Science & Technology

Summary

The United States has a long and storied history of scientific and technological innovation, serving as a global leader in many fields. This leadership is driven by factors such as:

  • Strong research institutions: The nation boasts world-class universities, research laboratories, and national scientific foundations that foster groundbreaking research.
  • Government support: Federal agencies like the National Science Foundation (NSF) and the National Institutes of Health (NIH) provide significant funding for scientific research and development.
  • A culture of innovation: The United States has a culture that encourages risk-taking, entrepreneurship, and the pursuit of new ideas.
  • Collaboration: The U.S. has a strong tradition of collaboration between academia, industry, and government, leading to efficient knowledge transfer and commercialization of research.

There are many issues related to Science & Technology that Congress is looking to address with legislation. In the ‘About’ section of this post is an overview of the issues and potential solutions, party positions, and web links. Other sections have information on relevant committees, chairs, & caucuses; departments & agencies; and the judiciary, nonpartisan & partisan organizations, and a wikipedia entry.

To participate in ongoing forums, ask the post’s curators questions, and make suggestions, scroll to the ‘Discuss’ section at the bottom of each post or select the “comment” icon.

The Science & Technology category has related posts and three posts on issues of particular focus: NanotechnologyArtificial General Intelligence (AGI), Space Exploration.

OnAir Post: Science & Technology

News

Protein design and structure prediction wins chemistry Nobel prize
Chemistry World, Jamie DurraniOctober 9, 2024

The developers of computational tools that can be used to accurately design and predict protein structures have been recognised with this year’s Nobel prize in chemistry. The Nobel committee noted that these tools have led to a revolution in biological chemistry and are today used by millions of researchers around the world.

Demis Hassabis and John Jumper from Google’s DeepMind team received one half of the prize for their work on AlphaFold and AlphaFold2 – programs that dramatically increased the accuracy of protein structure predictions. In 2021, the team released 350,000 structures including those of all 20,000 proteins in the human proteome. In 2022 they provided the structures of a further 200 million proteins – almost every protein known to science.

From games to science breakthrough – the story of AlphaFold
WARP News, Mathias SundinOctober 9, 2024

The history of computers competing against humans is long, and often attracts enormous attention. But what is it good for? What does it matter if a computer can win in chess, Go, or Starcraft? We got the answer when AlphaFold solved a 50-year old grand challenge in biology.

 

The Nobel Prize in chemistry went to three scientists for groundbreaking work using artificial intelligence to advance biomedical and protein research. AlphaFold uses databases of protein structures and sequences to predict and even design protein structures. It speeds up a months or years-long process to mere hours or minutes. Amna Nawaz discussed more with one of the winners, Demis Hassabis.

The 2024 Nobel Prizes in physics and chemistry have given us a glimpse of the future of science. Artificial intelligence (AI) was central to the discoveries honoured by both awards. You have to wonder what Alfred Nobel, who founded the prizes, would think of it all.

We are certain to see many more Nobel medals handed to researchers who made use of AI tools. As this happens, we may find the scientific methods honoured by the Nobel committee depart from straightforward categories like “physics”, “chemistry” and “physiology or medicine”.

We may also see the scientific backgrounds of recipients retain a looser connection with these categories. This year’s physics prize was awarded to the American John Hopfield, at Princeton University, and British-born Geoffrey Hinton, from the University of Toronto. While Hopfield is a physicist, Hinton studied experimental psychology before gravitating to AI.

The Nobel Prize winning ‘Godfather of AI’ speaks to Newsnight about the potential for AI “exceeding human intelligence” and it “trying to take over.” Geoffrey Hinton, former Vice President of Google and sometimes referred to as the ‘Godfather of AI’, has recently won the 2024 Nobel Physics Prize. He resigned from Google in 2023, and has warned about the dangers of machines that could outsmart humans. In May 2024, Faisal Islam spoke to the professor for Newsnight.

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Science and Innovation in the 118th Congress
Federation of American Scientists, Federation of American Scientists January 12, 2023

To be sure, narrowly split control of Congress adds to the complexity of addressing these challenges. But even in this situation, the 118th Congress can still create opportunities for bipartisan action to bolster American economic security, national security, and health. There are many national goals on which the parties agree. These include:

  • Stronger American science and innovation
  • Reliable, cleaner domestic energy
  • An American society that’s safe from threat of pandemics
  • Resilient, productive American agriculture

Even if there are some areas in which policy differences persist, there are many where action is possible.

To help seed the ground for bipartisan progress, we have assembled a wide-ranging menu of policy ideas on a range of critical topics.

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Science and Technology Issues for the 118th Congress
Congressional Research Service, PDFFebruary 29, 2024

Science and Technology Issues for the 118th Congress The federal government supports scientific and technological advancement directly by funding and performing research and development and indirectly by creating and maintaining policies that encourage private sector efforts. Additionally, the federal government regulates many aspects of science and technology (S&T) activities. Federal S&T support has led to scientific breakthroughs and new technologies ranging from jet aircraft and the internet to communications satellites and defenses against disease.

Many science and technology policy issues that may come before the 118th Congress represent areas of continuing Member interest. Examples include cross-cutting issues that affect scientific and technological progress, agricultural research, climate change, Defense Department research, earth science, space, and water. Other issues represent new or rapidly transforming areas such as biotechnology, energy, information technology and social media, financial technology, and telecommunications. See PDF for details.

 

 

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An Artificial General Intelligence (AGI) is a hypothetical type of intelligent agent which, if realized, could learn to accomplish any intellectual task that human beings or animals can perform. Alternatively, AGI has been defined as an autonomous system that surpasses human capabilities in the majority of economically valuable tasks. Creating AGI is a primary goal of some artificial intelligence research and of companies such as OpenAI, DeepMind, and Anthropic. AGI is a common topic in science fiction and futures studies.

  • In the ‘About’ section of this post is an overview of the issues or challenges, potential solutions, and web links. Other sections have information on relevant legislation, committees, agencies, programs in addition to information on the judiciary, nonpartisan & partisan organizations, and a wikipedia entry.
  • To participate in ongoing forums, ask the post’s curators questions, and make suggestions, scroll to the ‘Discuss’ section at the bottom of each post or select the “comment” icon.

The Regulating AGI category has related posts on government agencies and departments and  committees and their Chairs.

OnAir Post: Regulating AGI (US)

A long legal battle ended Thursday when a jury found that two conservative writers defamed the prominent climate scientist Michael Mann. William Brangham looks at what this verdict means and speaks with another renowned scientist who’s also endured this kind of vitriol, Dr. Peter Hotez.

Preliminary Terms with GlobalFoundries
NISTFebruary 19, 2024

Today, the Biden-Harris Administration announced that the U.S. Department of Commerce and GlobalFoundries (GF) have signed a non-binding preliminary memorandum of terms (PMT) to provide approximately $1.5 billion in direct funding under the CHIPS and Science Act to strengthen U.S. domestic supply chain resilience, bolster U.S. competitiveness in current-generation and mature-node (C&M) semiconductor production, and support economic and national security capabilities. The proposed funding would support a new state-of-the-art facility, significant capacity expansion, and the modernization of GF’s U.S. manufacturing sites in New York and Vermont, which produce essential automotive, communications, and defense semiconductor technologies.

