[From the U.S. Government Printing Office, www.gpo.gov]
The
U.S. GLOBAL OCEAN
SCIENCE PROGRAM
COAASTI@* LZ ONE
INFORAIATION CENTER
A Strategy for Understanding
the Role of the Ocean in Global Change
d
GC Dctober 1987
lcjo. 2
U55
1987
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THE
U.S. GLOBAL OCEAN SCIENCE PROGRAM
A STRATEGY FOR UNDERSTANDING
THE ROLE OF THE OCEAN IN GLOBAL CHANGE
A Report to the Ocean Principals
U.S. DEPARTMENT OF COMMERCE NOAA
COASTAL SERVICES CENTER
2234 SOUTH HOBSON AVENUE
CHARLESTON , SC 29405-2413
U.S. GOSP Interagency Working Group
October 1987
GC 190.2, U55 1987
24250850
DEC 11 1996
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Preface
The enclosed interagency report: "The U.S. Global Ocean Science Program" represents the
first stage of a coordinated, federal agency, strategic planning effort. The planning began
in November 1985 in recognition of the urgency of describing and understanding the
central role of the ocean in global change and the multiple effects of the ocean on our
society. The planning is timely because of the existence of new insights and the application
of new measurement and computing technology to global ocean processes. To carry out the
effort, the Ocean Principals agreed to coordinate the development of a national plan for
ocean sciences. The goal of the plan was to maintain and strengthen U.S. leadership in
ocean science and technology and to develop stronger international cooperation.
Planning during the following year in the federal agencies and in the ocean resear ch
community culminated in a workshop held at USGS Headquarters in Reston, Virginia on
November 6 and 7, 1986. The workshop included representatives from federal agencies
and the academic research community. From the workshop, a statement of opportunities
and plans was developed that was presented to the Ocean Principals on February 18,
1987. The statement outlined a strategic planning context for a U.S. Global Ocean Science
Program.
In response to the statement, the heads of the involved agencies requested the National
Science Foundation to convene an interagency working group to develop the overall goals
and objectives and identify specific scientific components of a U.S. Global Ocean Science
Program. In the course of this planning the group was also to develop recommendations on
steps needed to begin to implement the program. The planning was to be carried out in the
scientific context of active national and international planning for studies of global
environmental change.
The report presented here is the first stage of that planning effort. It presents the
rationale for the U.S. Global Ocean Science Program, identifies the necessary components
of science and technology, lays out the required actions for the short term, provides for
continuing coordination, and estimates the level of effort, over a 7-year period centered
upon FY 1989, required for the Program's success. The report, which will be updated
annually, provides an interagency strategic planning mechanism that allows individual
agencies to present a coordinated program structure for FY 1989.
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U.S. Global Ocean Science Program
Table of Contents
1. Executive Summary . . . . . . . . . . . . . . . . . . . . . . . . . 1
11. U.S. Global Ocean Science Program ... . . . . . . . . . . . . . . . . . 3
1. Opportunity and Challenge: the U.S. Global Ocean Science Program . . . . 3
2. The Rationale: Importance of Understanding the Global Ocean . . . . . . 4
3. New Developments: Where Do We Stand Today? . . . . . . . . . . . . 7
4. Recognition of Urgency: Why Now? . . . . . . . . . . . . . . . . 8
5. Evolution of the Interagency Program . . . . . . . . . . . . . . . 10
6. Goals, Objectives, Components, and Coordination . . . . . . . 0 0 . 11
17. Specific Agency Contributions and Required Actions . . . . . . . . . 19
III. Appendices: . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32
A. Acknowledgements
B. Attendees at Reston Meeting
C. Members of U.S. Global Ocean Science Program Working Group
D. Glossary
E. Bibliography
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EXECUTIVE SUMMARY
The U.S. Global Ocean Science Program is an interagency effort toassess and understand
earth's last frontier: the global ocean. The program has been developed in recognition of
the fact that, as in all frontier exploration, the nation that explores and understands it
earliest and best will benefit most. We know that the ocean plays a central role in global
change: It interacts with the atmosphere to cause changes in seasonal weather patterns,
and it is the principal driver of long-term climate change. The ocean is a critical source
of mineral and energy resources as well as a fertile field for fisheries, yet is subject to
extensive waste disposal. As a maritime nation, we have always seen the ocean as key to
our national defense. Thus, assessment and understanding of the global ocean and its
boundaries have been and should continue to be a national priority.
The nation is ready to carry out this global program. Satellites, supercomputers, and
other new ways of observing and modelling the ocean are at hand. The opportunity,
however, puts the U.S. at a crossroads in ocean science. Historically we have been'the
world leader in this field; but our leadership is diminishing as. our investment declines
and the investment of other countries grows aggressively. We face a global challenge and
we have an unprecedented opportunity: to use our technology and knowledge to move boldly
ahead in ocean science.
The goal of the U.S. Global Ocean Science Program is to describe and understand more fully
the interactive physical, chemical, geological, and biological processes within the global
ocean that contribute significantly to the regulation and condition of the earth's global
environment and to understand changes, both natural and anthropogenic, in the ocean that
affect the health of that environment.
