Simulation of Thermal Energy Transport in a Fully-Integrated Surface/Subsurface Framework

Brookfield, Andrea Elizabeth

January 2009

Thermal stream loadings from both natural and anthropogenic sources have significant relevance with respect to ecosystem health and water resources management, particularly in the context of future climate change. In recent years, there has been an increase in field-based research directed towards characterizing thermal energy transport exchange processes that occur at the surface water/groundwater interface of streams. In spite of this effort, relatively little work has been performed to simulate these exchanges and elucidate their roles in mediating surface water temperatures and to simultaneously take into account all the pertinent hydrological, meteorological and surface/variably-saturated subsurface processes. To address this issue, HydroGeoSphere, a fully-integrated surface/subsurface flow and transport model, was enhanced to include fully-integrated thermal energy transport. HydroGeoSphere can simulate water flow, evapotranspiration, and advective-dispersive heat and solute transport over the 2D land surface and water flow and heat and solute transport in 3D subsurface variably-saturated conditions. In this work, the new thermal capabilities of HydroGeoSphere are tested and verified by comparing HydroGeoSphere simulation results to those from a previous subsurface thermal groundwater injection study, and also by simulating an example of atmospheric thermal energy exchange. A proof of concept simulation is also presented which illustrates the ability of HydroGeoSphere to simulate fully-integrated surface/subsurface thermal energy transport. High-resolution 3D numerical simulations of a well-characterized reach of the Pine River in Ontario, Canada are also presented to demonstrate steady-state thermal energy transport in an atmosphere-groundwater-surface water system. The HydroGeoSphere simulation successfully matched the spatial variations in the thermal patterns observed in the river bed, the surface water and the groundwater. Transient simulations of the high-resolution Pine River domain are also presented. Diurnal atmospheric conditions were incorporated to illustrate the importance of fluctuations in atmospheric parameters on the entire hydrologic regime. The diurnal atmospheric input fluxes were found to not only change the temperatures of the surface and subsurface throughout the cycle, but also the magnitude and direction of the transfer of thermal energy between the surface and subsurface. Precipitation events were also simulated for the Pine River domain using three different rainfall rates. The surface temperatures responded quickly to the rainfall events, whereas the subsurface temperatures were slower to respond in regions where infiltration was not significant. A thermal energy signal from the precipitation event was evident in the subsurface, and dissipated once the rainfall ceased. This indicates that temperature can potentially be used as a tracer for hydrograph separation. The potential of a thermal energy tracer for hydrograph separation was investigated using HydroGeoSphere simulations of the Borden rainfall-runoff experiment. These results matched both measured and previous simulation results using a bromide tracer. The hydrograph separation results from the thermal energy tracer were sensitive to temperature conditions in the subsurface, although this sensitivity reduced considerably when the precipitation event and subsurface temperatures were significantly different. The contribution of each atmospheric component to thermal energy transport was investigated using the Pine River and Borden examples. Each atmospheric component was individually neglected from the simulation of both sites to investigate their impact on thermal energy transport. The results show that longwave radiation dominates the atmospheric inputs for the Borden example, whereas shortwave radiation dominates in the Pine River example. This indicates that the atmospheric contributions to the thermal energy distribution are site-specific and cannot be generalized. In addition, these results indicate that the atmospheric contributions should not be ignored; measuring atmospheric data in the field is an important component in developing an accurate thermal energy transport model. The addition of thermal energy transport to HydroGeoSphere provides a valuable tool for investigating the impact of anthropogenic and non-anthropogenic changes to the atmospheric and hydrological thermal energy system. This computational framework can be used to provide quantitative guidance towards establishing the conditions needed to maintain a healthy ecosystem.