President Biden signed the bipartisan CHIPS and Science Act to strengthen U.S. supply chains, create good-paying jobs, and advance U.S. economic and national security. Today’s announcement is the third PMT announcement the Department of Commerce has made under the CHIPS and Science Act.

GF chips are fundamental to everyday applications that impact all Americans, from blind spot detection and collision warnings in cars, to smartphones and electric vehicles that last longer between charges, to secure and reliable Wi-Fi and cellular connections. Currently, there are only four companies outside of China that provide current and mature foundry capabilities at the scale of GF – and GF is the only one of those companies that is headquartered in the United States. Shortages of some of these semiconductors caused major disruptions during the COVID-19 pandemic, resulting in a particularly acute impact on the availability and price of a broad range of goods for Americans, as well as the shutdown of automobile manufacturing sites. Part of the proposed funding is expected to support expanding the facility that houses a dedicated capacity corridor for General Motors, with whom GF entered into a strategic long-term supply agreement last year.

“Semiconductors are the brain of modern technology. While they are no larger than a fingernail and no thicker than a piece of paper, they are essential to every electronic device that we currently use – from computers and televisions to cars and washing machines. Thanks to our Administration’s CHIPS and Science Act, we are announcing the Department of Commerce’s preliminary agreement with GlobalFoundries, which will award approximately $1.5 billion to expand domestic production of semiconductors, strengthen U.S. supply chains, and create thousands of good paying jobs right here in America,” said Vice President Kamala Harris. “President Biden and I continue to be fully committed to growing our economy and creating opportunity in every part of America. Today’s announcement is another way in which we are delivering on that commitment in New York, Vermont, and communities throughout the country.”

“Semiconductors are in everything from our cellphones, to refrigerators, to cars, and our most advanced weapons systems, and access to them carries important economic and national security implications. It was the shortages of semiconductors during the COVID-19 pandemic that raised prices for consumers and led to the shutdown of automobile manufacturing sites across the country,” said Secretary of Commerce Gina Raimondo. “Thanks to President Biden’s CHIPS and Science Act, we’re working to onshore these critical technologies in order to bolster the supply of domestic chips that are essential to manufacturing cars, electronics, and national defense systems in New York, Vermont, and states across the country.”

“The CHIPS and Science Act set out to make the United States a leader in semiconductor R&D and manufacturing, and with this proposed CHIPS funding, GlobalFoundries could help realize this vision by modernizing and building new chip fabrication facilities to increase its capacity to make current-generation and mature-node chips in the United States while creating thousands of good jobs in New York and Vermont,” said Under Secretary of Commerce for Standards and Technology and NIST Director Laurie E. Locascio. “By investing in domestic manufacturing capabilities, CHIPS for America is helping secure a stable domestic supply of chips that are found in everything from home electronics to advanced aerospace systems.”

“GF is proud to announce this proposed funding from the Department of Commerce and appreciates the collaboration of the CHIPS Office throughout this process. These proposed investments, along with the investment tax credit (ITC) for semiconductor manufacturing, are central to the next chapter of the GlobalFoundries story and our industry. They would also play an important role in making the U.S. semiconductor ecosystem more globally competitive and resilient,” said Dr. Thomas Caulfield, president and CEO of GF. “With new onshore capacity and technology on the horizon, as an industry we now need to turn our attention to increasing the demand for U.S.-made chips, and to growing our talented U.S. semiconductor workforce.”

The proposed expansion of GF is expected to help advance U.S. economic and national security by increasing capacity, strengthening supply chain resilience, and onshoring technologies in the U.S. for the first time that are important to our defense and intelligence communities. With multiple facilities that are designated as Trusted Foundries by the Department of Defense, GF has a long history of supporting the U.S. military and this proposed funding is expected to strengthen those ties. The Department of Defense relies on GF chips for national defense uses including satellite and space communications. GF chips also support broader U.S. technological leadership and discovery, such as the James Webb Telescope and the International Space Station.

The approximately $1.5 billion in proposed CHIPS funding would be split across three projects:

  • Malta, New York – New State-of-the-Art 300 mm Fab: The construction of a new, large-scale 300 mm fabrication facility that is expected to produce high value technologies not currently available in the U.S. The new facility is intended to leverage existing infrastructure to expedite the path from construction to production.
  • Malta, New York – Capacity Expansion for Automotive: The proposed expansion of the existing Malta, New York fabrication facility, which includes a strategic agreement with General Motors, to secure a dedicated supply of essential semiconductor technologies. This project would also support America’s economic and national security by expanding domestic capacity for semiconductors that are used in the U.S. critical infrastructure base. This expansion, combined with the new 300 mm fabrication facility, is expected to triple the existing capacity of the Malta campus over the next 10+ years. These two projects are expected to increase wafer production to 1 million per year once all phases are complete.
  • Burlington, Vermont – Fab Revitalization: The revitalization of an existing fabrication facility in Burlington, Vermont, to commercialize new 200 mm technologies, creating the first U.S. facility capable of high-volume manufacturing of next-generation Gallium Nitride on Silicon for use in electric vehicles, power grid, 5G and 6G smartphones, and other critical technologies. The site will apply industry-leading sustainability practices, including the use of 100% carbon-neutral energy and the development of an onsite solar system to supply up to 9% of the site’s annual energy.

The proposed projects would create approximately 1,500 manufacturing jobs and approximately 9,000 construction jobs over the next 10 years. The PMT also proposes approximately $10 million in dedicated workforce development funding for GF to work with local workforce, education, training, and community-based organizations to provide GF with the facilities and construction talent they need now and in the future. GF also continues to build upon its GF Maintenance Technician Apprenticeship Program, which is the first U.S. registered semiconductor apprenticeship program and graduated its first apprentices in 2022. In recognizing the critical importance of child care for its operations, the company will not only continue to provide its $1,000 annual subsidy and child care support concierge service to its growing facility workforce but also extend these benefits to its construction workers. The company will be operating under an existing Project Labor Agreement (PLA) in New York and is in the process of establishing a PLA in Vermont for the purposes of this project.

In addition to potential direct funding, the CHIPS Program Office would make approximately $1.6 billion in loans available to GF under the PMT. The total potential public and private investment for the combined projects would be approximately $12.5 billion.

As explained in the Department’s first Notice of Funding Opportunity, the Department may offer applicants a PMT on a non-binding basis after satisfactory completion of the merit review of a full application. The PMT outlines key terms for a CHIPS incentives award, including the amount and form of the award. After the PMT is signed, the Department begins a comprehensive due diligence process on the proposed project and other information contained in the application. After satisfactory completion of the due diligence phase, the Department may enter into final award documents with the applicant. Terms of the final award documents are subject to negotiations with the applicant and may differ from the terms of the PMT.

About CHIPS for America 

The Department has received more than 600 statements of interest, more than 160 pre-applications and full applications for NOFO 1, and more than 160 small supplier concept plans for NOFO 2. The Department is continuing to conduct rigorous evaluation of applications to determine which projects will advance U.S. national and economic security, attract more private capital, and deliver other economic benefits to the country. The announcement with GlobalFoundries is the third PMT announcement the Department of Commerce has made under the CHIPS and Science Act, with additional PMT announcements expected to follow throughout 2024.

