The effect of a servant leadership seminar on church leaders

Barrett, Raymond I.

January 2000

Thesis (D. Min.)--Denver Seminary, 2000. / Includes bibliographical references (leaves 227-240).

Jewish family education as a vehicle for Jewish identification, family cohesion, and congregational bonding

Fink, Steven M.

January 1999

Thesis (D. Min.)--McCormick Theological Seminary, 1999. / Includes bibliographical references.

Hydrological processes inferred from water table fluctuations, Walnut Creek, Iowa

Schilling, Keith Edwin. Zhang, You-Kuan.

January 2009

Thesis supervisor: You-Kuan Zhang. Includes bibliographic references (p. 158-172).

The role of the senior pastor in relocating a church a case study approach /

Scheil, Randall Lee.

January 2003

Thesis (D. Min.)--Trinity International University, 2003. / Abstract. Includes bibliographical references (leaves 152-155).

The effect of a servant leadership seminar on church leaders

Barrett, Raymond I.

January 2000

Thesis (D. Min.)--Denver Seminary, 2000. / Includes bibliographical references (leaves 227-240).

Bison exploitation at Chan-ya-ta (13BV1) a Mill Creek culture site in northwest Iowa /

Santure, Sharron Kay.

January 1978

Thesis (M.A.)--Wisconsin. / Includes bibliographical references (leaves 80-81).

Growing in Christ spiritual formation for church leaders at the Central Church of Christ /

Seufferlein, Terry R.,

January 2006

Thesis (D. Min.)--Abilene Christian University, 2006. / Abstract and vita. Includes bibliographical references (leaves 116-120).

Fluorosis in the early permanent dentition: evaluating gene-environment interactions

Bhagavatula Naga, V R N Pradeep

01 July 2009

No description available.

Dental Fluorosis

Gene-Environment Interactions

Iowa Fluoride Study

Dental Public Health and Education

A study of nitrogen fate and transport in agricultural landscapes at the field, wetland, and watershed scales