Thermal Energy Transport

Earth Sciences

Simulation of Thermal Energy Transport in a Fully-Integrated Surface/Subsurface Framework

Brookfield, Andrea Elizabeth

January 2009

Thermal stream loadings from both natural and anthropogenic sources have significant relevance with respect to ecosystem health and water resources management, particularly in the context of future climate change. In recent years, there has been an increase in field-based research directed towards characterizing thermal energy transport exchange processes that occur at the surface water/groundwater interface of streams. In spite of this effort, relatively little work has been performed to simulate these exchanges and elucidate their roles in mediating surface water temperatures and to simultaneously take into account all the pertinent hydrological, meteorological and surface/variably-saturated subsurface processes. To address this issue, HydroGeoSphere, a fully-integrated surface/subsurface flow and transport model, was enhanced to include fully-integrated thermal energy transport. HydroGeoSphere can simulate water flow, evapotranspiration, and advective-dispersive heat and solute transport over the 2D land surface and water flow and heat and solute transport in 3D subsurface variably-saturated conditions. In this work, the new thermal capabilities of HydroGeoSphere are tested and verified by comparing HydroGeoSphere simulation results to those from a previous subsurface thermal groundwater injection study, and also by simulating an example of atmospheric thermal energy exchange. A proof of concept simulation is also presented which illustrates the ability of HydroGeoSphere to simulate fully-integrated surface/subsurface thermal energy transport. High-resolution 3D numerical simulations of a well-characterized reach of the Pine River in Ontario, Canada are also presented to demonstrate steady-state thermal energy transport in an atmosphere-groundwater-surface water system. The HydroGeoSphere simulation successfully matched the spatial variations in the thermal patterns observed in the river bed, the surface water and the groundwater. Transient simulations of the high-resolution Pine River domain are also presented. Diurnal atmospheric conditions were incorporated to illustrate the importance of fluctuations in atmospheric parameters on the entire hydrologic regime. The diurnal atmospheric input fluxes were found to not only change the temperatures of the surface and subsurface throughout the cycle, but also the magnitude and direction of the transfer of thermal energy between the surface and subsurface. Precipitation events were also simulated for the Pine River domain using three different rainfall rates. The surface temperatures responded quickly to the rainfall events, whereas the subsurface temperatures were slower to respond in regions where infiltration was not significant. A thermal energy signal from the precipitation event was evident in the subsurface, and dissipated once the rainfall ceased. This indicates that temperature can potentially be used as a tracer for hydrograph separation. The potential of a thermal energy tracer for hydrograph separation was investigated using HydroGeoSphere simulations of the Borden rainfall-runoff experiment. These results matched both measured and previous simulation results using a bromide tracer. The hydrograph separation results from the thermal energy tracer were sensitive to temperature conditions in the subsurface, although this sensitivity reduced considerably when the precipitation event and subsurface temperatures were significantly different. The contribution of each atmospheric component to thermal energy transport was investigated using the Pine River and Borden examples. Each atmospheric component was individually neglected from the simulation of both sites to investigate their impact on thermal energy transport. The results show that longwave radiation dominates the atmospheric inputs for the Borden example, whereas shortwave radiation dominates in the Pine River example. This indicates that the atmospheric contributions to the thermal energy distribution are site-specific and cannot be generalized. In addition, these results indicate that the atmospheric contributions should not be ignored; measuring atmospheric data in the field is an important component in developing an accurate thermal energy transport model. The addition of thermal energy transport to HydroGeoSphere provides a valuable tool for investigating the impact of anthropogenic and non-anthropogenic changes to the atmospheric and hydrological thermal energy system. This computational framework can be used to provide quantitative guidance towards establishing the conditions needed to maintain a healthy ecosystem.

Thermal Energy Transport

Earth Sciences

Fully Integrated Electrochemical Sensor Based on Surface Activated Copper/Polymer Bonding for Lead Detection