CHIPS for America is part of President Biden’s economic plan to invest in America, stimulate private sector investment, create good-paying jobs, make more in the United States, and revitalize communities left behind. CHIPS for America includes the CHIPS Program Office, responsible for manufacturing incentives, and the CHIPS Research and Development Office, responsible for R&D programs, that both sit within the National Institute of Standards and Technology (NIST) at the Department of Commerce. NIST promotes U.S. innovation and industrial competitiveness by advancing measurement science, standards, and technology in ways that enhance economic security and improve our quality of life. NIST is uniquely positioned to successfully administer the CHIPS for America program because of the bureau’s strong relationships with U.S. industries, its deep understanding of the semiconductor ecosystem, and its reputation as fair and trusted. Visit https://www.chips.gov to learn more.

About

Issues & Potential Legislative Solutions

The United States Constitution itself reflects the desire to encourage scientific creativity. It gives the United States Congress the power “to promote the progress of science and useful arts, by securing for limited times to authors and inventors the exclusive right to their respective writings and discoveries.”  This clause formed the basis for the U.S. patent and copyright systems, whereby creators of original art and technology would get a government granted monopoly, which after a limited period would become free to all citizens, thereby enriching the public domain. Wikipedia Entry on Science and technology in the US

Artificial Intelligence (AI)

  • Ethical and responsible development and use
  • Algorithmic bias and fairness
  • AI safety and control
  • Impact on employment and the economy

Biotechnology and Health

  • Gene editing and gene therapy
  • Precision medicine and personalized treatments
  • Drug discovery and development
  • Biosecurity and infectious disease threats

Quantum Computing

  • Development of quantum computers and algorithms
  • Security and encryption implications
  • Applications in materials science, medicine, and finance

Space Exploration

  • Human missions to Mars and beyond
  • Space telescopes and exoplanet research
  • Space resource utilization
  • Space debris and sustainability

Materials Science

  • Advanced materials for energy, electronics, and healthcare
  • Nanomaterials and composites
  • Sustainable and biodegradable materials
  • 3D printing and additive manufacturing

Cybersecurity and Data Privacy

  • Protection against cyber attacks and data breaches
  • Data encryption and privacy preservation
  • Ethical considerations and government regulation

Energy Security and Power Systems

  • Decarbonization of the power grid
  • Smart grids and microgrids
  • Energy storage and transmission
  • Cybersecurity and resilience of energy infrastructure

Food and Agriculture

  • Sustainable and resilient food production
  • Precision agriculture and data analytics
  • Genetically modified crops and food safety
  • Climate-resilient crops and livestock

Transportation and Infrastructure

  • Electric and autonomous vehicles
  • Smart cities and urban planning
  • Sustainable transportation systems
  • Infrastructure resilience and maintenance

Climate Change and Sustainability

  • Emissions reduction and climate adaptation
  • Renewable energy and energy efficiency
  • Carbon capture and storage
  • Sustainable development and biodiversity conservation

 

Source: Google Search + Gemini & Some onAir curation

Party Positions

Republican Party platform: In 2020, the Republican Party decided not to write a platform for that presidential election cycle, instead simply expressing its support for Donald Trump’s agenda.

Democratic Party platform:

Democratic Party

  • Investments in research and development: Supports increased funding for basic and applied scientific research and technological innovation.
  • Climate change mitigation: Recognizes the urgency of addressing climate change and supports policies to reduce carbon emissions, promote renewable energy, and invest in climate adaptation measures.
  • Healthcare innovation: Prioritizes access to affordable healthcare and supports efforts to develop new medical technologies and treatments.
  • Cybersecurity: Emphasizes the importance of protecting national security and critical infrastructure from cyber threats.
  • Artificial intelligence regulation: Supports the responsible development and use of AI, with a focus on addressing potential risks and biases.

Republican Party

  • Reduced government regulation: Supports minimizing government intervention in the private sector, including in areas of science and technology.
  • Energy independence: Prioritizes domestic energy production and emphasizes the role of fossil fuels in the energy mix.
  • Healthcare deregulation: Favors reducing government involvement in the healthcare system, supporting the free market as a driver of innovation.
  • Cybersecurity defense: Supports strengthening national security through cybersecurity measures, focusing on threat detection and response.
  • AI competitiveness: Emphasizes U.S. leadership in AI and supports policies to promote innovation and economic growth in this area.

Key Differences

  • Role of government: Democrats generally support a more active government role in supporting scientific research and regulating technology, while Republicans favor a smaller role.
  • Climate change: Democrats prioritize addressing climate change, while Republicans have varied views on its severity and appropriate mitigation strategies.
  • Healthcare: Democrats prioritize expanding access to affordable healthcare and supporting medical innovation, while Republicans favor market-based approaches.
  • Regulation: Democrats support more stringent regulation of emerging technologies like AI, while Republicans favor a lighter regulatory touch.
  • International cooperation: Democrats generally support international collaboration in science and technology, while Republicans may be more hesitant.

Source: Google Search + Gemini + onAir Curators

Key Websites

General Science and Technology News

Artificial Intelligence and Machine Learning

Biotechnology and Healthcare

Climate Change

Energy

Environmental Science

Information Technology

Space Exploration

Source: Google Search + Gemini + onAir Curators

Departments & Agencies

Department of Energy (DOE)

Source: onAir post

The United States Department of Energy (DOE) is a cabinet-level department of the United States government concerned with the United States’ policies regarding energy and safety in handling nuclear material. Its responsibilities include the nation’s nuclear weapons program, nuclear reactor production for the United States Navy, energy conservation, energy-related research, radioactive waste disposal, and domestic energy production. It also directs research in genomics; the Human Genome Project originated in a DOE initiative. DOE sponsors more research in the physical sciences than any other U.S. federal agency, the majority of which is conducted through its system of National Laboratories.

The agency is led by the United States Secretary of Energy, and its headquarters are located in Southwest Washington, D.C., on Independence Avenue in the James V. Forrestal Building, named for James Forrestal, as well as in Germantown, Maryland.

Wikipedia Entry    Website:energy.gov/

Department of Commerce (DOC)

Source: onAir post

The United States Department of Commerce is an executive department of the U.S. federal government concerned with promoting economic growth.[clarification needed] Among its tasks are gathering economic and demographic data for business and government decision making, and helping to set industrial standards.

This organization’s main purpose is to create jobs, promote economic growth, encourage sustainable development and block harmful trade practices of other nations. The Department of Commerce is headquartered in the Herbert C. Hoover Building in Washington, DC.

Wikipedia Entry   Websitecommerce.gov

National Aeronautics and Space Administration (NASA)

The National Aeronautics and Space Administration  is an independent agency of the U.S. federal government responsible for the civil space program, aeronautics research, and space research. Established in 1958, it succeeded the National Advisory Committee for Aeronautics (NACA) to give the U.S. space development effort a distinctly civilian orientation, emphasizing peaceful applications in space science. It has since led most American space exploration, including Project Mercury, Project Gemini, the 1968–1972 Apollo Moon landing missions, the Skylab space station, and the Space Shuttle. It currently supports the International Space Station and oversees the development of the Orion spacecraft and the Space Launch System for the crewed lunar Artemis program, the Commercial Crew spacecraft, and the planned Lunar Gateway space station.

