey, A. K

Subjects
Structural Mechanics
Abstract

Finite element thermal-structural analyses of large, cable-stiffened space structures are presented. A computational scheme for the calculation of prestresses in the cable-stiffened structures is also described. The determination of thermal loads on orbiting space structures due to environment heating is discussed briefly. Three finite element structural analysis techniques are presented for the analysis of prestressed structures. Linear, stress stiffening, and large displacement analysis techniques were investigated. These three techniques were employed for analysis of prestressed cable structures at different prestress levels. The analyses produced similar results at small prestress, but at higher prestress, differences between the results became significant. For the cable-stiffened structures studied, the linear analysis technique may not provide acceptable results. The stress stiffening analysis technique may yield results of acceptable accuracy depending upon the level of prestress. The large displacement analysis technique produced accurate results over a wide range of prestress and is recommended as a general analysis technique for thermal-structural analysis of cable-stiffened space structures.

Published
1984

43. A hierarchical finite element approach for integrated thermal-structural analysis

Author

Thornton, E. A and Dechaumphai, P

Subjects
Structural Mechanics
Abstract

A hierarchical finite element approach for thermal-structural analysis is presented. The approach employs a common nodal discritization and seeks improvements in the accuracy of the analyses by using hierarchical interpolation functions with nodeless variables. The effectiveness of the integrated approach is assessed for three applications with two-dimensional elements by comparison with conventional finite element thermal-structural solutions. Improvements in the accuracy of temperatures and thermal-stresses are demonstrated. The applications demonstrate the practical importance of having flexibility in refining each analysis independently while maintaining a common discretization, and show that the hierarchical approach offers potential for the development of a general method for integrated thermal-structural analysis.

Published
1984

44. Improved finite element methodology for integrated thermal structural analysis

Author

Dechaumphai, P and Thornton, E. A

Subjects
Fluid Mechanics And Heat Transfer
Abstract

An integrated thermal-structural finite element approach for efficient coupling of thermal and structural analyses is presented. New thermal finite elements which yield exact nodal and element temperature for one dimensional linear steady state heat transfer problems are developed. A nodeless variable formulation is used to establish improved thermal finite elements for one dimensional nonlinear transient and two dimensional linear transient heat transfer problems. The thermal finite elements provide detailed temperature distributions without using additional element nodes and permit a common discretization with lower order congruent structural finite elements. The accuracy of the integrated approach is evaluated by comparisons with analytical solutions and conventional finite element thermal-structural analyses for a number of academic and more realistic problems. Results indicate that the approach provides a significant improvement in the accuracy and efficiency of thermal stress analysis for structures with complex temperature distributions.

Published
1982

46. Finite element thermal-structural modeling of orbiting truss structures

Author

Thornton, E. A, Mahaney, J, and Dechaumphai, P

Subjects
Launch Vehicles And Space Vehicles
Abstract

A description of an integrated finite element (FE) thermal-structural approach for accurate and efficient modeling of large space structures is presented. A geometric model with a common discretization for all analyses is employed. It uses improved thermal elements and the results from the thermal analysis directly in the structural analysis without any intervening data processing. The differences between the conventional FE approach as implemented in large programs and an integrated FE approach currently under development are described. Considerations for thermal modeling of truss members is discussed and three thermal truss finite elements are presented. The performance of these elements was evaluated for typical truss members neglecting joint effects. A simple truss with metallic joints and composite members was studied to evaluate the effectiveness of the approach for realistic truss designs. A study of the effects of aluminum joints on the thermal deformations of a simple, plane truss with composite members showed that joint effects may be significant. Further study is needed to assess the role of joint effects on the deformation of large trusses.

Published
1982

47. Progress in thermostructural analysis of space structures

Author

Thornton, E. A, Dechaumphai, P, Mahaney, J, and Pandey, A. K

Subjects
Structural Mechanics
Abstract

A finite element space structures research focused on the interdisciplinary problems of heating, thermal, and structural analysis is discussed. Slender member shadowing effects, and cable stiffened structures are described.

Published
1982

48. Integrated transient thermal-structural finite element analysis

Author

Thornton, E. A, Dechaumphai, P, Wieting, A. R, and Tamma, K. K

Subjects
Fluid Mechanics And Heat Transfer
Abstract

An integrated thermal structural finite element approach for efficient coupling of transient thermal and structural analysis is presented. Integrated thermal structural rod and one dimensional axisymmetric elements considering conduction and convection are developed and used in transient thermal structural applications. The improved accuracy of the integrated approach is illustrated by comparisons with exact transient heat conduction elasticity solutions and conventional finite element thermal finite element structural analyses.

Published
1981

49. Finite element analyses of plane thermal entry-length flows

Author

Thornton, E. A and Dechaumphai, P

Subjects
Aerodynamics
Abstract

It is pointed out that the design of actively cooled engine and airframe structures for hypersonic flight requires strong interaction between fluid, thermal, and structural analyses. Research programs are being conducted to develop an integrated thermal-structural analysis capability based upon the finite element method. In connection with these programs, a finite element engineering approach has been developed based upon a number of assumptions customarily used in practical heat transfer analysis. An evaluation is conducted of the finite element engineering approach for entry-length flows. The evaluation makes use of an analysis of plane thermal entry-length flows by a finite element approach utilizing mean fluid temperatures with a convection coefficient. Another analysis is based on a finite element continuum approach, taking into account the rigorous momentum, mass, and energy equations of viscous, incompressible flow. The engineering approach was found to give excellent agreement with the rigorous continuum approach for Peclet number values not less than 100.

Published
1981

50. Exact finite elements for conduction and convection

Author

Thornton, E. A, Dechaumphai, P, and Tamma, K. K

Subjects
Fluid Mechanics And Heat Transfer
Abstract

An approach for developing exact one dimensional conduction-convection finite elements is presented. Exact interpolation functions are derived based on solutions to the governing differential equations by employing a nodeless parameter. Exact interpolation functions are presented for combined heat transfer in several solids of different shapes, and for combined heat transfer in a flow passage. Numerical results demonstrate that exact one dimensional elements offer advantages over elements based on approximate interpolation functions.

Published
1981

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