Specific objectives include: understanding ocean processes and their effects on global
weather and climate; understanding both the natural variability of the global ocean and
that due to man's activities, so that the ocean may be used effectively with minimal
adverse impact; assessing and managing our coastal oceans and exclusive economic zone; -
and assuring national security interests and the safety of vessels and life at sea.
The program strategy used to address these issues divides the U.S. Global Ocean Science
Program into five major science and three major infrastructure components:
- Global Ocean Structure and Dynamics
- Global Climate: Atmosphere-Ocean Interaction
- Global Ecosystems and Productivity Processes
- Global Ocean Lithosphere and Geoprocesses
- Coastal Margins and Polar Oceans Processes
- Technology for Global Measurements
- Facilities and Centers
- Data Management Systems
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,The U.S. Global Ocean Science Program requires cooperation among federal agencies
because ocean processes transcend state and national boundaries and the related issues cut
across agency responsibilities. Studies of the ocean are too long-term for the private
sector, and too important to the nation's security and future strength to leave leadership to
others. No single agency can marshall all the resources needed to gain a fully
comprehensive understanding of the ocean and its role in the earth system. Thus, we must
look to a collaborative and cooperative arrangement. The context of global environmental
ch ange and the need for interagency cooperation are the overarching rationale and driving
force for the U.S. Global Ocean Science Program.
In this context, for each of the science and infrastructure components of the program, the
Federal agencies including the National Science Foundation, the National Oceanic and
Atmospheric Administration, the Department of the Navy, the National Aeronautics and
Space Administration, the United States Geological Survey, the Environmental Protection
Agency, the Department of Energy, and the Department of State have developed plans that
will be coordinated by an interagency working group. This group will represent those
agencies with major roles in the U.S. Global Ocean Science Program as well as those that
will collaborate in particular components. Specific agency contributions to each
component and plans for coordination are summarized in the report. FY 1989 actions
required for the Program's success are identified, and a 7-year level of effort centered on
FY 1989 is estimated.
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U.S. Global Ocean Science Program
Opportunity and Challenge: the U..S. Global Ocean Science Program
In every scientific field, major advances in understanding are driven by new technology
that provides a clearer view and different perspective of nature at work. When these
advances have an impact on pressing economic issues, major national benefits can accrue.
Today we are offered such an opportunity at Earth's last frontier: the global ocean. New
instruments, whether satellite-borne, in the ocean, or on the sea floor give us a
capability to understand the role of the ocean in the total earth system. Supercomputers
and communications technologies link scientists and sources of data so that models of
ocean, atmosphere, and sea floor processes can be constructed to provide the basis for
better prediction. With the opportunity now offered by new technology and new insights
into ocean and seafloor processes, we are ready to accept the challenge of assessing and
understanding the global ocean and its role in global environmental change. The payoff
will accrue in basic scientific knowledge, in improved national security, and in economic
development.
The U.S. Global Ocean Science Program describes a Federal plan to assess and understand
this last frontier. In recognition of the breadth of agencies and disciplines involved, the
plan has been developed by an interagency group. It appears now in recognition of the fact
that, as in all frontier exploration, the nation that explores and understands it earliest and
best will benefit most.
This report establishes the goals, objectives, and components of the Program, and
illustrates how these will be coordinated. The aim of the report is to set the scientific and
technological context for agency programs and plans and to identify specific actions
required in the near and far term if the Program is to succeed.
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2. The Rationale: Importance of Understanding the Global Ocean
Our knowledge of the global ocean with its coastal and polar margins has expanded
dramatically in recent years, bringing insights about the ocean and its role in the complex
processes that govern the nature and health of our planet. For example, today we know
that the ocean interacts with the atmosphere to cause changes in seasonal weather
patterns. It is the principal driver of longer-term climate change. The ocean is a critical
source of mineral and energy resources and a fertile field for fisheries. As a maritime
nation, we have always seen the ocean as a key element in our national defense. Most of the
world's commerce is transported by sea. Better understanding of ocean processes will
result in savings associated with improved shipping practices and the protection of vessels
and life at sea. We do not have sufficient description or knowledge of ocean processes to
enable us to address these major issues adequately. The U.S. Global Ocean Science Program
is aimed at expanding our knowledge of this last global frontier to allow us to resolve these
issues.
Last Frontier
The depth, breadth, and complexity of the global ocean, covering over 70% of earth's
surface, have challenged our ability to explore, measure, and comprehend its governing
processes and to predict its behavior. But today, technology has evolved to the point where
we can examine the ocean on a global scale and study the role it plays in the total global
earth system. We are also beginning to comprehend the changes mankind is making on the
global environment. The little understood physical, chemical, biological, and geological
processes at work in the global ocean and their interaction with the other components of
the earth system are vital elements in the exploration and understanding of this last
frontier. These interactive processes produce our climate, are responsible for the
distribution of fishery, mineral, and energy resources, and are essential elements in
national security and waste disposal.
Changing Climate
Changes in climate are a critical factor governing life on Earth, and the ocean plays a key
role in such climate changes. Describing and understanding short-term,
atmosphere-ocean processes like El Nino can have immediate economic impact.
Agricultural production, and therefore our food supply and economy, is directly affected
by both short and long-term climate variations. Understanding the role of the ocean and its
high-latitude sea-ice cover in long-term changes in climate, especially those related to
changes in atmospheric gases like carbon dioxide, are critical for developing a predictive
capability so that we can project how best to minimize long-term effects on our society.