NASA’s science is focused on better understanding Earth through the Earth Observing System;advancing heliophysics through the efforts of the Science Mission Directorate’s Heliophysics Research Program;exploring bodies throughout the Solar System with advanced robotic spacecraft such as New Horizons and planetary rovers such as Perseverance; and researching astrophysics topics, such as the Big Bang, through the James Webb Space Telescope, the Great Observatories and associated programs. The Launch Services Program oversees launch operations and countdown management for its uncrewed launches.

Wikipedia Entry Website: nasa.gov.

National Science Foundation (NSF)

The National Science Foundation (NSF) is an independent agency of the United States federal government that supports fundamental research and education in all the non-medical fields of science and engineering. Its medical counterpart is the National Institutes of Health. With an annual budget of about $8.3 billion (fiscal year 2020), the NSF funds approximately 25% of all federally supported basic research conducted by the United States’ colleges and universities. In some fields, such as mathematics, computer science, economics, and the social sciences, the NSF is the major source of federal backing.

NSF’s director and deputy director are appointed by the president of the United States and confirmed by the United States Senate, whereas the 24 president-appointed members of the National Science Board (NSB)[5] do not require U.S. Senate confirmation. The director and deputy director are responsible for administration, planning, budgeting and day-to-day operations of the foundation, while the NSB meets six times a year to establish its overall policies. The current NSF director is Sethuraman Panchanathan.

Source: Wikipedia Entry      Website: nsf.gov.

National Institutes of Health (NIH)

The National Institutes of Health, commonly referred to as NIH, is the primary agency of the United States government responsible for biomedical and public health research. It was founded in the late 1880s and is now part of the United States Department of Health and Human Services. Many NIH facilities are located in Bethesda, Maryland, and other nearby suburbs of the Washington metropolitan area, with other primary facilities in the Research Triangle Park in North Carolina and smaller satellite facilities located around the United States. The NIH conducts its own scientific research through the NIH Intramural Research Program (IRP) and provides major biomedical research funding to non-NIH research facilities through its Extramural Research Program.

As of 2013, the IRP had 1,200 principal investigators and more than 4,000 postdoctoral fellows in basic, translational, and clinical research, being the largest biomedical research institution in the world, while, as of 2003, the extramural arm provided 28% of biomedical research funding spent annually in the U.S., or about US$26.4 billion.

The NIH comprises 27 separate institutes and centers of different biomedical disciplines and is responsible for many scientific accomplishments, including the discovery of fluoride to prevent tooth decay, the use of lithium to manage bipolar disorder, and the creation of vaccines against hepatitis, Haemophilus influenzae (HIB), and human papillomavirus (HPV).

In 2019, the NIH was ranked number two in the world, behind Harvard University, for biomedical sciences in the Nature Index, which measured the largest contributors to papers published in a subset of leading journals from 2015 to 2018.

Source: Wikipedia Entry      Website: nih.gov.

Committees & Caucuses

Senate Committee on Commerce, Science, and Transportation

Source: onAir post

Mission 
Has broad jurisdiction over all matters concerning interstate commerce, science and technology policy, and transportation, the Senate Commerce Committee is one of the largest of the Senate’s standing committees, with 26 members in the 117th Congress.

Wikipedia Entry   Website: commerce.senate.gov/members

House counterparts: Energy and Commerce Committee; Science, Space, and Technology Committee; and Transportation and Infrastructure Committee

Democratic Members (Majority):
Maria Cantwell, Washington, Chair
Amy Klobuchar, Minnesota
Richard Blumenthal, Connecticut
Brian Schatz, Hawaii
Ed Markey, Massachusetts
Gary Peters, Michigan
Tammy Baldwin, Wisconsin
Tammy Duckworth, Illinois
Jon Tester, Montana
Kyrsten Sinema, Arizona
Jacky Rosen, Nevada
Ben Ray Luján, New Mexico
John Hickenlooper, Colorado
Raphael Warnock, Georgia
Peter Welch, Vermont

Republican Members (Minority):
Ted Cruz, Texas, Ranking Member
John Thune, South Dakota
Roger Wicker, Mississippi
Deb Fischer, Nebraska
Jerry Moran, Kansas
Dan Sullivan, Alaska
Marsha Blackburn, Tennessee
Todd Young, Indiana
Ted Budd, North Carolina
Eric Schmitt, Missouri
J. D. Vance, Ohio
Shelley Moore Capito, West Virginia
Cynthia Lummis, Wyoming

House Science, Space, and Technology Committee

Mission:
To oversee all non-defense federal scientific research and development. More specifically, the committee has complete jurisdiction over the following federal agencies: NASA, NSF, NIST, and the OSTP. The Committee also has authority over R&D activities at the Department of Energy, the EPA, FAA, NOAA, the DOT, the NWS, the DHS and the U.S. Fire Administration.

Senate Counterpart: Committee on Commerce, Science, and Transportation

Subcommittees:

  • Energy
  • Environment
  • Investigations and Oversight
  • Research and Technology
  • Space and Aeronautics

Chair: Frank Lucas, Oklahoma (R)
Ranking Member: Zoe Lofgren, California (D)

Majority Staff Director: Janie Thompson
Minority Staff Director: Josh Mathis
Meeting Location: 2321 Rayburn House Office Building, Washington, DC 20515; Phone: 202-225-6371

Wikipedia Entry        Government Website:science.house.gov/

Caucuses & Other Committees

  • Joint Committee on the Library (Subcommittee on Science)
  • Senate Committee on Energy and Natural Resources (Subcommittee on Energy)

Caucuses

House of Representatives

  • Congressional Science, Space, and Technology Caucus (CSSTC): Focused on promoting science, technology, engineering, and mathematics (STEM) education and innovation.
  • Congressional Robotics Caucus: Advocates for the advancement of robotics technology and its applications across industries.
  • Artificial Intelligence Caucus: Promotes responsible development and deployment of artificial intelligence (AI).
  • Space Caucus: Focuses on issues related to space exploration, space policy, and aerospace industry.
  • Congressional Cyber Caucus: Addresses cybersecurity threats and promotes secure cyberspace.
  • Congressional Nanotechnology Caucus: Supports the advancement of nanotechnology research and its applications.

Senate

  • Senate Science and Technology Committee: Oversees science and technology policy, research, and development funding.
  • Senate Subcommittee on Science, Space, and Competitiveness: Focuses on STEM education, scientific research, and technological innovation.
  • Senate Subcommittee on Space, Science, and Competitiveness: Oversees space exploration, NASA funding, and astrophysics research.
  • Senate Cybersecurity Caucus: Promotes cybersecurity awareness, research, and policy.
  • Senate Artificial Intelligence Caucus: Supports responsible AI development and deployment.

Bipartisan Caucuses

  • Congressional Internet Caucus: Addresses issues related to the internet, technology, and cybersecurity.
  • Congressional Blockchain Caucus: Promotes the adoption and responsible use of blockchain technology.
  • Congressional Caucus on the Future of Work: Focuses on the impact of technology on the workforce and the economy.

More Information

Judiciary

The judiciary is increasingly involved with science and technology as legal cases become more complex. Judges and juries must understand scientific and technological issues to make decisions in a variety of cases, including:
  • Mass torts
    Judges must understand scientific, medical, and statistical principles to evaluate the likelihood of injury from chemical agents, medical devices, or pharmaceutical products.
  • Patent infringement
    Judges and juries must understand scientific or technological issues to decide if there was patent infringement.
  • Criminal law
    Judges must evaluate the scientific validity of evidence, such as DNA comparison or brain imaging, to determine if it’s admissible. 

