Evan Pugh’s Penn State


Book Description

When Evan Pugh became the first president of Pennsylvania’s Farmers’ High School—later to be known as The Pennsylvania State University—the small campus was in disrepair and in dire need of leadership. Pugh was young, barely into his 30s, but he was energetic, educated, and visionary. During his tenure as president he molded the school into a model institution of its kind: America’s first scientifically based agricultural college. In this volume, Roger Williams gives Pugh his first book-length biographical treatment. Williams recounts Pugh’s short life and impressive career, from his early days studying science in the United States and Europe to his fellowship in the London Chemical Society, during which he laid the foundations of the modern ammonium nitrate fertilizer industry, and back to Pennsylvania, where he set about developing “upon the soil of Pennsylvania the best agricultural college in the world” and worked to build an American academic system mirroring Germany’s state-sponsored agricultural colleges. This last goal came to fruition with the passage of the Morrill Act in 1862, just two years prior to Pugh’s death. Drawing on the scientist-academic administrator’s own writings and taking a wide focus on the history of higher education during his lifetime, Evan Pugh’s Penn State tells the compelling story of Pugh’s advocacy and success on behalf of both Penn State and land-grant colleges nationwide. Despite his short life and career, Evan Pugh’s vision for Penn State made him a leader in higher education. This engaging biography restores Pugh to his rightful place in the history of scientific agriculture and education in the United States.




Evan Pugh's Penn State


Book Description

Explores the contributions of Evan Pugh (1828-1864), founding president of today's Pennsylvania State University, in quickly building it into America's first scientifically based agricultural college.




Frederick Watts and the Founding of Penn State


Book Description

Frederick Watts came to prominence during the nineteenth century as a lawyer and a railroad company president, but his true interests lay in agricultural improvement and in raising the economic, social, and political standing of Pennsylvania’s farmers. After being elected founding president of The Pennsylvania State Agricultural Society in 1851, he used his position to advocate vigorously for the establishment of an agricultural college that would employ science to improve farming practices. He went on to secure the charter for the Farmers’ High School of Pennsylvania, which would eventually become the Pennsylvania State University. This biography explores Watts’s role in founding and leading Penn State through its formative years. Watts adroitly directed the school as it was sited, built, and financed, opening for students in 1859. He hired the brilliant Evan Pugh as founding president, who, with Watts, quickly made it the first successful agricultural college in America. But for all his success in launching the institution, Watts nearly brought it to the brink of closure through a series of ruinous presidential appointments that led to an abandonment of the land-grant focus on agriculture and engineering. Watts’s influence in the agricultural modernization movement and his impact on land-grant education in the United States—both in his role with Penn State and later as US commissioner of agriculture—made him a leader in the history of agricultural and higher education. Roger L. Williams’s compelling biography of Watts reestablishes him in this legacy, providing a balanced analysis of his missteps and accomplishments.







Signature in the Cell


Book Description

"This book attempts to make a comprehensive, interdisciplinary case for a new view of the origin of life"--Prologue.




Environmental Transport Processes


Book Description

A unique approach to the challenges of complex environmental systems Environmental Transport Processes, Second Edition provides much-needed guidance on mass transfer principles in environmental engineering. It focuses on working with uncontrolled conditions involving biological and physical systems, offering examples from diverse fields, including mass transport, kinetics, wastewater treatment, and unit processes. This new edition is fully revised and updated, incorporating modern approaches and practice problems at the end of chapters, making the Second Edition more concise, accessible, and easy to use. The book discusses the fundamentals of transport processes occurring in natural environments, with special emphasis on working at the biological physical interface. It considers transport and kinetics in terms of systems that involve microorganisms, along with in-depth coverage of particles, size spectra, and calculations for particles that can be considered either spheres or fractals. The book's treatment of particles as fractals is especially unique and the Second Edition includes a new section on exoelectrogenic biofilms. It also addresses dispersion in natural and engineered systems unlike any other book on the subject. Readers will learn to tackle with confidence complex environmental systems and make transport calculations in heterogeneous environments with mixtures of chemicals.




The Mermaid’s Tale


Book Description

While competitive natural selection is widely assumed to be evolution’s prime mover, Weiss shows how life generally works on the basis of cooperation. He reveals that focus on competition and cooperation is largely an artifact of compression of time—a distortion that dissolves when life is viewed from developmental and evolutionary time scales.




Turbomachinery Fluid Dynamics and Heat Transfer


Book Description

This festschrift in honor of Professor Budugur Lakshminarayana's 60th birthday-based on the proceedings of a symposium on Turbomachinery Fluid Dynamics and Heat Transfer held recently at The Pennsylvania State University, University Park-provides authoritative and conclusive research results as well as new insights into complex flow features found in the turbomachinery used for propulsion, power, and industrial applications. Explaining in detail compressors, heat transfer fields in turbines, computational fluid dynamics, and unsteady flows, Turbomachinery Fluid Dynamics and Heat Transfer covers: Mixing mechanisms, annulus wall boundary layers, and the flow field in transonic turbocompressors The numerical implementation of turbulence models in a computer code Secondary flows, film cooling, and thermal turbulence modeling The visualization method of modeling using liquid crystals Innovative techniques in the computational modeling of compressor and turbine flows measurement in unsteady flows as well as axial flows and compressor noise generation And much more Generously illustrated and containing key bibliographic citations, Turbomachinery Fluid Dynamics and Heat Transfer is an indispensable resource for mechanical, design, aerospace, marine, manufacturing, materials, industrial, and reliability engineers; and upper-level undergraduate and graduate students in these disciplines.




Fostering Integrity in Research


Book Description

The integrity of knowledge that emerges from research is based on individual and collective adherence to core values of objectivity, honesty, openness, fairness, accountability, and stewardship. Integrity in science means that the organizations in which research is conducted encourage those involved to exemplify these values in every step of the research process. Understanding the dynamics that support â€" or distort â€" practices that uphold the integrity of research by all participants ensures that the research enterprise advances knowledge. The 1992 report Responsible Science: Ensuring the Integrity of the Research Process evaluated issues related to scientific responsibility and the conduct of research. It provided a valuable service in describing and analyzing a very complicated set of issues, and has served as a crucial basis for thinking about research integrity for more than two decades. However, as experience has accumulated with various forms of research misconduct, detrimental research practices, and other forms of misconduct, as subsequent empirical research has revealed more about the nature of scientific misconduct, and because technological and social changes have altered the environment in which science is conducted, it is clear that the framework established more than two decades ago needs to be updated. Responsible Science served as a valuable benchmark to set the context for this most recent analysis and to help guide the committee's thought process. Fostering Integrity in Research identifies best practices in research and recommends practical options for discouraging and addressing research misconduct and detrimental research practices.