Redhwan, Md Taufique Zaman

11 1900

Lead (Pb) levels in tap water below the established water safety guideline are now considered harmful, thus detecting sub-parts-per-billion level Pb is important. This thesis reports on a miniaturized Copper (Cu)−based electrochemical sensor fabricated from thick film electrodes for their superior sensing performance. These thick film electrodes are based on highly conductive rolled-annealed Cu foil that has a compact bulk structure, but these advantages are often offset by the fact that RA Cu foil is difficult to bond to a substrate due to poor film-adhesion property and lack of mechanical interlocks. For this reason, we develop a direct bonding process for Cu/polymer. An integrated three-electrode planar configuration is then fabricated on the bonded specimen to achieve a fully-functional sensor that can detect 0.2 μg/L (0.2 ppb) Pb2+ ions from a 100 μL sample in only 30 s. This is the most rapid detection of Pb featured to date by an all Cu-based sensor. This thesis first focuses on improving substrate adhesion of RA Cu foil to liquid crystal polymer (LCP). This is achieved by a surface activated bonding process where Cu and LCP surfaces are treated with low-power reactive ion etching oxygen plasma followed by low-pressure contact at 230 °C. This treatment produces hydroxyl (OH−) groups on Cu and LCP surfaces making them highly hydrophilic. When Cu and LCP are contacted and heated, the OH− chains condense by dehydration and form an intermediate oxide layer. This layer mainly develops as Cu2O nanoparticles from the plasma-treated Cu side due to thermal oxidation in air. These nanoparticles diffuse into the polymer substrate when heated under mechanical pressure, resulting in a strongly bonded flexible specimen for the sensor. A simple, inexpensive, and production-friendly fabrication process is then developed for these sensors. Following direct bonding, flexible Cu/LCP is fed into a LaserJet printer for a one-step transfer of polyester resin−based electrode mask on Cu. This is followed by etching, packaging, and a chlorinating process to achieve a fully-functional integrated sensor. The sensing performance of directly bonded Cu/LCP is comparable to that of commercially available Cu/polyimide (PI) laminate. Our approach holds promise towards realizing low-cost integrated water quality monitoring systems. / Thesis / Master of Applied Science (MASc) / Lead contamination in tap water has major health risks for which monitoring of its levels is important. In this thesis, we develop a low-cost copper/polymer-based lead sensor. The sensor is fabricated from high-quality metal foil electrodes that are integrated to a polymer substrate by a direct bonding process. This enables strong adhesion of foil-based electrodes to the substrate that is crucial to the sensor performance and packaging integrity. We investigate the bonding mechanism between copper and polymer to understand the fundamentals of materials integration. These findings will lead to the development of polymer-based sensors and integrated systems. The bonded sensor bases are mechanically flexible, which facilitates a rapid and low-cost fabrication process using a laser printer. The developed sensor has a fast response time (30 s) and can detect very low levels of lead, thus making it suitable for water quality monitoring applications in under-developed and developed countries with legacy water systems that have not been upgraded yet.

surface activated bonding

lead detection

electrochemical sensor

fully integrated

water quality monitoring

copper

polymer

environmental sensor

Identifying Asymmetries in Web-based Transfer Student Information that is Believed to be Correct using Fully Integrated Mixed Methods