To improve the quality of science in judicial determinations, the judiciary is working to: 
  • Educate judges
    The Federal Judicial Center offers science education programs for judges, including the Reference Manual on Scientific Evidence. The AAAS Center for Scientific Responsibility and Justice (SRJ) also offers judicial seminars and other resources to help judges understand science and technology. 

  • Improve communication
    The Program in Science, Technology, and Law brings together scientists, engineers, judges, attorneys, and government and corporate officials to improve communication between these communities. 

  • Use technology wisely
    Courts should ensure that new technologies benefit all parties and are adopted in a way that respects due process, procedural fairness, and transparency

Nonpartisan Organizations

Source: Google Search + Gemini + onAir curation

Science and Technology Policy

  • American Association for the Advancement of Science (AAAS)
  • Union of Concerned Scientists (UCS)
  • Council on Foreign Relations (CFR)
  • National Academy of Sciences, Engineering, and Medicine

Science Education

  • National Science Teachers Association (NSTA)
  • American Association of Physics Teachers (AAPT)
  • National Association of Biology Teachers (NABT)
  • American Chemical Society (ACS)

Science Communication

  • Society for Science & the Public
  • American Geophysical Union (AGU)
  • American Institute of Physics (AIP)
  • Association for the Advancement of Artificial Intelligence (AAAI)

Science and Society

  • AAAS Center for Science Diplomacy
  • National Organization of Science and Technology Advisors (NOSTRA)
  • Federation of American Scientists (FAS)
  • American Civil Liberties Union (ACLU)

Energy and Climate Change

  • Environmental Defense Fund (EDF)
  • Natural Resources Defense Council (NRDC)
  • Sierra Club
  • American Geophysical Union (AGU)

Health and Medicine

  • National Institutes of Health (NIH)
  • National Cancer Institute (NCI)
  • American Academy of Pediatrics (AAP)
  • American Medical Association (AMA)

Partisan Organizations

Source: Google Search + Gemini + onAir curation

Democratic Organizations

  • Union of Concerned Scientists (UCS): Advocates for socially responsible use of science and technology, with a focus on climate change, nuclear safety, and responsible innovation.
  • Council for Responsible Genetics (CRG): Promotes responsible use of genetic technologies, including the protection of genetic privacy and the prevention of discrimination.
  • Public Citizen: Advocates for consumer protection, public health, and environmental safety, including issues related to science and technology.
  • Sierra Club: A national environmental organization that addresses issues such as climate change mitigation and adaptation, sustainable energy, and protecting public lands.
  • American Civil Liberties Union (ACLU): Defends civil liberties, including the right to privacy and the freedom of speech, which can impact scientific research and innovation.

Republican Organizations

  • The Heritage Foundation: A conservative think tank that promotes free-market policies and limited government regulation, including in the areas of science and technology.
  • American Enterprise Institute (AEI): A research and educational organization that promotes conservative values, including support for scientific research and innovation.
  • Cato Institute: A libertarian think tank that advocates for free-market principles, limited government intervention, and individual liberty, which can impact science and technology policy.
  • Competitive Enterprise Institute (CEI): A free-market advocacy organization that challenges government regulations and promotes the benefits of competition, including in the areas of science and technology.
  • American Legislative Exchange Council (ALEC): A network of state legislators that promotes conservative legislation, including bills related to science education and environmental regulation.

“Science and technology in the US” (Wiki)

Science and technology in the United States has a long history, producing many important figures and developments in the field. The United States of America came into being around the Age of Enlightenment (1685 to 1815), an era in Western philosophy in which writers and thinkers, rejecting the perceived superstitions of the past, instead chose to emphasize the intellectual, scientific and cultural life, centered upon the 18th century, in which reason was advocated as the primary source for legitimacy and authority. Enlightenment philosophers envisioned a “republic of science,” where ideas would be exchanged freely and useful knowledge would improve the lot of all citizens.

The United States Constitution itself reflects the desire to encourage scientific creativity. It gives the United States Congress the power “to promote the progress of science and useful arts, by securing for limited times to authors and inventors the exclusive right to their respective writings and discoveries.”[1] This clause formed the basis for the U.S. patent and copyright systems, whereby creators of original art and technology would get a government granted monopoly, which after a limited period would become free to all citizens, thereby enriching the public domain.[2]

Early American science

National Academy of Sciences
Benjamin Franklin, one of the first early American scientists
Henry Ford, Thomas Edison, and Harvey Firestone in Fort Myers, Florida, February 11, 1929

In the early decades of its history, the United States was relatively isolated from Europe and also rather poor. At this stage, America’s scientific infrastructure was still quite primitive compared to the long-established societies, institutes, and universities in Europe.

Eight of America’s founding fathers were scientists of some repute. Benjamin Franklin conducted a series of experiments that deepened human understanding of electricity. Among other things, he proved what had been suspected but never before shown: that lightning is a form of electricity. Franklin also invented such conveniences as bifocal eyeglasses. Franklin also conceived the mid-room furnace, the “Franklin Stove”. However, Franklin’s design was flawed, in that his furnace vented the smoke from its base: because the furnace lacked a chimney to “draw” fresh air up through the central chamber, the fire would soon go out. It took David R. Rittenhouse, another hero of early Philadelphia, to improve Franklin’s design by adding an L-shaped exhaust pipe that drew air through the furnace and vented its smoke up and along the ceiling, then into an intramural chimney and out of the house.[3]

Thomas Jefferson (1743–1826), was among the most influential leaders in early America; during the American Revolutionary War (1775–83), Jefferson served in the Virginia legislature, the Continental Congress, was governor of Virginia, later serving as U.S. minister to France, U.S. secretary of state, vice president under John Adams (1735–1826), writer of the Declaration of Independence and the third U.S. president. During Jefferson’s two terms in office (1801–1809), the U.S. purchased the Louisiana Territory and Lewis and Clark explored the vast new acquisition.

After leaving office, he retired to his Virginia plantation, Monticello, and helped spearhead the University of Virginia.[4] Jefferson was also a student of agriculture who introduced various types of rice, olive trees, and grasses into the New World. He stressed the scientific aspect of the Lewis and Clark expedition (1804–06),[5] which explored the Pacific Northwest, and detailed, systematic information on the region’s plants and animals was one of that expedition’s legacies.[6]

Like Franklin and Jefferson, most American scientists of the late 18th century were involved in the struggle to win American independence and forge a new nation. These scientists included the astronomer David Rittenhouse, the medical scientist Benjamin Rush, and the natural historian Charles Willson Peale.[6]

During the American Revolution, Rittenhouse helped design the defenses of Philadelphia and built telescopes and navigation instruments for the United States’ military services. After the war, Rittenhouse designed road and canal systems for the state of Pennsylvania. He later returned to studying the stars and planets and gained a worldwide reputation in that field.[6]

As United States Surgeon General, Benjamin Rush saved countless lives of soldiers during the American Revolutionary War by promoting hygiene and public health practices. By introducing new medical treatments, he made the Pennsylvania Hospital in Philadelphia an example of medical enlightenment, and after his military service, Rush established the first free clinic in the United States.[6]