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Oceanic Crust
Global solid earth processes determine the distribution of mineral and energy resources.
These processes are often revealed best beneath the ocean where surface erosion and other
processes are not present and where geological structure is in many cases simpler than
continental crustal structure. Thus, through increased knowledge of the structure of the
earth's crust beneath the ocean, the oceanic crust, we will gain new understanding of the
processes that generate volcanoes, earthquakes, and tsunamis, and that are responsible for
the distribution of mineral and energy resources. The majority of the earth's remaining
unexplored giant oil fields lie beneath the ocean. The processes leading to the evolution of
the continental margins are critically important to understanding the distribution of the
basins most fertile for exploration.
New Economic Considerat ions
The coastal ocean, with its complex land/sea interactions, provides most of our fishery
resources. Its shallow shelves contain energy resources important to the U.S. economy
and security. Because of this, coastal states around the world have assumed new
responsibility in the coastal ocean by proclaiming Exclusive Economic Zones (EEZ). The
'U.S. EEZ is nearly equal to the land area of the nation. By the year 2000, 75% of the U.S.
population will live within 50 miles of the ocean, making increased demands on estuaries
and coastal resources. Moreover, changing processes in the coastal regions 'also affect the
global ocean, providing a boundary condition.
National Security
Mastery of the sea is essential for national security. The strategic and tactical emphases
of maritime defense have become fully global with new geopolitical and technical
developments. Thus the. global ocean environment is a major critical factor in national
security. The ocean is the Navy's operating medium and a barrier for protection. Yet our
knowledge base is poor. As we improve our understanding of processes and their
variability in the ocean and at the sea floor, the Navy will better be able to exploit the
ocean to advantage. In addition, the sea floor promises to be an important source of
strategic minerals, another aspect of national security.
Waste Disposal
The ocean is the ultimate sink for land, water and many atmospheric discharges.
Moreover, as waste disposal sites are filled on land, the ocean is being used increasingly
for direct disposal. Protecting the ocean and its food and cultural resources requires an
understanding of chemical and biological interactions, the transfer of contaminants
through food chains and their fate in the oceanic system. It.also requires a much better
understanding of the geological and geophysical processes at the sea floor to define the
stability of these regions for potential permanent waste sites.
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Summary
The broad rationale described above reflects our current awareness of the importance of
the global ocean to many of the nation's affairs. The program developed here builds on this
rationale and on new developments in science and technology to provide the optimal
interagency program for achieving an appropriate U.S. role in the necessary assessment
and understanding of the ocean.
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3. New. Developments: Where Do We Stand Today?
Historic Leadership
The U.S. has long been a maritime power. Since World War 11, U.S. oceanographers have
led the world in ocean science. This position of leadership is beginning to bring the nation
major benefits, such as weather and climate prediction, the ability to explore and develop
offshore energy and mineral resources, and increased understanding of the ocean as an
operating medium for the U.S. Navy and merchant marine.
Leadership Diminishing
Our nation's lead is growing smaller due to our own lack of major new investment and the
continued aggressive position taken by our principal trading partners. For example,
Japan and France have each built deep-diving submersibles that can reach most-of the sea
floor. The U.S. ALVIN, the only deep-submersible widely available to the U.S. research
community, can reach only about one-half of the sea floor, and is restricted to working on
continental margins or mid-ocean ridges. U.S. oceanographers seeking to carry out major
programs in the polar regions have had to look to non-U.S. ships: either the new West
German or USSR research icebreakers. Both France and the United Kingdom operate
marine multichannel survey systems that, are vastly superior to those available here. On
shore, laboratories and analytical instruments at U.S. universities are aged and many can
no longer provide students with training in modern technology. 'Without action, we will
lose our competitiveness.
Econoriiic Competitiveness
The global challenge and the national opportunity are especially clear today. Our nation is
facing aggressive competition from other countries, and we are in danger of losing our
scienti.fic and technical leadership with consequent loss of economic competitiveness. We
must be able to reliably assess resources available in the ocean. and at its boundaries to
balance the efforts of other nations who aggressively explore their- EEZs and the global
ocean. The next generation of developments in ocean science could lead to improved
predictions of seasonal and longer term changes in climate and weather predictions, thus
helping to protect the nation's agricultural production and permit the nation to better
protect life and property . The President's 1987 State of the Union address and the FY
1988 Budget submitted to Congress in January 1987 underscore this need. The FY 1988
Budget is aimed at providing Federal su pport for the generation of new knowledge and the
provision of an effective and timely transfer of this new knowledge to specific
applications. A "global geosciences program to understand the earth, its oceans, and its
atmosphere as a unified system" was specifically noted. The U.S. Global Ocean Science
Program has been developed to provide a rapid follow-up of that lead.
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4. Recognition of Urgency: Why Now?
At certain times, developments in basic understanding and technology come together to
produce dramatic advances. Such a breakthrough is now possible in ocean science. A
major increase in global geosciences research with an interdisciplinary approach
exploiting new technology will produce a tremendous increase in our understanding of how
the. earth operates as a system. This is nowhere more evident or more applicable than in
the ocean.