Reeping, David Patrick

04 December 2019

Transfer between community colleges and four-year institutions has become more common as student mobility increases. Accordingly, the higher education system has coped with the fluidity by establishing articulation agreements that facilitate pathways from one institution to another. The forward-facing policies and guides to inform students on those pathways are known to be complicated, leading to the development of web-based tools like Transferology to help students navigate the system. Still, credit loss is common, whether through misunderstandings, lack of awareness, or changing degree plans. A proliferation of literature examines the experiences of transfer students and other agents in the process like community college advisors, but few pieces interrogate the underlying website structures that facilitate those experiences as the unit of analysis. Information related to facilitating transfer from one institution to another is often fragmented across multiple webpages or policies and uses language not optimal for communicating with students – creating what are called "information asymmetries" between the students and institutions. The premise of an exchange having information asymmetries is that one or more parties in the exchange have more or better information than the others, leading to an imbalance in power. In the case of higher education, transfer students – and their advisors by extension – can be subjected to manipulation by the invisible hands of the four-year institutions through language gaps and scattered sources of information. Accordingly, this dissertation explored four-year university websites, a major point of contact students have with information on transfer, to address the following main research question: "How are information asymmetries in curricular policies/procedures apparent for engineering students on institutional webpages in terms of language and fragmentation?" The subsequent research question synthesized the results of the first question: "Looking across information asymmetry measures, what are the different narratives of information asymmetry that integrate themes of language and fragmentation across institutions?" A fully integrated mixed methods design using all existing data was employed to address the two research questions. A stratified random sample was taken with respect to institution size based on their Carnegie classifications (n = 38). The collection of relevant public webpages based on a set of keywords from the sampled institutions was transformed into three network measures - hierarchy, centrality, and nonlinear – that were used in cluster analyses to group the institutions based on their information structures. Sequential mixed methods sampling was used to choose institutions purposefully from each cluster based on notable features recorded during the first stage of data collection. Two-cycle coding followed the cluster analysis by elaborating on the networks formed during data collection. I used joint displays to organize the networks and In-Vivo codes in the same picture and develop themes related to fragmentation and language simultaneously. K-means and K-medoids cluster methods both produced the same four cluster solution illustrating one aspect of information asymmetries through fragmentation. The clustering solution highlighted four major network patterns, plus one cluster mixing two of the patterns: 1) linear browsing, 2) centralized expansive browsing, 3) branched browsing, and 4) mixed browsing. Further qualitative analysis of the sampled institutions revealed several types of missteps where information is obscured through language or dispersed in the network. I explored a subset of 16 institutions and identified four themes related to fragmentation (unlinked divergence, progressive disclosure, lack of uniformity, and neighborhood linking) and six themes related to language (hedging transferability and applicability, legalese handwaving, building rapport, exclusivity, deviance from common practice, and defining terms). The missteps were contextualized further using six narratives with institutional examples. This work characterized the information design for transfer students as a messy web of loosely connected structures with language that complicates understanding. Integrated narratives illustrate a landscape of loosely coupled information structures that become more expansive as state initiatives interact with already existing local agreements. Moreover, institutional websites describing transfer processes use communication strategies similar to private companies writing online privacy policies. In light of the themes of information asymmetries, opportunities for supporting transfer were highlighted. For example, institutions are encouraged to create visual representations of the transfer credit process, ensure terms are defined upfront while minimizing jargon, and avoid linking to information that is easily summarizable on the current page. This research would be of interest to institutions looking to improve the presentation of their transfer information by critically examining their designs for the missteps described here. In addition, engineering education practitioners and researchers studying transfer student pathways and experiences will find the results of interest – especially in considering how to support the students despite the large information gaps. Finally, those looking to implement a fully integrated mixed methods design or use existing/archival data in their own context will find the use of mixing strategies of interest. / Doctor of Philosophy / Transfer between community colleges and four-year institutions has become more common as student mobility increases, especially for engineering. Institutions have coped with this inter-institutional movement by establishing agreements with each other that facilitate pathways between programs. The forward-facing policies and guides to inform students on such pathways are known to be complicated, leading to the development of web-based tools like Transferology to help students navigate the system. Despite these advances, transfer students continue to struggle in their information search. The purpose of this dissertation was to describe the extent to which information for engineering transfer students is scattered across multiple web-based sources and written in a manner not conducive to understanding. I used a fully integrated mixed methods design to create narratives capturing the interactions between the more quantitative idea of scatter using network analysis and the more qualitative aspect of language-use using visually based two-cycle coding across 38 U.S. four-year institutions. All data was readily available online, which were transformed and combined using several mixing strategies to form integrated stories of information asymmetries. The resulting narratives characterized the information design for transfer students as a messy web of loosely connected structures with language that complicates understanding. Moreover, institutional websites describing transfer processes use communication strategies similar to private companies writing online privacy policies. In light of the themes of information asymmetries, opportunities for supporting transfer were highlighted. This work will be of interest to those interested in engineering transfer student experiences and pathways. Also, those looking to implement fully integrated mixed methods approaches or make extensive use of existing data, especially mixing during analysis, will see strategies applicable in their own work.

Information asymmetry

transfer students

fully integrated mixed methods

policy

existing data

archival data

website design

Exploring the realm of culture within management : The effects of fully integrated relocation services on cross-cultural learning and adjustment