Charles Willson Peale is best remembered as an artist, but he also was a natural historian, inventor, educator, and politician. He created the first major museum in the United States, the Peale Museum in Philadelphia, which housed the young nation’s only collection of North American natural history specimens. Peale excavated the bones of an ancient mastodon near West Point, New York; he spent three months assembling the skeleton, and then displayed it in his museum. The Peale Museum started an American tradition of making the knowledge of science interesting and available to the general public.[6]

Science immigration

American political leaders’ enthusiasm for knowledge also helped ensure a warm welcome for scientists from other countries. A notable early immigrant was the British chemist Joseph Priestley, who was driven from his homeland because of his dissenting politics. Priestley, who migrated to the United States in 1794, was the first of thousands of talented scientists drawn to the United States in search of a free, creative environment.[6]

Alexander Graham Bell placing the first New York to Chicago telephone call in 1892

Other scientists had come to the United States to take part in the nation’s rapid growth. Alexander Graham Bell, who arrived from Scotland by way of Canada in 1872, developed and patented the telephone and related inventions. Charles Proteus Steinmetz, who came from Germany in 1889, developed new alternating-current electrical systems at General Electric Company,[6] and Vladimir Zworykin, an immigrant who arrived from Russia to the States in 1919, bringing his knowledge of x-rays and cathode ray tubes and later won his first patent on a television system he invented. The Serbian Nikola Tesla went to the United States in 1884, and would later adapt the principle of the rotating magnetic field in the development of an alternating current induction motor and polyphase system for the generation, transmission, distribution and use of electrical power.[7]

Enrico Fermi physicist and Nobel laureate, Fermi moved to the USA in 1938. He played a crucial role in the Manhattan Project, which led to the development of the atomic bomb.

Into the early 1900s, Europe remained the center of science research, notably in England and Germany. From the 1920s onwards, the tensions heralding the onset of World War II spurred sporadic but steady scientific emigration, or “brain drain“, in Europe. Many of these emigrants were Jewish scientists, fearing the repercussions of anti-Semitism, especially in Germany and Italy, and sought sanctuary in the United States.[8] One of the first to do so was Albert Einstein in 1933. At his urging, and often with his support, a good percentage of Germany’s theoretical physics community, previously the best in the world, left for the United States. Enrico Fermi, came from Italy in 1938, and led the work that produced the world’s first self-sustaining nuclear chain reaction. Many other scientists of note moved to the U.S. during this same emigration wave, including Niels Bohr, Victor Weisskopf, Otto Stern, and Eugene Wigner.[9]

Several scientific and technological breakthroughs during the Atomic Age were the handiwork of such immigrants, who recognized the potential threats and uses of new technology. For instance, it was German professor Einstein and his Hungarian colleague, Leó Szilárd, who took the initiative and convinced President Franklin D. Roosevelt to pursue the pivotal Manhattan Project.[10] Many physicists instrumental to the project were also European immigrants, such as the Hungarian Edward Teller, “father of the hydrogen bomb,”[11] and German Nobel laureate Hans Bethe. Their scientific contributions, combined with Allied resources and facilities helped establish the United States during World War II as an unrivaled scientific juggernaut. In fact, the Manhattan Project’s Operation Alsos and its components, while not designed to recruit European scientists, successfully collected and evaluated Axis military scientific research at the end of the war, especially that of the German nuclear energy project, only to conclude that it was years behind its American counterpart.[12]

Theoretical physicist Albert Einstein, who emigrated to the United States to escape Nazi persecution, is an example of human capital flight as a result of political change.

When World War II ended, the United States, the United Kingdom and the Soviet Union were all intent on capitalizing on Nazi research and competed for the spoils of war. While President Harry S. Truman refused to provide sanctuary to ideologically committed members of the Nazi party, the Office of Strategic Services introduced Operation Paperclip, conducted under the Joint Intelligence Objectives Agency. This program covertly offered otherwise ineligible intellectuals and technicians whitewashed dossiers, biographies, and employment. Ex-Nazi scientists overseen by the JIOA had been employed by the U.S. military since the defeat of the Nazi regime in Project Overcast, but Operation Paperclip ventured to systematically allocate German nuclear and aerospace research and scientists to military and civilian posts, beginning in August 1945. Until the program’s termination in 1990, Operation Paperclip was said to have recruited over 1,600 such employees in a variety of professions and disciplines.[13]

Serbian-American inventor Nikola Tesla sitting in the Colorado Springs experimental station with his “Magnifying transmitter” generating millions of volts

In the first phases of Operation Paperclip, these recruits mostly included aerospace engineers from the German V-2 combat rocket program, experts in aerospace medicine and synthetic fuels. Perhaps the most influential of these was Wernher Von Braun, who had worked on the Aggregate rockets (the first rocket program to reach outer space), and chief designer of the V-2 rocket program. Upon reaching American soil, Von Braun first worked on the United States Air Force ICBM program before his team was reassigned to NASA.[14] Often credited as “The Father of Rocket Science,” his work on the Redstone rocket and the successful deployment of the Explorer 1 satellite as a response to Sputnik 1 marked the beginning of the American Space program, and therefore, of the Space Race. Von Braun’s subsequent development of the Saturn V rocket for NASA in the mid-to late sixties resulted in the first crewed landing on the Moon, the Apollo 11 mission in 1969.

Wernher von Braun with the F-1 engines of the Saturn V first stage at the U.S. Space and Rocket Center

In the post-war era, the U.S. was left in a position of unchallenged scientific leadership, being one of the few industrial countries not ravaged by war. Additionally, science and technology were seen to have greatly added to the Allied war victory, and were seen as absolutely crucial in the Cold War era. This enthusiasm simultaneously rejuvenated American industry, and celebrated Yankee ingenuity, instilling a zealous nationwide investment in “Big Science” and state-of-the-art government funded facilities and programs. This state patronage presented appealing careers to the intelligentsia, and further consolidated the scientific preeminence of the United States. As a result, the U.S. government became, for the first time, the largest single supporter of basic and applied scientific research. By the mid-1950s, the research facilities in the U.S. were second to none, and scientists were drawn to the U.S. for this reason alone. The changing pattern can be seen in the winners of the Nobel Prize in physics and chemistry. During the first half-century of Nobel Prizes – from 1901 to 1950 – American winners were in a distinct minority in the science categories. Since 1950, Americans have won approximately half of the Nobel Prizes awarded in the sciences.[15] See the List of Nobel laureates by country.

The American Brain Gain continued throughout the Cold War, as tensions steadily escalated in the Eastern Bloc, resulting in a steady trickle of defectors, refugees and emigrants. The partition of Germany, for one, precipitated over three and a half million East Germans – the Republikflüchtling – to cross into West Berlin by 1961. Most of them were young, well-qualified, educated professionals or skilled workers[16] – the intelligentsia – exacerbating human capital flight in the GDR to the benefit of Western countries, including the United States.