Technical Readiness
The task is to assess and understand the ocean on a global scale. We are now prepared to do
this, because we have capabilities not available earlier. For example, new satellite-borne
instruments permit global observations and provide a capability to describe and
understand the role of the ocean in the total earth system. New instruments in the ocean
and on the ocean floor and new chemical techniques measure processes more precisely and
over longer periods than ever before. Supercomputers now allow us to assimilate and
study the enormous quantities of data from these systems. New communication
technologies can link satellites, ships and instruments at sea, and scientific laboratories
to provide real-time interaction as well as cost-effective data collection.
World Climate Research Program
The new technology has provided a basis for new international programs. The most recent
of these, the World Climate Research Program (WCRP) began in the early 1980s with
new in-situ and satellite measurement techniques. The WCRP is aimed at understanding
long-term weather variability and climate change. In recognition of the central role of the
ocean in these processes, the WCRP has a focus on the interaction of the ocean and the
atmosphere with emphasis on tropical interactions (the Tropical Ocean Global Atmosphere
program - TOGA) and on global ocean circulation (the World Ocean Circulation
Experiment - WOCE). In addition, the WORP will continue to study the processes which
control the energy budget and the exchanges of energy and water within the global climate
system. These programs, for which the U.S. is providing major resources, provide a
context for much of the U.S. Global Ocean Science Program.
International Recognition of Global Change
Issues of global environmental change will necessarily require emphasis on a broader
range of disciplines than those covered in the World Climate Research Program. In
September 1986 the International Council of Scientific Unions approved a new report on
the International Geosphere-Biosphere Program: A Study of Global Change. This new
program (IGBP) will be aimed at describing and understanding the interactive physical,
chemical, and biological processes that regulate the total earth system, the unique
environment it provides for life, the changes that are occurring in the system, and the
manner by which these changes are influenced by human actions. The IGBP builds on the
global and international programs typified by the International Geophysical Year, the
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International Biological Program, the International Lithosphere Program, and the now
active World Climate Research Program. The IGBP will study such phenomena as acid
deposition, ozone depletion, and greenhouse effects, all of which reflect highly coupled
systems of oceanic, atmospheric and terrestrial processes. The international Joint Global
Ocean Flux Study (JGOFS), aimed at understanding oceanic biogeoch emical cycles and
budgets and the factors that control long-t erm chemical, and biological dynamics on global
scales, will make major contributions to the IGBP. JGOFS, which will- have significant
U.S. participation, is' currently in the planning stages under the auspices of the
international Scientific Committee for Oceanic Research (SCOR).
International Cooperation: Programs and Partners
It is clear from the development of these international programs that the international
community of atmospheric and oceanic scientists has come of age. In addition, we have
seen that in such programs as the international Ocean Drilling Program, it is now possible
to have sign'ificant partnerships between the U.S. and other countries. By participating in
these international programs, we leverage our own investments, and thus make it possible
to address these global issues. One of the purposes of the U.S. Global Ocean Science
Program is to help identify and facilitate such international cooperation and management
arrangements.
A Human Resource Base
The nation's most *effective long-term response to the challenge of an international
knowledge- based economy is an educated human resource base. Investing in research is
an effective way to provide educated scientists and engineers and to transfer technology
from research projects to industrial practice. The US has an effective ocean research
community now, and technology transfer has worked reasonably well, but this community
needs to be substantially enlarged to meet the needs of understanding the global ocean and
its role in global change.
The Federal Response
The President's FY 1988 Budget and previous budgets have- responded to. the general
recognition that the U.S. must increase its investments in basic research now to develop
and expand technologies that can help bolster the nation's economy. A vital part of that
investment has been in the ocean sciences, and the return on the investment is becoming
apparent in terms of improved scientific understanding and ocean technology. A continuing
focus on ocean research through the FY 1989 -and later budgets can ensure that the
benefits of scientific advances in exploiting the ocean and its resources flow to the U.Si
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5. Evolution of the Interagency Program
Background - The Foundation
For the past several years, informally through the Ocean Principals group and formally
through various Committees of the Federal Coordinating Council on Science, Engineering, and
Technology (FCCSET), the relevant agencies have loosely coordinated programs that address
global ocean science. Long-range planning efforts for new programs and for facilities such as
ships and satellites have been developed by individual agencies and various advisory groups.
Notable among these are the NSF Long-Range Plan for Ocean Sciences, NASA's plan for
Oceanography from Space, the UNOLS and Navy ship replacement plan, and NOAA's Ocean
Climate Research Plan. All of these help set the stage for the coordinated, interagency U.S.
Global Ocean Science Program.
Interagency Approach
The Federal agencies have different, but related, needs for understanding the global ocean to
meet their mission responsibilities. No single agency, however, can marshaH all the
resources needed (people, dollars, and capital assets) to gain a comprehensive understanding
of the global ocean. If we are to effectively advance our knowledge, then we must do so in a
collaborative and cooperative arrangement. The U.S. ocean research establishment is a
unique and highly productive mix of universities, industry, federal agencies, and government
laboratories. All sectors have important roles in providing and exploiting new technology and
ensuring the availability of new scientific advances to the nation. Moreover, ocean research
is properly a major responsibility of the federal government. Ocean processes transcend
state and national boundaries, are too long-term for private sector investment, and are too
important to the nation's security and future economic strength to leave leadership to other
nations. The U.S. Global Ocean Science Program includes strong participation from all of the
federal agencies with major ocean science interest and responsibilities. Certain agencies such
as NOAA, NSF, NASA, Navy, DOE, and USGS are major participants in the Program, other
agencies such as EPA and Department of State anticipate collaboration and participation in
specific elements of the Program that relate to each of their missions and activities.