Armaki, Shamin

January 2019

Expatriates’ adjustment to the host-country culture is a dynamic and gradual process. This process can be facilitated by cross-cultural training. The relationship between cross-cultural training and crosscultural adjustment has been explored to a great extent in the literature, however scholars have mainly put focus on how this relationship unfolds in the context of MNCs offering CCT in-house. Consequently, this leaves an interesting uninvestigated gap in terms of how fully integrated relocation service companies work with cross-cultural services and how their work can facilitate cross-cultural adjustment. This qualitative case-study therefore aims to examine the relationship between crosscultural training provided by a relocation service company and the expatriate adjustment process. An extensive review on existing theories concerning cross-cultural adjustment, cross-cultural training and cross-cultural learning are presented. After this, the case study examines how Nordic Relocation Group (NRG), a relocation service company in Sweden, operates in terms of providing cross-cultural services. The findings indicate that the relocation service company’s services are divided into different phases, whereby the timing and content of services offered varies as the expatriates’ international assignment develops over time. This form of tailoring the cross-cultural training and the content of their services supports the notion of sequential training, which within IHRM literature, is proposed as optimal in order to facilitate the expatriate’s adjustment process. Moreover, the results further indicate that the way in which NRG works with cross-cultural services, in terms of strategy, sequential order, and specific CCT activities offered, promotes effective cross-cultural learning. Consequently, the CCT strategies offered by the relocation service company can be viewed as being aligned with best practice.

cross-cultural training

cross-cultural adjustment

cross-cultural learning

sequential training

fully integrated relocation services

Business Administration

Företagsekonomi

A Fully Integrated Fractional-N Frequency Synthesizer for Wireless Communications

Son, Han-Woong

12 April 2004

A fully integrated, fast-locking fractional-N frequency synthesizer is proposed and demonstrated in this work. In this design, to eliminate the need for large, inaccurate capacitors and resistors in a loop filter, an analog continuous-time loop filter whose performance is sensitive to process and temperature variations and aging has been replaced with a programmable digital Finite Impulse Response (FIR) filter. In addition, using the adaptive loop gain control proportional to the frequency difference, the frequency-locking time has been reduced. Also, the phase noise and spurs have been reduced by a Multi-stAge noise SHaping (MASH) controlled Fractional Frequency Detector (FFD) that generates a digital output corresponding directly to the frequency difference. The proposed frequency synthesizer provides many benefits in terms of high integration ability, technological robustness, fast locking time, low noise level, and multimode flexibility. To prove performance of the proposed frequency synthesizer, the frequency synthesizers analysis, design, and simulation have been carried out at both the system and the circuit levels. Then, the performance was also verified after fabrication and packaging.

Fully integrated

Wireless communications

FIR digital filter

PLL

Fractional-N frequency synthesizer

Frequency synthesizers

Time-Domain/Digital Frequency Synchronized Hysteresis Based Fully Integrated Voltage Regulator

January 2019

abstract: Power management integrated circuit (PMIC) design is a key module in almost all electronics around us such as Phones, Tablets, Computers, Laptop, Electric vehicles, etc. The on-chip loads such as microprocessors cores, memories, Analog/RF, etc. requires multiple supply voltage domains. Providing these supply voltages from off-chip voltage regulators will increase the overall system cost and limits the performance due to the board and package parasitics. Therefore, an on-chip fully integrated voltage regulator (FIVR) is required. The dissertation presents a topology for a fully integrated power stage in a DC-DC buck converter achieving a high-power density and a time-domain hysteresis based highly integrated buck converter. A multi-phase time-domain comparator is proposed in this work for implementing the hysteresis control, thereby achieving a process scaling friendly highly digital design. A higher-order LC notch filter along with a flying capacitor which couples the input and output voltage ripple is implemented. The power stage operates at 500 MHz and can deliver a maximum power of 1.0 W and load current of 1.67 A, while occupying 1.21 mm2 active die area. Thus achieving a power density of 0.867 W/mm2 and current density of 1.377 A/mm2. The peak efficiency obtained is 71% at 780 mA of load current. The power stage with the additional off-chip LC is utilized to design a highly integrated current mode hysteretic buck converter operating at 180 MHz. It achieves 20 ns of settling and 2-5 ns of rise/fall time for reference tracking. The second part of the dissertation discusses an integrated low voltage switched-capacitor based power sensor, to measure the output power of a DC-DC boost converter. This approach results in a lower complexity, area, power consumption, and a lower component count for the overall PV MPPT system. Designed in a 180 nm CMOS process, the circuit can operate with a supply voltage of 1.8 V. It achieves a power sense accuracy of 7.6%, occupies a die area of 0.0519 mm2, and consumes 0.748 mW of power. / Dissertation/Thesis / Doctoral Dissertation Electrical Engineering 2019

Electrical engineering

Energy

Buck Converter

DC- DC

Digital Hysteresis Control

Fully Integrated Voltage Regulator

Power Density

Time Domain

Switched-Capacitor DC-DC Converters for Near-Threshold Design

Abdelfattah, Moataz

January 2017

No description available.