Technology inflows from abroad have played an important role in the development of the United States, especially in the late nineteenth century. A favorable US security environment that allowed relatively low defense spending. High trade barriers encouraged the development of domestic manufacturing industries and the inflow of foreign technologies.[17]

American applied science

Men of Progress, representing 19 contemporary American inventors, 1857

During the 19th century Britain, France, and Germany were at the forefront of new ideas in science and mathematics.[18][19] But if the United States lagged behind in the formulation of theory, it excelled in using theory to solve problems: applied science. This tradition had been born of necessity. Because Americans lived so far from the well-springs of Western science and manufacturing, they often had to figure out their own ways of doing things. When Americans combined theoretical knowledge with “Yankee ingenuity“, the result was a flow of important inventions. The great American inventors include Robert Fulton (the steamboat); Samuel Morse (the telegraph); Eli Whitney (the cotton gin); Cyrus McCormick (the reaper); and Thomas Alva Edison, with more than a thousand inventions credited to his name. His research laboratory developed the phonograph, the first long-lasting light bulb, and the first viable movie camera.[20]

First flight of the Wright Flyer I, December 17, 1903, Orville piloting, Wilbur running at wingtip

Edison was not always the first to devise a scientific application, but he was frequently the one to bring an idea to a practical finish. For example, the British engineer Joseph Swan built an incandescent electric lamp in 1860, almost 20 years before Edison. But Edison’s light bulbs lasted much longer than Swan’s, and they could be turned on and off individually, while Swan’s bulbs could be used only in a system where several lights were turned on or off at the same time. Edison followed up his improvement of the light bulb with the development of electrical generating systems. Within 30 years, his inventions had introduced electric lighting into millions of homes.

Howard Hughes with his Boeing 100 in the 1940s

Another landmark application of scientific ideas to practical uses was the innovation of the brothers Wilbur and Orville Wright. In the 1890s, they became fascinated with accounts of German glider experiments and began their own investigation into the principles of flight. Combining scientific knowledge and mechanical skills, the Wright brothers built and flew several gliders. Then, on December 17, 1903, they successfully flew the first sustained and controlled heavier-than-air powered flight.[21]
The automobile companies of Ransom E. Olds (Oldsmobile) and Henry Ford (Ford Motor Company) popularized the assembly line in the early 20th century. The rise of fascism and Nazism in the 1920s and 30s led many European scientists, such as Albert Einstein, Enrico Fermi, and John von Neumann, to immigrate to the United States.[22]

An American invention that was barely noticed in 1947 went on to usher in the Information Age. In that year John Bardeen, William Shockley, and Walter Brattain of Bell Laboratories drew upon highly sophisticated principles of quantum physics to invent the transistor, a key component in almost all modern electronics, which led to the development of microprocessors, software, personal computers, and the Internet.[23] As a result, book-sized computers of today can outperform room-sized computers of the 1960s, and there has been a revolution in the way people live – in how they work, study, conduct business, and engage in research.
World War II had a profound impact on the development of science and technology in the United States. Before World War II, the federal government basically did not assume responsibility for supporting scientific development. During the war, the federal government and science formed a new cooperative relationship. After the war, the federal government became the main role in supporting science and technology. And in the following years, the federal government supported the establishment of a national modern science and technology system, making America a world leader in science and technology.[24]

Part of America’s past and current preeminence in applied science has been due to its vast research and development budget, which at $401.6bn in 2009 was more than double that of China’s $154.1bn and over 25% greater than the European Union’s $297.9bn.[25]

The Atomic Age and “Big Science”

The mushroom cloud from the Mike shot, developed by United States Atomic Energy Commission

One of the most spectacular – and controversial – accomplishments of US technology has been the harnessing of nuclear energy. The concepts that led to the splitting of the atom were developed by the scientists of many countries, but the conversion of these ideas into the reality of nuclear fission was accomplished in the United States in the early 1940s, both by many Americans but also aided tremendously by the influx of European intellectuals fleeing the growing conflagration sparked by Adolf Hitler and Benito Mussolini in Europe.

The Space Shuttle Columbia takes off on a crewed mission to space.

During these crucial years, a number of the most prominent European scientists, especially physicists, immigrated to the United States, where they would do much of their most important work; these included Hans Bethe, Albert Einstein, Enrico Fermi, Leó Szilárd, Edward Teller, Felix Bloch, Emilio Segrè, John von Neumann, and Eugene Wigner, among many, many others. American academics worked hard to find positions at laboratories and universities for their European colleagues.

A visual example of a 24 satellite GPS constellation in motion with the earth rotating. Notice how the number of satellites in view from a given point on the earth’s surface, in this example in Golden, Colorado, USA(39.7469° N, 105.2108° W), changes with time.

After German physicists split a uranium nucleus in 1938, a number of scientists concluded that a nuclear chain reaction was feasible and possible. The Einstein–Szilárd letter to President Franklin D. Roosevelt warned that this breakthrough would permit the construction of “extremely powerful bombs.” This warning inspired an executive order towards the investigation of using uranium as a weapon, which later was superseded during World War II by the Manhattan Project the full Allied effort to be the first to build an atomic bomb. The project bore fruit when the first such bomb was exploded in New Mexico on July 16, 1945.

The development of the bomb and its use against Japan in August 1945 initiated the Atomic Age, a time of anxiety over weapons of mass destruction that has lasted through the Cold War and down to the anti-proliferation efforts of today. Even so, the Atomic Age has also been characterized by peaceful uses of nuclear power, as in the advances in nuclear power and nuclear medicine.

Edward Witten is a renowned theoretical physicist and mathematician known for his groundbreaking contributions to string theory and various areas of mathematical physics.

Along with the production of the atomic bomb, World War II also began an era known as “Big Science” with increased government patronage of scientific research. The advantage of a scientifically and technologically sophisticated country became all too apparent during wartime, and in the ideological Cold War to follow the importance of scientific strength in even peacetime applications became too much for the government to any more leave to philanthropy and private industry alone. This increased expenditure on scientific research and education propelled the United States to the forefront of the international scientific community—an amazing feat for a country which only a few decades before still had to send its most promising students to Europe for extensive scientific education.

The first US commercial nuclear power plant started operation in Illinois in 1956. At the time, the future for nuclear energy in the United States looked bright. But opponents criticized the safety of power plants and questioned whether safe disposal of nuclear waste could be assured. A 1979 accident at Three Mile Island in Pennsylvania turned many Americans against nuclear power. The cost of building a nuclear power plant escalated, and other, more economical sources of power began to look more appealing. During the 1970s and 1980s, plans for several nuclear plants were cancelled, and the future of nuclear power remains in a state of uncertainty in the United States.

Meanwhile, American scientists have been experimenting with other renewable energy, including solar power. Although solar power generation is still not economical in much of the United States, recent developments might make it more affordable.