An Interdisciplinary and International Context
The strategy outlined here is consistent with the evolution of the IGBP to study global
environmental change. Fundamental to that program is the concept that no single part -
oceans, atmosphere, land and biota - can be understood adequately without study of the other
parts. For example"we know that the ocean influences the atmosphere and land, and that only
by studying these parts simultaneously can we fully understand the ocean itself. The
scientific community and the federal agencies have responded to the need for
interdisciplinary planning by developing new integrated programs. NSF has a new initiative
in Global Geosciences, NASA plans a program in Earth System Science, NOAA plans an
accelerated program in global climate change, and ONR has begun a series of interdisciplinary
research initiatives impacting global understanding. The U.S. Global Ocean Science Program
presented here builds on these programmatic themes to provide a context and ocean science
focus for these broad agency actions.
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6. Goal. Objectives, Components, and Coordination
Goal and Objectives
We have a new challenge to understand the global ocean, and we have a new national
opportunity to maintain world leadership role. Recognizing the challenge and opportunity and
with the firm foundation that has been developed, we can establish a sharp focus for the
interests and needs of all the major agencies involved. The purpose of the U.S. Global Ocean
Science Program is to provide a focus and overall context so that the total can be greater than
the sum of the parts. The overall goal of the Program has been arrived at by mutual
agreement of.the interagency group and is the following:
To describe and understand more fully the interactive physical, chemical,
geological, and biological processes within the global ocean and at the
ocean boundaries that contribute significantly to the regulation and
condition of the earth's global environment, and to understand the changes,
both natural and anthropogenic, in the ocean that contribute directly to the
health of the global environment.
The specific objectives of the Program derive directly from the overall goal and the
program rationale and are aimed at both science and resources:
To understand the physical, chemical, and biological processes at work within
the ocean and their effects on global weather and climate, and to assess the
changes caused by mankind in the global ocean.
With this global description and understanding, 'we can expect:
- To use the ocean more effectively as a source of food, energy, and mineral
resources with minimal adverse effects on the environment,
- To better assess and manage our coastal ocean, our Exclusive Economic Zone,
and future coastal development,
- To ensure the safety of vessels and life at sea,
- To protect national security interests, and
- To identify and control those human activities such as ceflain waste discharges
which will irreparably damage renewable resources.
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Program Strategy
In order to meet its goal and objectives, the U.S. Global Ocean Science Program uses a strategy of
identifying science and infrastructure components, each of which has a single unifying theme.
Agencies contribute to each component with individual agency programs and with complimentary
contributions to interagency programs. Identification of critical needs, gaps, and potential overlaps
is the responsibility of an interagency working group that provides an overview of the entire
program. This document is the first stage in that process.
Components of the Program
The science aspects of the U.S. Global Ocean Science Program are divided programmatically into five
science components which will have interlocking parts:
� Global Ocean Structure and Dynamics
� Global Climate: Atmosphere-Ocean Interactions
� Global Ecosystems and Productivity Processes
� Global Ocean Lithosphere and Geoprocesses
� Coastal Margins and Polar Oceans Processes
If we can achieve major advances in our understanding of each of these component areas, then we
will begin to have the understanding we need to make a major step towards our goal of describing
and understanding the ocean; its role in global environmental change; and the specific objectives
listed previously. However, it will not be possible to mount the associated science programs
without simultaneous improvement in the infrastructure to support these programs. In order to
fulfill the goal and hence to meet the objectives, we need global measurement systems in place; we
need communication networks that can deliver data as required to researchers and operational users
in government, private industry, and academia; and we need to develop and validate models that can
use the new global data sets. Thus we also identify the infrastructure components of the Program:
- Technology
- Facilities and Centers
- Data Management Systems
Support in these areas will ensure that we have the necessary instruments, that basic facilities. are
in place, and that new data sets can be handled efficiently. The science and infrastructure
components together with the coordinating mechanism make up the heart of the U.S. Global Ocean
Science Program. Below we describe the overall aims of each of the components, address the vital
issue of manpower needs, and identify the coordination mechanism. In the next section, we will
identify critical elements of each of these, and show 'how these can be met with on-going programs
and new proposals. The following diagram illustrates this approach to developing the interagency
plan.
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Science Components
Global Ocean Structure and Dynamics
This component must develop a quantitative description and understanding of the global
ocean with emphasis on relating ocean circulation to driving forces and boundary
conditions, developing and validating predictive models, understanding internal
dynamics and mass and energy transfers, and relating scales of motion and mixing
from small to large. The World Ocean Circulation Experiment (WOCE), sponsored by
the WCRP, is a key element here.
Global. Climate: Atmosphere-Ocean Interactions
This componen "t must develop a quantitative understanding of air-sea interactions with
emphasis on understanding the role of the ocean in global climate, determining the
transports of heat, momentum, energy, moisture, and chemical substances through
the interface, assessing climate-related feedbacks among ice, ocean, and atmosphere,
and understanding near-surface and deeper processes that affect biological and
chemical exchanges, abundances and distributions. The Tropical Ocean-Global
Atmosphere (TOGA) program, sponsored by the WCRP is a key element.
