An Investigation of Quantifying and Monitoring Stone Surface Deterioration Using Three Dimensional Laser Scanning

Three dimensional laser scanning is considered to be the next generation of documentation methods, however the cost of these technologies remains extremely high and there are both known and unknown limitations of their application. This thesis, therefore, investigates the strengths and weaknesses of 3D laser scanning, identifies potential sources of error, investigates potential uses for the data while focusing on its use for quantifying and monitoring stone surface deterioration, and determines the success of resulting 3D models for communicating conditions information. Additionally, the ambiguity in existing literature regarding success of applications of 3D laser scanning for meeting project objectives, including cost - benefit analyses, indicates this topic warrants exploration. In order to perform this analysis four topics of investigation are followed: 1) Identification of tools for recording and monitoring surface deterioration of stone, which will provided a basis for comparing laser scanning techniques. 2) Identification of recording standards and objectives for heritage sites, which laser scanning methods must satisfy. 3) Identification of stone deterioration types and surface appearance, specifically marble, which laser scanning data will need to represent for conditions analysis. 4) Undertaking a test case study: three dimensional laser scanning of the stone lions at the Merchants’ Exchange Building, Philadelphia, PA, to determine whether the data can be used for conditions surveying and monitoring of surface deterioration on the lions. The coalescence of these topics will provide a datum on which to begin investigating whether or not 3D laser scanning is an appropriate and practicable tool for enabling informed decision making for conservation and heritage management

Emerging Approaches to DNA Data Storage: Challenges and Prospects

With the total amount of worldwide data skyrocketing, the global data storage demand is predicted to grow to 1.75 × 1014GB by 2025. Traditional storage methods have difficulties keeping pace given that current storage media have a maximum density of 103GB/mm3. As such, data production will far exceed the capacity of currently available storage methods. The costs of maintaining and transferring data, as well as the limited lifespans and significant data losses associated with current technologies also demand advanced solutions for information storage. Nature offers a powerful alternative through the storage of information that defines living organisms in unique orders of four bases (A, T, C, G) located in molecules called deoxyribonucleic acid (DNA). DNA molecules as information carriers have many advantages over traditional storage media. Their high storage density, potentially low maintenance cost, ease of synthesis, and chemical modification make them an ideal alternative for information storage. To this end, rapid progress has been made over the past decade by exploiting user-defined DNA materials to encode information. In this review, we discuss the most recent advances of DNA-based data storage with a major focus on the challenges that remain in this promising field, including the current intrinsic low speed in data writing and reading and the high cost per byte stored. Alternatively, data storage relying on DNA nanostructures (as opposed to DNA sequence) as well as on other combinations of nanomaterials and biomolecules are proposed with promising technological and economic advantages. In summarizing the advances that have been made and underlining the challenges that remain, we provide a roadmap for the ongoing research in this rapidly growing field, which will enable the development of technological solutions to the global demand for superior storage methodologies