Telecom and technology

Bill Gates and Steve Jobs at the fifth D: All Things Digital conference (D5) in 2007

For the past 80 years, the United States has been integral in fundamental advances in telecommunications and technology. For example, AT&T’s Bell Laboratories spearheaded the American technological revolution with a series of inventions including the first practical light emitted diode (LED), the transistor, the C programming language, and the Unix computer operating system.[26] SRI International and Xerox PARC in Silicon Valley helped give birth to the personal computer industry, while ARPA and NASA funded the development of the ARPANET and the Internet.[27]

Silicon Valley

Herman Hollerith was just a twenty-year-old engineer when he realized the need for a better way for the U.S. government to conduct their Census and then proceeded to develop electromechanical tabulators for that purpose. The net effect of the many changes from the 1880 census: the larger population, the data items to be collected, the Census Bureau headcount, the scheduled publications, and the use of Hollerith’s electromechanical tabulators, was to reduce the time required to process the census from eight years for the 1880 census to six years for the 1890 census.[28] That kick started The Tabulating Machine Company. By the 1960s, the company name had been changed to International Business Machines, and IBM dominated business computing.[29] IBM revolutionized the industry by bringing out the first comprehensive family of computers (the System/360). It caused many of their competitors to either merge or go bankrupt, leaving IBM in an even more dominant position.[30] IBM is known for its many inventions like the floppy disk, introduced in 1971, supermarket checkout products, and introduced in 1973, the IBM 3614 Consumer Transaction Facility, an early form of today’s Automatic Teller Machines.[31]

In 1983, the DynaTAC 8000x was the first commercially available handheld mobile phone. From 1983 to 2014, worldwide mobile phone subscriptions grew to over seven billion; enough to provide one for every person on Earth.[32]

The Space Age

Two Jet Propulsion Laboratory engineers stand with three vehicles, providing a size comparison of three generations of Mars rovers. Front and center is the flight spare for the first Mars rover, Sojourner, which landed on Mars in 1997 as part of the Mars Pathfinder Project. On the left is a Mars Exploration Rover (MER) test vehicle that is a working sibling to Spirit and Opportunity, which landed on Mars in 2004. On the right is a test rover for the Mars Science Laboratory (MSL), which landed Curiosity on Mars in 2012.

Sojourner is 65 cm (2.13 ft) long. The MERs are 1.6 m (5.2 ft) long. Curiosity on the right is 3 m (9.8 ft) long.

The Hubble Space Telescope as seen from Space Shuttle Discovery during its second servicing mission
Mars Oxygen ISRU Experiment

During the Cold War, competition for superior missile capability led to the Space Race between the United States and Soviet Union.[33][34] American Robert Goddard was one of the first scientists to experiment with rocket propulsion systems. In his small laboratory in Worcester, Massachusetts, Goddard worked with liquid oxygen and gasoline to propel rockets into the atmosphere, and in 1926 successfully fired the world’s first liquid-fuel rocket which reached a height of 12.5 meters.[35] Over the next 10 years, Goddard’s rockets achieved modest altitudes of nearly two kilometers, and interest in rocketry increased in the United States, Britain, Germany, and the Soviet Union.[36]

As Allied forces advanced during World War II, both the American and Russian forces searched for top German scientists who could be claimed as spoils for their country. The American effort to bring home German rocket technology in Operation Paperclip, and the bringing of German rocket scientist Wernher von Braun (who would later sit at the head of a NASA center) stand out in particular.

Expendable rockets provided the means for launching artificial satellites, as well as crewed spacecraft. In 1957, the Soviet Union launched the first satellite, Sputnik 1, and the United States followed with Explorer 1 in 1958. The first human spaceflights were made in early 1961, first by Soviet cosmonaut Yuri Gagarin and then by American astronaut Alan Shepard.

From those first tentative steps, to the Apollo 11 landing on the Moon and the partially reusable Space Shuttle, the American space program brought forth a breathtaking display of applied science. Communications satellites transmit computer data, telephone calls, and radio and television broadcasts. Weather satellites furnish the data necessary to provide early warnings of severe storms. The United States also developed the Global Positioning System (GPS), the world’s pre-eminent satellite navigation system.[37] Interplanetary probes and space telescopes began a golden age of planetary science and advanced a wide variety of astronomical work.

On April 20, 2021, MOXIE produced oxygen from Martian atmospheric carbon dioxide using solid oxide electrolysis, the first experimental extraction of a natural resource from another planet for human use.[38] In 2024, the United States ranked 3rd in the Global Innovation Index.[39]

Medicine and health care

A 1783 portrait of Rush by Charles Willson Peale. Known as the “Father of American Psychiatry.”
Gene therapy using an adenovirus vector. In some cases, the adenovirus will insert the new gene into a cell. If the treatment is successful, the new gene will make a functional protein to treat a disease.

As in physics and chemistry, Americans have dominated the Nobel Prize for physiology or medicine since World War II. The private sector has been the focal point for biomedical research in the United States, and has played a key role in this achievement.

Maurice Hilleman, a well-known American virologist, is remembered for having developed more than 40 Vaccines, thus creating an important record in the field of medicine. He was responsible for his contribution to the creation of vaccines against the Asian flu of 1957, which broke out in Guizhou, and the Hong Kong flu of 1968, contributing to the preparation and distribution of the vaccine doses that saved the world. He was responsible for the creation of vaccines against measles, mumps, hepatitis A, hepatitis B, chickenpox, Neisseria meningitidis, Streptococcus pneumoniae and Haemophilus influenzae. He was awarded the Distinguished Service Medal by the US Army for his important work.[1].

Dr. Michael DeBakey was a renowned cardiovascular surgeon and innovator. He made significant contributions to the development of the artificial heart and pioneered techniques in heart surgery.

As of 2000, for-profit industry funded 57%, non-profit private organizations such as the Howard Hughes Medical Institute funded 7%, and the tax-funded National Institutes of Health (NIH) funded 36% of medical research in the United States.[40] However, by 2003, the NIH funded only 28% of medical research funding; funding by private industry increased 102% from 1994 to 2003.[41]

The NIH consists of 24 separate institutes in Bethesda, Maryland. The goal of NIH research is knowledge that helps prevent, detect, diagnose, and treat disease and disability. At any given time, grants from the NIH support the research of about 35,000 principal investigators. Five Nobel Prize-winners have made their prize-winning discoveries in NIH laboratories.

NIH research has helped make possible numerous medical achievements. For example, mortality from heart disease, the number-one killer in the United States, dropped 41 percent between 1971 and 1991. The death rate for strokes decreased by 59 percent during the same period. Between 1991 and 1995, the cancer death rate fell by nearly 3 percent, the first sustained decline since national record-keeping began in the 1930s. And today more than 70 percent of children who get cancer are cured.

With the help of the NIH, molecular genetics and genomics research have revolutionized biomedical science. In the 1980s and 1990s, researchers performed the first trial of gene therapy in humans and are now able to locate, identify, and describe the function of many genes in the human genome.

Research conducted by universities, hospitals, and corporations also contributes to improvement in diagnosis and treatment of disease. NIH funded the basic research on Acquired Immune Deficiency Syndrome (AIDS), for example, but many of the drugs used to treat the disease have emerged from the laboratories of the American pharmaceutical industry; those drugs are being tested in research centers across the country.

See also

References

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  5. ^ “Thomas Jefferson and the Lewis and Clark Expedition – Thomas Jefferson’s Monticello”.
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  39. ^ World Intellectual Property Organization (2024). Global Innovation Index 2024. Unlocking the Promise of Social Entrepreneurship. Geneva. p. 18. doi:10.34667/tind.50062. ISBN 978-92-805-3681-2. Retrieved October 22, 2024. {{cite book}}: |website= ignored (help)CS1 maint: location missing publisher (link)
  40. ^ The Benefits of Medical Research and the Role of the NIH.
  41. ^ Medical Research Spending Doubled Over Past Decade, Neil Osterweil, MedPage Today, September 20, 2005


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