Global Ecosystems and Productivity Processes
This component must develop a quantitative understanding of ocean ecosystem
dynamics on a global scale, including biological productivity, recruitment processes,
and the full food web; and of the physical, chemical, and biological processes
important in affecting the origins, distributions, and variability of oceanic biological
and chemical species. The Global Ocean Flux Study (GOFS,) now being planned, is a
Key element. A new Global Ocean Ecosystem Dynamics (GOED) program will be
proposed here.
Global Ocean Lithosphere and Geoprocesses
This component must develop a quantitative understanding of the ocean lithosphere.
The emphasis is on determining geologic structure and on describing and
understanding geoprocesses ranging from the upper lithosphere, ridge crest, and
hydrothermal venting processes to those controlling the structure and shape of the
seafloor and continental margins. The program will aim to understand the influence of
these geoprocesses on the global ocean environment and the production of energy and
mineral resources.
Coastal Margins and Polar Oceans Processes
In order to understand global phenomena, this component must develop a quantitative
understanding of those critical processes that occur in coastal andpolar regions. The
emphasis is on the role of the coastal ocean in global ocean climate, in biological
productivity, in biogeochernical cycles, and in geological processes. The coastal
component of GOFS, under active development, is an important element. The component
includes consideration of the effect of high latitude processes (such as bottom water
formation) on global ocean circulation, on climate variability, on gas and chemical
exchange, and on renewable and non-renewable resources.
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Infrastructure Components
Technology
Here we look to new in-situ techniques and instruments, new supercomputers and
communication technologies, and new satellite-borne instrumentation. There have
been great strides in the past decade, but we need now to apply the technology on a
global scale. Examples of needs include development of "smart" CTDs, pop-up
drifters, "intelligent" collecting nets, automated systems for long-term data
collection, and new satellite instruments.
Facilities and Centers
Ocean science, as all U.S. science, suffers from a lack of adequate facilities ranging
from platforms (ships, moorings, island and coastal stations, satellites) to
laboratories to large specialized facilities. Special needs include modernizing the
federal and the academic fleet, providing access to modern physical, chemical, and
biological laboratories, and supporting special large facilities such as satellite
systems and accelerator mass spectrometers.
Data Management Systems
Traditional oceano graphic data systems have depended on individuals or individual
institutions for maintenance and support.-Today, with enormous amounts of new data
coming in from a variety of new instruments, and with much more likely from new
satellites that will come at the end of the decade, more formal arrangements are
required. This topic is one of much interest among the federal agencies; one very
successful management arrangement has been developed by NOAA's National
Oceanographic Data Center (NODC). This joint arrangement between NODC and one or
more oceanographic institutions has the advantage of providing expertise from both
sides in science and data; more such imaginative arrangements need to be considered.
15
�
Manpower Requirements
As we approach each of the initiatives in the US Global Ocean Science Program there is a
need to attract the research capability of the best students and scientists available.
Manpower is a critical requirement, and we must support innovative concepts to achieve
our technical goals. In order to attract the best students into earth sciences and ocean
sciences in particular, we need to support the development of exciting new educational
programs including field work for students at all levels. This is best done by the agencies
working together with the academic oceanographic community. Joint industry programs
that allow students real hands-on experience are also available. These issues need to be
more fully explored and an education initiative developed for early funding. An example is
the ONR program to apprize professors from leading undergraduate colleges and
universities of scientific opportunities in oceanography that are available to students.
Coordination
The U.S. Global Ocean Science Program will continue to be coordinated through an
interagency working group which will periodically review agency initiatives and
interagency programs in the context of this and other global planning efforts. The
interagency group will analyze and identify needs, critical elements, and gaps in cross
cutting analyses. Individual agency representatives on the group will be responsible for
integrating the needs of the U.S. Global Ocean Science Program into each year's budget
planning process.
Within the Federal Government, the interagency group will look to the Ocean Principals
and the FCCSET Committee on Earth Sciences for guidance. Input from the academic and
industrial communities would come through individual agency advisory committees, the
National Academy of Science and the National Academy of Engineering. Specific actions for
FY 1989 are identified in the next section of this plan. In addition, the interagency group
will be responsible for taking the long-term view of the Program's needs, and ensuring
that the right pieces are in place in each agency for the Program's long-term success.
The following section and diagram summarize the major components of this plan and their
integration.
