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Although its contributions to global science date from 1980, Qatar embarked on an ambitious plan in 2009 to position itself as an important hub for global research production. This paper assesses Qatar’s contribution over the past three decades to global research output and science productivity in STEM+ fields, as measured by scientific journal article production.

The core of the analysis is based on a specially coded dataset of all peer-reviewed journal articles in the STEM+ disciplines with at least one author whose primary affiliation was a Qatar-based research organization. The original data source is Thomson Reuters’ Science Citation Index Expanded (SCIE). Analyzing trends between 1980 (the first year in which a paper with a Qatar-based author appeared in these selected leading journals) and 2011, the chapter documents how scientific journal article production in Qatar has developed over three decades.

Between 1980 and 2002, rates of journal article production were relatively low. From 2003, reflecting considerable investments in higher education and research, the annual number of journal article publications increased dramatically. Most publications were authored by university-based scientists (58%) and scientists based at research hospitals or other medical research facilities (30%). By 2011, over 83% of scientific journal articles published with at least one Qatar-based author were the result of collaboration with international partners. European, North American, and Middle Eastern research scientists and organizations were the most common international collaborators.

This is the first comprehensive empirical study of Qatar’s contributions to global scientific production in the STEM+ disciplines.

A national multi‐gigabit‐per‐second research and education network known as the National Research and Education Network is to be established by 1996, according to the High‐Performance Computing Act of 1991 (P.L. 102–194) passed in December 1991. Commonly known as the NREN and referred to as the “information highway,” this electronic network is expected to provide scientific, educational, and economic benefits for the United States and to serve as the basis for an all‐encompassing National Information Infrastructure available to all citizens. The idea of the NREN began in the late 1960s in the Department of Defense and its Defense Advanced Research Projects Agency (DARPA) with the development of ARPANet, the first packet‐switching network. This evolved into the Internet, or Interim NREN, after the National Science Foundation (NSF) linked its national supercomputing centers with the NSFNet. The NSFNet is to be the technological backbone for the NREN, which will continue the networking begun by the Internet. Initially, the NREN is intended to interconnect researchers and resources of research institutions, educational institutions, industry, and government in every state.

The overall goal of science is to build a valid and reliable body of knowledge about the functioning of the world and how applying that knowledge can change it. As personnel and human resources management researchers, we aim to contribute to the respective bodies of knowledge to provide both employers and employees with a workable foundation to help with those problems they are confronted with. However, what research on research has consistently demonstrated is that the scientific endeavor possesses existential issues including a substantial lack of (a) solid theory, (b) replicability, (c) reproducibility, (d) proper and generalizable samples, (e) sufficient quality control (i.e., peer review), (f) robust and trustworthy statistical results, (g) availability of research, and (h) sufficient practical implications. In this chapter, we first sing a song of sorrow regarding the current state of the social sciences in general and personnel and human resources management specifically. Then, we investigate potential grievances that might have led to it (i.e., questionable research practices, misplaced incentives), only to end with a verse of hope by outlining an avenue for betterment (i.e., open science and policy changes at multiple levels).

Strengthening the nation’s technological workforce, competing and expanding its relevance in the global economy, and maintaining personal as well as homeland security will be highly dependent on the quantity, quality, and diversity of the next generations of scientists, engineers, technologists, and mathematicians. Production of a diverse generation of human resources with relevant, competitive skills is critical. However, so too is the need to raise an enlightened citizenry with cross-cultural experience and cultural awareness competency, with a broad worldview and global perspectives. These requirements are critical to understanding the challenges and opportunities of scholarly activity in a pluralistic global environment and positioning ourselves to capitalize upon them. Scholars with cross-cultural experience and competency are empowered to adapt and work collaboratively, nationally and globally, with scholars of different races, geopolitical, socioeconomic, and cultural backgrounds. Development of effective strategies to transform science, technology, engineering, and mathematics (STEM) departments for inclusion and to broaden the participation in STEM across cultures, socioeconomic standing, race, and gender in higher education has been a dominant topic of pedagogical interest of national priority in the last several decades. However, success in these endeavors is achievable only through systemic change and a cultural shift to address the underlying root causes of socioeconomic disparity, gender, and racial disparities and a paucity of cultural awareness among all educational stakeholders. STEM departments can only be truly transformed for inclusion through the development of sensitive, creative, and student-engaging curricula and targeted recruitment and retention of underrepresented minorities in STEM. Formation of well-coordinated alliances spanning educational sectors, governmental and non-governmental organizations, and community engagement and outreach are also critical to promoting inclusive and broad participation in STEM education.

The first section of the chapter gives an introduction to various challenges, obstacles, and hindrances that prevent a successful transformation of K–12 science education as well as STEM departments in higher education for inclusion. The second section discusses historical perspectives of the University of Arkansas-Fort Smith (UAFS) – the institutional profile, missions, and visions of UAFS as a regional university. Policies and strategies for addressing the socioeconomic disparity, faculty gender, and racial disparities and cultural competency awareness at UAFS are also highlighted in this section. Other approaches including targeted efforts to recruit and retain underrepresented minority students, provision of financial assistance for students from low-income families, and a creative “Math-up” curriculum innovation to promote inclusive and broad participation in STEM at UAFS are highlighted in the latter section of the chapter. Formation of alliances between UAFS, local K–12 school districts, and governmental and non-governmental agencies to promote broad participation in STEM at UAFS are discussed. The last section of the chapter provides recommendations for adaptation and sustainability of strategies and efforts aimed at transforming national STEM departments for inclusion.

