The cross in the valley ; the history of the establishment of the Catholic church in the Northern San Joaquin Valley of California up to 1863

Bonta, Robert Eugene

01 January 1963

This thesis is the story of the development of the Catholic Church in San Joaquin County and the adjacent areas that were served by the pioneer clergymen of Stockton 1 s St. Mary's Church from approximately 1851 to 186). These first dozen years of Central California Catholicism cover the pastorates of Stockton's first four priests: Fathers Dominic Blaive, Cornelius Delahunty, Robert Maurice, and Joseph Gallagher. These dozen years mark the transition of Stockton from a hectic supply center for the Southern Mines to a stable community whose economy became, based upon the agricultural production of its surrounding rural areas. These first four pastors, then, witnessed the development of the early American Catholic Church from its infancy as a mission when Abbe Blaive arrived in Stockton from his native France, to its maturity as a stable.and respected community church under the spiritual direction of the American, Father Joseph Gallagher.

Catholic Church

California

San Joaquin Valley

St Mary of the Assumption (Stockton

Calif)

Arts and Humanities

History

Acquisition development and demonstration of grit among latina teachers from the central San Joaquin Valley

Mitchell, Jane Virginia

01 January 2015

This qualitative collective case study explored how four female Latina teachers in the Central San Joaquin Valley acquired and developed the noncognitive trait of grit. Additionally, this study explored how the manifestation of this noncognitive trait of grit is demonstrated by these teachers with students in their classrooms. Through a series of interviews, and classroom observations with annotated field notes, I examined the life experiences and professional educational background of participants in order to highlight factors that are contributory and fundamental in the underpinnings of how grit developed in each of their lives. I examined and analyzed distinctive traits, specific influences, and behaviors. The theoretical framework developed by Duckworth, Peterson, Matthews and Kelly (2007) provided the background structure to help in understanding the noncognitive trait of grit. This exploration extended current scholarship on grit by exploring one specific cultural and gendered-subset of teachers to aid in the understanding of how grit emerges in teachers deemed exceptional. This qualitative case study addresses the following questions: 1. From the perspective of four female Latina teachers, what is grit? 2. From the perspectives of four female Latina teachers, in what ways has grit been acquired, developed and demonstrated? 3. From the perspective of four female Latina teachers, how has gender and race shaped their experiences in grit? 4. From the perspectives of four female Latina teachers, and as evidenced by student outcomes, how does the trait of grit impact teacher effectiveness?

Minority women educators

San Joaquin Valley California

Perseverance (Ethics)

Personality development

Characters and characteristics

Success

Teacher-student relationships

Education

Simulating the Predevelopment Hydrologic Condition of the San Joaquin Valley, California