INTEGRATED MICROSYSTEM-BASED APPROACH FOR DETECTION AND TREATMENT OF BACTERIAL BIOFILMS ON URINARY CATHETERS

Biofilms are a ubiquitous mode of growth for bacteria and present a significant challenge in healthcare due to their resistant nature towards traditional antibiotic therapy. Particularly, biofilms can form on indwelling urinary catheters, leading to catheter-associated urinary tract infections, which are one of the most prevalent healthcare-acquired infections. In recent years, microsystems-based approaches have been developed to measure and study bacterial biofilms. In this dissertation, microsystems are adapted for the catheterized urinary tract environment to address biofilm infections in situ. Specifically, a proof-of-concept device comprised of gold interdigitated electrodes on a flexible polyimide substrate is fabricated and characterized in vitro. This substrate allows the device to conform seamlessly with the cylindrical surface of a catheter. Real-time impedance sensing is demonstrated, showing an average decrease in impedance of 30.3% following 24 hours of biofilm growth. The device also applies the bioelectric effect, which yields an increase in impedance of 12% and the lowest biomass relative to control treatments. Furthermore, 3D-printed molds and commercial modeling software show that the cylindrical conformation does not have an appreciable impact on performance. This device is integrated with a commercially available Foley catheter using two disparate approaches: (1) integration of the flexible proof-of-concept device using a 3D-printed catheter insert and (2) electroless plating directly onto the catheter lumen. In addition to electrode integration, miniaturized electronic systems are developed to control sensing and treatment wirelessly with a minimal form factor. A smartphone mobile application is developed in conjunction with this effort, to provide a user-friendly interface for the system. Several functions are verified with the integrated system, including biofilm sensing, wireless signal transmission, bladder drainage, and balloon inflation. To decrease the risk associated with this system for future research in vivo and in a clinical setting, sensing and treatment are evaluated under realistic conditions. The biochemical aspect of the catheterized environment is recreated using artificial urine, and the physical aspect is recreated using a silicone model of a human bladder and a programmable pump. A 13.0% decrease in impedance is associated with bacterial growth; this decreased magnitude relative to the proof-of-concept device is due to the reduced degree of growth in artificial urine. The bioelectric effect is demonstrated as well, showing a reduction in planktonic bacteria of 1.50×107 CFU/ml and adhered biomass equivalent to OD590nm = 0.072 relative to untreated samples. This work provides a framework for developing microsystem-based tools for biofilm infection management and research from proof-of-concept to integrated system, particularly for CAUTI. The results demonstrate that the cylindrical conformation does not interfere with device sensing or treatment performance and that the system maintains functionality under realistic conditions, laying the groundwork for future in vivo and clinical testing. The system will provide in situ and real-time data regarding catheter biofilm colonization in a way that is not possible with existing techniques. Finally, the system can serve to reduce reliance on antibiotics and reduce the spread of antibiotic resistance in CAUTI and other vulnerable areas

USCID Fourth international conference on irrigation and drainage

Presented at the Role of irrigation and drainage in a sustainable future: USCID fourth international conference on irrigation and drainage on October 3-6, 2007 in Sacramento, California.Includes bibliographical references.Integrated regional water management -- Change of irrigation water quantity according to farm mechanization and land consolidation in Korea -- Local stakeholders participation for small scale water resources management in Bangladesh -- Water user participation in Egypt -- The man swimming against the stream knows the strength of it -- Roles and issues of Water Users' Associations for Sustainable Irrigation and Drainage in the Kyrgyz Republic and Uzbekistan in Central Asia -- Chartered Water User Associations of Afghanistan -- Updated procedures for calculating state-wide consumptive use in Idaho -- Measuring and estimating open water evaporation in Elephant Butte Reservoir in New Mexico -- Evapotranspiration of deficit irrigated sorghum and winter wheat -- Evaluation of a two-layer model to estimate actual evapotranspiration for vineyards -- Estimating pecan water use through remote sensing in Lower Rio Grande -- Estimating crop water use from remotely sensed NDVI, crop models, and reference ET -- Alfalfa production using saline drainage water -- Performance evaluation of subsurface drainage system under unsteady state flow conditions in coastal saline soils of Andhrapradesh, India -- Management strategies for the reuse of wastewater in Jordan -- Providing recycled water for crop irrigation and other uses in Gilroy, California -- Oakdale Irrigation District Water Resources Plan -- Use of information technology to support integrated water resources management implementation -- Decision-support systems for efficient irrigation in the Middle Rio Grande -- Salt management -- Ghazi Barotha Project on Indus River in Pakistan -- Field tests of OSIRI -- Water requirements, irrigation evaluation and efficiency in Tenerife's crops (Canary Islands, Spain) -- Using wireless technology to reduce water use in rice production -- Variability of crop coefficients in space and time -- Assessing the implementation of integrated water management approach in closed basins -- New strategies of donors in the irrigation sector of Africa -- Holistic perspective for investments in agricultural drainage in Egypt -- Mapping system and services for canal operation techniques -- An open channel network modernization with automated structures -- Canal control alternatives in the irrigation district 'Sector BXII del Bajo Guadalquivir,' Spain -- Hydrodynamic behavior of a canal network under simultaneous supply and demand based operations -- Simulation on the effect of microtopography spatial variability on basin irrigation performance -- Drip irrigation as a sustainable practice under saline shallow ground water conditions -- Water retention, compaction and bean yield in different soil managements under a center pivot system -- Precision mechanical move irrigation for smallholding farmers -- Wild flood to graded border irrigation for water and energy conservation in the Klamath basin -- A method describing precise water application intensity under a CPIS from a limited number of measurements -- An irrigation sustainability assessment framework for reporting across the environmental-economic-social spectrum -- Planning for future irrigation landscapes -- One size does not fit all -- Water information networks -- Improving water use efficiency -- Irrigation system modernization in the Middle Rio Grande Valley -- Relationship of operation stability and automatic operation control methods of open canal -- Responsive strategies of agricultural water sector in Taiwan -- Effect of network water distribution schedule and different on-farm water management practices on sugarbeet water use efficiency -- Variable Frequency Drive (VFD) considerations for irrigation -- Accuracy of radar water level measurements -- Transition submergence and hysteresis effects in three-foot Cutthroat flumes -- Practical irrigation flow measurement and control -- Linear anionic PAM as a canal water seepage reducing technology -- In-situ non-destructive monitoring of water flow in damaged agricultural pipeline by AE -- Reoptimizing global irrigation systems to restore floodplain ecosystems and human livelihoods -- Water management technologies for sustainable agriculture in Kenya -- Impacts of changing rice irrigation practices on the shallow aquifer of Nasunogahara basin, Japan -- Drought protection from an in-lieu groundwater banking program -- Development of agricultural drought evaluation system in Korea -- Bean yield and root development in different soil managements under a center pivot system -- Can frost damage impact water demand for crop production in the future? -- Real time water delivery management and planning in irrigation and drainage networks -- Growth response of palm trees to the frequency of irrigation by bubblers in Khuzestan, Iran -- Application of Backpropagation Neural Network to estimate evapotranspiration for ChiaNan irrigated area, Taiwan -- Increasing water and fertilizer use efficiency through rain gun sprinkler irrigation in sugar cane agriculture