Drake, Chad Walter

01 December 2018

Reducing agricultural nutrient loading in Iowa is critical to achieving Gulf of Mexico hypoxia water quality goals. Iowa comprises 4.4% of the Mississippi-Atchafalaya River Basin but contributes an average of 29% of the annual nitrate (NO3-N) load to the Gulf of Mexico (Jones et al., 2018). The main goal of this research was to study nitrogen fate and transport in agricultural areas of Iowa at different spatial scales using a unique combination of water monitoring and numerical modeling. High-frequency, continuous water quality monitoring provided valuable insights into stream and wetland NO3-N dynamics. A biogeochemical model was written and coupled to a spatially distributed, surface-subsurface hydrologic model to perform continuous (multi-year) nitrogen fate and transport simulations at the field, wetland, and watershed scales. Field scale simulations of a tile-drained, corn-soybean rotation under conventional agricultural management over a 5-yr period illustrated strengths and weaknesses of the soil nitrogen model. Using a simplified approach to describe soil organic matter dynamics, the simulated annual nitrogen balance and NO3-N loss in tile drainage were comparable to observations and literature estimates. However, the model was not able to predict the correct response of NO3-N loss in tile drainage to fertilizer rate, which was attributed in part to limitations with the current plant uptake function which did not capture the nonlinear relationship expected between fertilizer rate and crop nitrogen uptake. NO3-N removal was quantified at one of Iowa’s largest constructed wetlands using high-frequency (15-min), continuous water quality monitoring and hydrologic modeling. The wetland reduced incoming NO3-N concentrations 49% and loads by an estimated 61 kg day-1 from May-Nov over a 3-yr period. Wetland removal was influenced by both hydrologic and biological conditions; mass removal was greatest in Jun when discharge and NO3-N loading were highest, while percent removal was greatest in Aug when discharge was low, water residence times in the wetland were high, and warm water temperatures enhanced processing. The high-frequency monitoring captured NO3-N dynamics not possible with traditional lower frequency grab sampling, including concentration dynamics connected to storm events telling of sources and pathways of NO3-N delivery, diurnal variations in concentration indicative of biological processes, and the marked variability in wetland removal performance during low and high flow conditions. Over 5600 wetlands of similar removal performance treating over 60% of Iowa’s area and costing $1.5 billion would be required to reduce the state’s baseline NO3-N load by 45%. The high-frequency monitoring guided and informed numerical simulations of nitrogen fate and transport at the wetland and watershed scales. Wetland simulations using imposed discharge and water quality conditions upstream of the wetland (inlet) and first order, temperature dependent kinetics produced satisfactory daily and monthly predictions of NO3-N concentration and water temperature downstream of the wetland (outlet) from May-Nov in 3/4 and 4/4 study years, respectively. NO3-N predictions were most sensitive to the denitrification first order rate constant and temperature during low discharge periods and least sensitive to both during storm events. Temperature dependent kinetics were necessary to accurately predict wetland NO3-N removal in late summer. The continuous watershed simulations produced satisfactory monthly predictions of inlet and outlet NO3-N concentration and outlet water temperature. Consistent with findings from other modeling studies, annual nitrogen components and NO3-N dynamics were simulated reasonably well under average hydrologic conditions, while simulated NO3-N dynamics weakened under extreme (wet) hydrologic conditions. Temperature was important for predicting the seasonality of wetland NO3-N removal during the growing season, while other factors such as organic carbon and dissolved oxygen may be more influential outside the growing season when removal can still occur despite cold conditions. A preliminary evaluation of six recently constructed wetlands that detain and process agricultural runoff from 12% of a 45 km2 watershed in north central Iowa estimated sizable flood and NO3-N reductions locally which diminished moving downstream. Continuous watershed simulations over a 13 month period following wetland implementation estimated peak flow reductions of 3-43% at the wetlands that dissipated with drainage area; similarly, the wetlands reduced NO3-N loads by an estimated 7-25% locally and 2% at the watershed outlet. Further refinements to the biogeochemical-hydrologic model are needed to improve simulated NO3-N dynamics in order to more reliably assess downstream flow and NO3-N reduction benefits. This work identified limitations with the current modeling approach, areas of future work, and offers recommendations to guide future conservation design. Sensible hydrologic predictions are imperative to the success and dependability of the water quality simulations, which may seem obvious but can be difficult to ascertain in ungauged catchments. Future work aspires to couple a complete agricultural systems model with a physically-based hydrologic model to simulate the nitrogen cycle in a more comprehensive manner to assess which field scale nitrogen processes are most important to accurately predict stream nutrient loading at the watershed scale. Constructed wetlands could provide greater flood and nutrient reduction benefits if the normal pool hydraulics were designed with smaller hydraulic structures that more effectively throttle down incoming flows and provide the opportunity for active rather than passive pool management. As the ultimate goal of this research and other like work is to quantify progress of water quality goals set forth by the Gulf Hypoxia Task Force and help guide future conservation practice implementation, continued investment in science-based water research, water monitoring, and water modeling is necessary.

High-frequency monitoring

Iowa

Nitrogen fate and transport

Numerical modeling

Water quality

Wetlands

Civil and Environmental Engineering

The Iowa Tests of Educational Development as Predictors of Academic Success at Utah State University

Hendricks, James Vance

01 May 1967

Academic achievement at Utah State University was predicted for a sample of students from Cache County, Utah, high schools. Predictor variables were grade point averages for grades ten-twelve and the ten scores of the Iowa Tests of Educational Development. Criteria included grade point ave rages after one quarter of college and after each college year. Simple correlation coefficients between high school and col l ege grades ranged from .655 to .706, with a median of .676 and a mean of .677, Simple correlation coefficients between s cores on the Iowa Tests of Educational Development and college grades r ange d f rom .366 to ,566, with a median of ,476 and a mean of .472 . Multiple correlation coefficients between predictor and criteria ranged from .403 to ,792, with a median of .641 and a mean of .557. Multiple regression equations were also developed for predieting grades for twenty-five university general education courses.

Iowa Tests of Educational Development

Academic Success

Utah State University

Social and Behavioral Sciences