Bolger, Benjamin Luke

January 2009

The San Joaquin Valley is part of the Great Central Valley of California, a major agricultural centre and food supplier for the United States. This area has significant water management concerns given the very high water demand for an increasing state population and for intense irrigation in a hot, temperate to semi-arid climate where the overall rate of evapotranspiration (ET) is high, and the overall rate of precipitation is low. Irrigation heavily relies upon groundwater and surface water extractions. Through the historical and current concerns of regional water resources reliability, land surface subsidence, water quality issues, and the health of ecosystems, a need for regional-scale water resource management and planning has developed. The physically-based surface-subsurface HydroGeoSphere (HGS) model is used to examine the regional-scale hydrologic budget of a large portion of the San Joaquin Valley. The objective of this investigation is to develop a steady-state groundwater-surface water model of the San Joaquin Valley representative of predevelopment hydrologic conditions. The groundwater-surface water system has undergone drastic changes since the employment of groundwater and surface water extractions for irrigation and mining, and is still responding to past and present stresses. The only certain stable initial condition must therefore be that of the natural system. The model input parameters were constrained by all relevant available hydrologic data. The model was not calibrated to subsurface hydraulic heads or river flows. However, the model does provide a fair match between simulated and actual estimated water table elevations. Historic river flow estimates were not used to calibrate the model, because data consistent with that collected by Hall (1886) and representative of the natural system were not available. For this investigation, water enters through precipitation and the inflow of major rivers only. The subsurface domain is bounded by no-flow boundaries, and groundwater is therefore only able to exit the subsurface through discharge to surface water features or through ET. Surface water is only able to exit the model through discharge via the San Joaquin River and through ET. Average river inflows circa 1878 to 1884 documented by Hall (1886) were applied where the rivers enter into the valley. The spatially variable average rate of precipitation (years 1971 to 2000) from a PRISM dataset was applied to the top of the model. The spatially variable long term average potential ET rates from the California Department of Water Resources (DWR) et al. (1999) were applied to the top of the model. Averaged overland flow parameters and vegetation factors needed to calculate actual ET were specified at the top of the model based on literature values and the 1874 spatial distribution of natural vegetation provided by California State University at Chico et al. (2003). Hydrogeological data including hydraulic conductivities, porosities, specific storage, and unsaturated zone properties are based on literature values from other relevant studies. The resulting steady state model is therefore characterized by historical long term average data assumed to be representative (as close as possible) of the flow system circa 1848. Results indicate that the natural hydrologic setting of the San Joaquin Valley is a complex one. Complex hydrologic processes, including significant groundwater-surface water interaction along the major rivers and within wetland areas formed by flooded surface water, as well as ET and impacted root zone processes were identified in the model domain. Identification and simulation of the complex recharge and discharge relationships in the model domain sheds insight into the hydrologic nature of some historic natural wetlands. Evapotranspiration is a very significant sink of both surface water and groundwater (44.8 % of the water balance input), and has a major impact on hydrologic processes in the root zone. The presence and path of the major rivers in the domain are well defined in the model output and agree well with their actual locations. The model simulates gaining and losing reaches of the major rivers, replicating the historic recharge-discharge relationship documented by others. The general location, formation, and hydrologic processes of some significant wetlands simulated by the model have a fair agreement with historical records. As mentioned above, there is also a fair match between simulated and actual estimated water table elevations. Successful simulation of the complex hydrologic processes and features that characterize the predevelopment hydrologic conditions of the San Joaquin Valley and that resolve the water balance of the natural system underscores the importance and necessity of using an integrated model. This steady state model should serve as a reasonable initial condition for future transient runs that bring the model up to current hydrologic conditions capable of estimating present and future water budgets.

San Joaquin Valley

water budget

regional water resources

predevelopment hydrologic conditions

surface water

integrated modelling

groundwater

groundwater-surface water interaction

Earth Sciences

Simulating the Predevelopment Hydrologic Condition of the San Joaquin Valley, California