Since at least the 1970s, the American research university system has experienced episodic periods of austerity, frequently accompanied by expressions of concern about the threats that these conditions pose to U.S. scientific and technological leadership. In general, austerity has been tied to fluctuations in Federal Government funding of academic research and macroeconomic fluctuations that have shrunk state government budget revenues. Even amidst these episodes, the system has continued to expand and decentralize. The issue at present is whether this historic resiliency, of being a marvelous invalid, will overcome adverse contemporary trends in Federal and state government funding, as well as political trends that eat away at the societal bonds between universities and their broader publics. The paper juxtaposes examinations of the organizational and political influences that have given rise to the American research university system, trends in research revenues and research costs, and contemporary efforts by universities to balance the two. It singles out the secular decline in state government’s support of public universities as the principal reason why this period of contraction is different from those of the past. Rather though then these trends portending a market shakeout, as some at times have predicted, the projection here is that the academic research system will continue to be characterized by excess capacity and recurrent downward pressures on research costs. Because the adverse impacts are concentrated in the public university sector, they may also spill over into political threats to the current system of awarding academic research grants primarily via competitive, merit review arrangements.

Xavier University of Louisiana has a national reputation for producing science, technology, engineering, and mathematics (STEM) graduates who go on to obtain MD and PhD degrees. According to a 2013 National Science Foundation report, Xavier is ranked first in producing African American graduates who go on to receive life sciences PhD degrees, fifth in the nation in producing African American graduates who go on to receive science and engineering PhD degrees, and seventh in producing African American graduates who go on to receive physical sciences PhD degrees. Xavier is currently third among the nation’s colleges and universities in the number of African American graduates enrolled in medical school, according to data compiled by the Association of American Medical Colleges, and ranked first in the number of African American alumni who successfully complete their medical degrees. The success of Xavier’s graduates is due to a combination of university-based student support initiatives and externally funded programs, in particular, the Building Infrastructure Leading to Diversity (BUILD), Maximizing Access to Biomedical Research Careers (MARC) U*STAR, and Research Initiative in Scientific Enhancement (RISE) programs. These three programs, funded by the Training, Workforce Development, and Diversity (TWD) Division at the National Institutes of Health (NIH), offer select trainees undergraduate research opportunities, support mechanisms, and a variety of activities designed to improve their potential for success in graduate school. The BUILD, MARC U*STAR, and RISE programs work closely together and with the University to leverage the resources provided by each in order to provide the best experience possible for their students with a minimum of redundancy of effort. This chapter focuses on the program components and how the programs work together.

In this chapter, we present our ongoing efforts in developing and sustaining interdisciplinary STEM undergraduate programs at North Carolina A&T State University (NCA&T) – a state-supported HBCU and National Science Foundation (NSF) Historically Black Colleges and Universities Undergraduate Program (HBCU-UP) Institutional Implementation Project grantee. Through three rounds of NSF HBCU-UP implementation grants, a concerted effort has been made in developing interdisciplinary STEM undergraduate research programs in geophysical and environmental science (in round 1), geospatial, computational, and information science (in round 2), and mathematical and computational biology (in round 3) on NCA&T campus. We first present a brief history and background information about the interdisciplinary STEM undergraduate research programs developed and sustained at NCA&T, giving rationales on how these programs had been conceived, and summarizing what have been achieved. Next we give a detailed description on the development of undergraduate research infrastructure including building research facilities through multiple and leveraged funding sources, and engaging a core of committed faculty mentors and research collaborators. We then present, as case studies, some sample interdisciplinary research projects in which STEM undergraduate students were engaged and project outcomes. Successes associated to our endeavor in developing undergraduate research programs as well as challenges and opportunities on implementing and sustaining these efforts are discussed. Finally, we discuss the impact of well-structured undergraduate research training on student success in terms of academic performance, graduation rate and continuing graduate study, and summarize many of the learnings we have gained from implementation and delivery of undergraduate research experiences at HBCUs.

Morgan State University (Morgan) is a leading undergraduate institution for black science and engineering doctoral degree recipients. Morgan also is a leader in the production of black engineering degree recipients in the United States. This chapter provides a historic overview of the major programs with a tie to the impact on the institutional metrics, a discussion of the process for developing researchers in science and engineering, and alumni perspectives. The undergraduate research development models used in engineering at Morgan are compared and contrasted with the life sciences and physical sciences. The programs focus on developing communities of engineering practice and communities of science, thereby enhancing students’ self-efficacy and resilience, shaping disciplinary identity, and creating learning communities. These approaches are critical for the success of minority students and are supported by the social science literature. Best practices have been adopted at varying levels by the School of Engineering, the School of Computer Mathematics and Natural Science and the Behavioral Science departments that have netted these Ph.D. outcomes including multiyear mentored research, research training courses, and participation in professional meetings. Multiple approaches to student development, when matched with the disciplinary culture, are shown to result in national impact.

The “collaboratory” concept has recently entered the vernacular of the scientific community to reflect new modes of scientific communication, cooperation and collaboration made possible by information technology. The collaboratory represents a scientific research center “without walls” for accessing and sharing data, information, instrumentation and computational resources. The principal applications of the collaboratory concept have been in the physical and biological sciences, including space physics, oceanography and molecular biology. Discusses the attributes of the collaboratory, and applies the concept developed by computer and physical scientists to the design and operation of the SIPPACCESS prototype information system for complex data to be used through the Internet by sociologists, demographers and economists. Examines obstacles to collaboratory development for the social sciences. Concludes that four major obstacles will inhibit the development of collaboratories in the social sciences.