Electrical Engineering

How College Students' Conceptions of Newton's Second and Third Laws Change Through Watching Interactive Video Vignettes: A Mixed Methods Study

Engelman, Jonathan

January 2016

No description available.

Science Education

Interactive Video Vignettes

Conceptual Change

Fully Integrated Mixed Methods Design

Elicit, Confront, Resolve, Reflect

Physics Education Research

Design of Power Combining Amplifiers for Mobile Communications

Zhao, Jinshu

04 June 2024

This work explores the application of various power amplifier design techniques for mobile communications. Several circuit configurations including class A amplifier, Doherty amplifier and power combining amplifier have been developed, which are to improve the performance of power amplifiers in terms of power added efficiency transmission power and bandwidth. In chapter 2, the cascode PA adopting tuning capacitor structure is proposed and implemented to enhance the efficiency. In chapter 3, a novel Doherty amplifier configuration using a 3-stage polyphase filter as power splitter is introduced. Moreover, the second harmonic cancellation function of balun combining PA is analysed and verified with experimental results in chapter 4. The fully integrated cascode class A amplifier adopts RC negative feedback, which is to enhance bandwidth and input/output matching. The integrated choke inductor compensating the parasitic capacitor of transistors has very low quality factor, which decreases the efficiency of the power amplifier. To reduce the inductance value of the choke inductor, a tuning capacitor is connected in parallel with the choke inductor. As a result, the inductor resistance is reduced as well, which diminishes the power consumption induced by the resistance of the choke inductor. This proposed PA configuration is validated by simulation results with the PAE improved by 3 % at the 1 dB compression point compared to the topology without tuning capacitor. The experimental results demonstrate a PA which delivers an output power of 21.3 dBm with PAE of 21 % at the 1 dB compression point. The Doherty amplifier with 2-way Wilkinson power splitter is integrated in a 0.9 mm×1.8 mm chip. The main and peak amplifier adopt cascode configuration to improve the stability of the Doherty amplifier. To minimize the chip size, the quarter wave transmission line in the topology is replaced by π-type lumped element equivalent network. To increase the operating bandwidth, the Doherty amplifier configuration using a 3-stage polyphase filter as power splitter is proposed. The topology consists of 3-stage RC polyphase filter, drive amplifiers, main amplifier, peak amplifier, and impedance inverter. By employing the polyphase filter, the quarter-wave transmission line at the input of the peak amplifier for compensating the phase shift of the impedance inverter is eliminated. According to the analysis of the polyphase filter prototype, the 3-stage polyphase filter is selected, and the component parameters are determined. The main amplifier and peak amplifier are using differential cascode configuration. The drive amplifier is to increase the power gain and provide proper impedance matching for the Doherty amplifier. The results demonstrate an outstanding broadband Doherty amplifier with a bandwidth of 1.8 GHz. The chip temperature rises dramatically due to the high power consumption of power amplifier. Consequently, the collector currents of the SiGe transistors are varying with the changing temperature, which deteriorates the PA performance. In the improved 3-stage PPF Doherty design, the bias voltages of the transistors in the first version 3-stage PPF Doherty amplifier are replaced by reference currents feeding through bias circuits. With current sources providing bias current to the transistors, the performance of the improved Doherty amplifier is enhanced. The power combining PAs are constructed on FR-4 PCB boards using discrete components. The single ended power amplifier in the power combining PA is built with high linearity HEMT transistor. The balun combining PA has an advantage of second harmonic cancellation, which is validated by both analysis and measurements. Moreover, power combining PAs with 2-way transmission line and lumped element Wilkinson power divider are designed. The transmission lines in these designs are analyzed using EM simulation tool and verified with testing structures on PCB boards.

info:eu-repo/classification/ddc/621

ddc:621