Bolger, Benjamin Luke

January 2009

The San Joaquin Valley is part of the Great Central Valley of California, a major agricultural centre and food supplier for the United States. This area has significant water management concerns given the very high water demand for an increasing state population and for intense irrigation in a hot, temperate to semi-arid climate where the overall rate of evapotranspiration (ET) is high, and the overall rate of precipitation is low. Irrigation heavily relies upon groundwater and surface water extractions. Through the historical and current concerns of regional water resources reliability, land surface subsidence, water quality issues, and the health of ecosystems, a need for regional-scale water resource management and planning has developed. The physically-based surface-subsurface HydroGeoSphere (HGS) model is used to examine the regional-scale hydrologic budget of a large portion of the San Joaquin Valley. The objective of this investigation is to develop a steady-state groundwater-surface water model of the San Joaquin Valley representative of predevelopment hydrologic conditions. The groundwater-surface water system has undergone drastic changes since the employment of groundwater and surface water extractions for irrigation and mining, and is still responding to past and present stresses. The only certain stable initial condition must therefore be that of the natural system. The model input parameters were constrained by all relevant available hydrologic data. The model was not calibrated to subsurface hydraulic heads or river flows. However, the model does provide a fair match between simulated and actual estimated water table elevations. Historic river flow estimates were not used to calibrate the model, because data consistent with that collected by Hall (1886) and representative of the natural system were not available. For this investigation, water enters through precipitation and the inflow of major rivers only. The subsurface domain is bounded by no-flow boundaries, and groundwater is therefore only able to exit the subsurface through discharge to surface water features or through ET. Surface water is only able to exit the model through discharge via the San Joaquin River and through ET. Average river inflows circa 1878 to 1884 documented by Hall (1886) were applied where the rivers enter into the valley. The spatially variable average rate of precipitation (years 1971 to 2000) from a PRISM dataset was applied to the top of the model. The spatially variable long term average potential ET rates from the California Department of Water Resources (DWR) et al. (1999) were applied to the top of the model. Averaged overland flow parameters and vegetation factors needed to calculate actual ET were specified at the top of the model based on literature values and the 1874 spatial distribution of natural vegetation provided by California State University at Chico et al. (2003). Hydrogeological data including hydraulic conductivities, porosities, specific storage, and unsaturated zone properties are based on literature values from other relevant studies. The resulting steady state model is therefore characterized by historical long term average data assumed to be representative (as close as possible) of the flow system circa 1848. Results indicate that the natural hydrologic setting of the San Joaquin Valley is a complex one. Complex hydrologic processes, including significant groundwater-surface water interaction along the major rivers and within wetland areas formed by flooded surface water, as well as ET and impacted root zone processes were identified in the model domain. Identification and simulation of the complex recharge and discharge relationships in the model domain sheds insight into the hydrologic nature of some historic natural wetlands. Evapotranspiration is a very significant sink of both surface water and groundwater (44.8 % of the water balance input), and has a major impact on hydrologic processes in the root zone. The presence and path of the major rivers in the domain are well defined in the model output and agree well with their actual locations. The model simulates gaining and losing reaches of the major rivers, replicating the historic recharge-discharge relationship documented by others. The general location, formation, and hydrologic processes of some significant wetlands simulated by the model have a fair agreement with historical records. As mentioned above, there is also a fair match between simulated and actual estimated water table elevations. Successful simulation of the complex hydrologic processes and features that characterize the predevelopment hydrologic conditions of the San Joaquin Valley and that resolve the water balance of the natural system underscores the importance and necessity of using an integrated model. This steady state model should serve as a reasonable initial condition for future transient runs that bring the model up to current hydrologic conditions capable of estimating present and future water budgets.

San Joaquin Valley

water budget

regional water resources

predevelopment hydrologic conditions

surface water

integrated modelling

groundwater

groundwater-surface water interaction

Earth Sciences

California's War Over the Bay-Delta: Historic Failures and Current Battles

Mao, Jessica J.

01 January 2012

California has one highly-coveted possession: the Bay-Delta, which is the second largest estuary in the United States. Today, tensions are higher than ever as Southern California continues to grow and demand water from the Delta, agriculture suffers from drought and less-than-promised water allocations, and aquatic life diminishes due to environmentally damaging processes like pumping and exporting of water elsewhere. This paper will examine the historic policies that have shaped how the Delta has been managed, their successes and failures, and current plans in discussion for continuing improvement of the Delta. The Bay-Delta Conservation Plan and the Sacramento-San Joaquin Valley Water Reliability Act (HR 1837) are the specific current plans presented and analyzed for potential effectiveness. Despite some of the promising suggestions in HR 1837 and the Bay-Delta Conservation Plan, the Delta will remain a problem in the 21st century until stakeholders from all perspectives compromise enough to enact a single, clear-cut solution.

HR 1837

Bay-Delta Conservation Plan

Water Management Policy

Solutions and Compromise

Agricultural and Resource Economics

Environmental Law

Environmental Policy

Natural Resources Law

Politics

Water Law