USCID fourth international conference

Presented at the Role of irrigation and drainage in a sustainable future: USCID fourth international conference on irrigation and drainage on October 3-6, 2007 in Sacramento, California.Salt management is a critical component of irrigated agriculture in arid regions. Successful crop production cannot be sustained without maintaining an acceptable level of salinity in the root zone. This requires drainage and a location to dispose drainage water, particularly, the salts it contains, which degrade the quality of receiving water bodies. Despite the need to generate drainage water to sustain productivity, many irrigation schemes have been designed and constructed with insufficient attention to drainage, to appropriate re-use or disposal of saline drainage water, and to salt disposal in general. To control the negative effects of drainage water disposal, state and federal agencies in several countries now are placing regulations on the discharge of saline drainage water into rivers. As a result, many farmers have implemented irrigation and crop management practices that reduce drainage volumes. Farmers and technical specialists also are examining water treatment schemes to remove salt or dispose of saline drainage water in evaporation basins or in underlying groundwater. We propose that the responsibility for salt management be combined with the irrigation rights of farmers. This approach will focus farmers' attention on salt management and motivate water delivery agencies and farmers to seek efficient methods for reducing the amount of salt needing disposal and to determine methods of disposing salt in ways that are environmentally acceptable

USCID fourth international conference

Presented at the Role of irrigation and drainage in a sustainable future: USCID fourth international conference on irrigation and drainage on October 3-6, 2007 in Sacramento, California.Includes bibliographical references.Application of different irrigation management practices plays a considerable role in water saving to achieve potential yields. On the other hand, network water distribution schedule is a governing factor in this regard. In current study conducted in Mahabad plain in North West of Iran, four different irrigation managements on sugarbeet cultivation including traditional farmer's management, Furrow Deepening, Reduced Discharge per Deepened Furrow, and Alternate Furrow Irrigation have been studied in real farmers' fields measuring 10.2 hectares. Participatory management approach has been used while working in farmers' fields. Soils textures are silty clayey. Results of studies indicate that water used has been reduced considerably while higher root and sugar yields are obtained due to better on-farm water management practices. Water Use Efficiency, in kg of yield per m3 of water used, increased considerably under alternate furrow irrigation management in comparison to what obtained under traditional management. Results show application of alternate furrow irrigation in sugarbeet cultivation not only resulted in lesser water use per hectare, but also it increased both root and sugar yields and, consequently, higher water use efficiency was obtained. Assessments have been made on irrigation schedule imposed by the irrigation network and its effects on actual water requirements. Results show that the delivery schedule practiced in the network in incapable of delivering the actual amount of water requirement for the dominant crop of the scheme. Suggestions are made to the network operator to improve overall network efficiency including revisions on water resources planning and allocation and/or improve network operation system