16
�
.5 L mm_ M
U.S. Global Ocean Science Program: Components
Global Ocean Structure and Dynamics
To describe and understand the global ocean emphasising:
- Circulation, driving forces and boundary conditions
- Predictive models
- Internal dynamics, mass and energy transfers
Global Climate: Atmosphere-Ocean Interactions
To understand air-sea interactions emphasising:
� Role of the ocean in climate and hydrologic cycles
� Transports of heat, momentum, energy, moisture, and chemical substances
through the interface
� Climate-related feedbacks
� Chemical and biological exchanges and distributions
Global Ecosystems and Productivity Processes
To understand oceanic ecosystem dynamics on a global scale emphasising:
� Productivity, recruitment, food web
� Origin, distribution, variability of species
� Chemical and biological exchanges and distributions
Global Ocean Lithosphere and Geoprocesses
To understand the ocean lithosphere emphasising:
Geoprocesses of upper lithosphere
Influence on environment, mineral resource distribution
Coastal Margins and Polar Oceans Processes
To understand effects of coastal margin and polar oceans on:
� Global climate, circulation, and productivity
� Biogeochemical cycles, geological processes
� Renewable and non-renewable resources
Technology
To develop the necessary new jazsiW techniques and instruments emphasising:
- Measurements of large scale systems
- Potential real-time monitoring
Facilities and Centers
To provide capital infrastructure including:
� Platforms
� Laboratories
� Specialized measurement facilities such as satellite systems
Data Management Systems
To provide data handling schemes for global data sets including:
- New techniques for data management
- Data Networks linking institutions
- New joint Federal/University/Industry arrangements
17
�
U.S. Global Ocean Science Program: Components
cle
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and
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Global Ocean
Lithosphere
& Geoprocesses
18
�
7. Specific Agency Contributions and Required Actions
The Global Ocean Science Program involves coordinated activities by several agencies in
both the science and infrastructure components. As part of the planning for the Program,
the interagency group has looked carefully at on-going and proposed interagency and
agency'activities in each of the Program components to identify specific needs, critical
elements, and gaps, that have not yet been addressed. From these, specific FY 1989
requirements have been identified. Even with these required actions, however, not all the
gaps are filled. A summary of unfinished business is therefore also provided. This will be
a long-term program. For illustration of the continuing effort required, an assessment of
the current and recommended level of effort from FY 1986 through FY 1992 in,each of the
components has been developed to show the support that these components will need to
make the Program successful.
19
�
Global Ocean Structure and, Dynamics
In this component the Program requires a broad range of research and technology aimed at
describing the physics of global circulation. Studies in this component will interact: closely
with studies in the climate and ecosystem components, and will require infrastructure
support in technology (ocean instruments), facilities (operational and -research satellites,
accelerator mass spectrometer),. and data management (new joint institutes).
Critical Elements and Contributing Agencies
World Ocean Circulation. Experiment (NSF, NASA, NOAA, Navy)
Tropical Ocean-Global Atmosphere Program (NOAA, NSF, DOE)
Global Sea Level Measurement Network (NOAA, NSF, DOE)
Research Satellites: Altimeter and Scatterometer (NASA, NSF, Navy, NOAA)
Research on Global Circulation (NSF, NASA, NOAA, Navy, DOE)
Research on Mesoscale Circulation (Navy, NSF, NOAA)
Global Chemical Tracer Measurements (NSF, NOAA, DOE)
Bilateral and Multi-lateral Programs (DOS, technical agencies)
Gaps
Further efforts needed in:
Fully Global in-situ Sea Level Network
NROSS for flight of scatterometer and other instruments not yet approved
International management arrangements for WOCE, JGOFS
Research ships, data management
FY 89 Actions Required
NSF: Maintain Global Geosciences growth (including Global Circulation, Climate and
Productivity), advanced computing, data management
NASA: Maintain TOPEX, NSCAT (for flight on NROSS)
NOAA: Enhance large-scale ocean observing systems (including global sea level) and ocean
circulation studies related to global climate change
Navy: Ship initiative, modelling and mesoscale processes, NROSS approval
Projected Level of Effort
The timing for this component is largely determined by the flight schedules of satellites.
TOPEX/POSEIDON and NROSS are currently planned for 1991. There is a buildup to 1989,
followed by a gradual decline since the next generation of technology will be developed by that time.
Agency Programs
3.0 Interagency Programs
2.5
LU 2.0
1.5
(D 1.0
0.5
0. 0 0220
FY '86 FY '87 FY 188 FY 189 FY '90 FY '91 FY '92
20
�
Global Climate: Atmosphere-Ocean Interactions
In this component the Program requires a broad range of climate-related research including
the effects of air-sea exchange, ice interactions, the hydrologic cycle, and chemical and
biological processes that affect climate. This component interacts with the Global Ocean
Structure and Dynamics and the Global Ecosystem and Productivity Processes components,
and will require support from each of the infrastructure components. Examples of such
infrastructure are air-sea exchange instrument development, climate data management, and
operational weather satellites.
Critical Elements and Contributing Agen cies
Seasonal and Interannual Climate Research including Tropical Ocean-Global
Atmosphere Program (NOAA, NSF, DOE)
Trace Gases (Climate/Air Quality)(NOAA, NSF, DOE)
Arctic System Sciences (ARCSS)(NSF, Navy, NOAA, NASA)
Research on Air-Sea Exchange/Marine Meteorology (Navy, NSF, NOAA, DOE)
Research related to the satellite wind scatterometer (NASA, NSF, Navy)
Climate Modelling Diagnostics and Data Management (NOSS, NSF, NASA, Navy)
Bilateral and Multi-lateral Programs (DOS, technical agencies)
GV9
Further efforts needed in:
Sea Level in the Indian Ocean
NROSS (not yet approved)
Global Trace Gases Chemistry
Data Management for global climate studies
FY 89 Actions Required
NOAA: Maintain full TOGA program; accelerate work on global climate change including
trace gas studies, historical climate proxy studies, climate modelling and
diagostics, and data management
NSF: Maintain Global Geosciences growth (TOGA, WOCE, trace gases), advanced
computing, data networks
NASA: Maintain NSCAT support, data management
Navy: NROSS approval, modelling, ship initiatives, bio-physical interactions
Projected Level of Effort
This component is underway. TOGA began in 1985. Tropical studies will enter a new stage in
approximately 1991, when new global satellite data will be available for tropical winds and
ocean currents. The level of effort is already close to maximum, building slightly to 1989 with
the addition of initiatives such as paleoclimate studies after which it remains roughly constant.