USCID fourth international conference

Presented at the Role of irrigation and drainage in a sustainable future: USCID fourth international conference on irrigation and drainage on October 3-6, 2007 in Sacramento, California.Includes bibliographical references.As a lower riparian country Bangladesh is largely dependent on 57 transboundary rivers. The upstream courses of these river systems traverse India, China, Nepal, Bhutan and Myanmar. Each day, approximately 3,000 million cubic meters of water discharge into the Bay of Bengal through these rivers. However, flows are much lower during the dry season when surface water is critical to such uses as irrigation, salinity control, habitat preservation, effluent dilution and navigation. Unilateral diversion of water from the transboundary rivers impedes agricultural development using irrigation-fertilizers-modern varieties technology. Thus, sustainable irrigation system is instrumental for the growth of food production. For this, peoples' participation is prerequisite to form social capital in building consensus about the irrigation water uses. Local Government Engineering Department (LGED) has developed a model to facilitate sustainable use of water resources and demonstrated its effectiveness for irrigation management. It develops stakeholders-driven water infrastructure in subprojects each covering 1,000 ha or less. LGED involves local people in subproject planning, design, construction and operation and maintenance (O&M). It has constructed 320 subprojects under the Small Scale Water Resources Development Sector Project. Case study in a subproject in northwestern part of the country found that local stakeholders' participation in managing water resources and operation of water control infrastructure results in excellent performance of irrigation system and improvement of distribution system. This raises irrigation efficiency with productive use of water and releases constraints on land use through facilitating cultivation in three crop seasons and increases the proportion of irrigated area under small farms

"When We Came There Was Nothing": Land, Work, and Value among Transnational Soybean Farmers in the Brazilian Cerrado

This dissertation is a comparative ethnography of two groups of transnational soybean farmers in the Brazilian Cerrado. In this exploration of migration and industrial crop production for global markets, the new capacity for highly flexible farming is examined in relation to the fixity of family tradition, religious practices, landscapes, and expertise born of working the land. In 1968, Holdeman Mennonites embarked on a tour of rural Brazil. In search of autonomy from an encroaching cultural crisis, they found cheap farm land in Rio Verde, Goiás and encountered a government eager for their migration. Decades later, a group of Midwestern family farmers toured rural Brazil and found cheap, expansive land to occupy. They courted investors (mostly neighboring farmers), bought massive tracts of land, and settled in Luis Eduardo Magalhães, Bahia. The two groups’ migrations began with experiences of crisis: for the Mennonites a cultural crisis in the United States that threatened their family and community reproduction and for the Midwestern family farmers a farm crisis which threatened their livelihoods. In Brazil they adopted common farming techniques related to soil fertilization and tillage, yet differed in crop rotations, use of technology, and most starkly in their perceptions of what counted as “good farming.” Each community internally contested identity and value as they made meaning out of transnational lives and industrial farming. These cases problematize how we understand large-scale processes of the South American soy boom, the massive expansion of soy production in South America, the global land grab, and the proliferation of global land deals. This dissertation identifies difference and generativity of farming in two communities of transnational soybean farmers while also recognizing the power and domination behind such massive economic processes. The Holdeman Mennonite community pursues an alternative to soybean development in their use of family labor, avoidance of capital and technology, and diversified farming practices. The community of Midwestern family farmers adopts capitalist managerial and farming practices, yet reconcile this with their values of good farming. Together they reveal areas of convergence and divergence that make industrial, transnational soybean production possible.Doctor of Philosoph