3.0
2.5 El Agency Programs
LU Z.U
"6 1.5 El Interagency ProgramE
1.0
0.5 ON go
0.0 Wom MM MOM
FY '86 FY '87 FY '88 FY 189 FY 190 FY '91 FY '92
21
�
Global Ecosystems and Productivity Processes
In this component the Program requires, support of. a broad range of ecosystem research.
Because of the importance of ther physical climate system, this component must be carried
out in the context of the Global Ocean Structure and Dynamics and the Global Climate
components. This component will,;' require support from the Technology component for new
sampling and.analysis instruments;.
Critical Elements and Contributing Agencies
Global Ocean Flux Study (GOFS) (NSF, Navy, NOAA, DOE)
Global Ocean Ecosystem Dynamics program (NSF, Navy, NOAA)
Research related to satellite ocean color measurements (NASA, NSF, Navy, NOAA)
Physical/Biological interactions studies (Navy, NSF, NOAA)
Fish eries/Oceanography interactions (NOAA, NSF)
Bilateral and Multi-lateral Programs (DOS, technical agencies)
Further efforts needed in:
Satellite Ocean Color Instrument
NROSS (not yet approved)
Global Ocean Ecosystem Studies
New sampling techniques
FY 89 Actions Required
NSF: Maintain Global Geosciences growth (including JGOFS); Establish Global Ocean
Ecosystem Dynamics program
NASA: Support Sea-Wifs ocean color instrument for flight on Landsat-6
NOAA: Support fisheries related oceanographic research and expand global marine
ecosystem studies
Navy: Modelling, bio-physical interactions, increase in bio optics and particle dynamics.
NROSS approval
DOE: Expansion of C02 program to include biological interactions
Projected Level of Effort
This program is just beginning, and will depend strongly on the Global Ocean Structure and
Dynamics and Global Climate components for basic physical and chemical understanding. Major
funding begins in FY 1989 for field activities beginning in FY 1991 to coincide with the Global
Ocean Structure and Dynamics c6mpon.ent. Funding during the prior years is for process
studies and technology development aimed at better global sampling of biota and processes.
3.0 Agency Programs
2.5 Interagency Programs
LU 2.0
0 1.5
'Zi 1.0
(D
_J 0.5
0.01 1
FY '86 FY '87 FY '88 FY '89 FY 'go FY '91 FY '92
- MI.
22
�
Global Ocean Lithosphere and Geoprocesses
In this component, the Program requires a variety of measurements of the structure of the
sea floor and continental margins to enhance our understanding of the global geoprocesses
that control the solid,- but dynamic, earth. This component interacts primarily with the
Global Ocean Structure and Global Ecosystems components, through cross cutting interests
in the chemistry at ridge crests, the paleoclimate aspects of global climate, (since the
sediments record the history of global change), and programs in continental geology and
geophysics. Infrastructure needs include long-term bottom observatories and satellite
measurements of gravity and magnetic field.
Critical Elements and Contributing Agencies
Processes at plate boundaries and other active regions (NSF, USGS, NOAA, Navy, DOE)
Global network of seismometers (NSF, USGS, Navy)
Coastal Ocean geoprocesses (Navy, NSF, USGS, NOAA)
High Latitude Drilling (NSF, Navy, USGS)
Satellite measurements of Gravity and Magnetic Field (NASA, Navy, NOAA)
Bilateral and Multi-lateral Programs (DOS, technical agencies)
Gaps
Further efforts needed in:
Ridgecrest processes, back arc spreading and vent program
Ocean Bottom Seismometers
Arctic Drilling
Coastal Ocean Dynamics and Fluxes
Satellite missions for gravity and magnetic field
Morphology of the floor of the global ocean
FY 89 Actions Required
NSF: Maintain Growth of Global Geosciences Program (includes Ridgecrest Processes and
Vents Program)
Navy: Ship initiative, ULF/VLF, Increase in particle dynamics and ridge crest processes
DOE: Development of isotopic chemistry (young time markers)
NOAA: Expand studies of ridge crest processes, including the VENTS program
USGS: Multichannel seismic studies of the U.S. continental margin
Projected Level of Effort
This program, with major agency components such as the Ocean Drilling Program already well
underway, is at a relatively high level of effort. Major gaps include satellite measurements of
gravity and magnetic field and Arctic drilling. As critical interagency elements are developed,
broad support increases to develop and integrate different techniques.
3.0 Agency Progra .ms
2.5
0
Interagency Programs
2.o
1.5
-6 1.0
(D
0.5
0.0
FY '86 FY '87 FY '88 FY '89 FY '90 FY '91 FY '92
23
�
Coastal Margins and Polar Oceans Processes
This component of the Program addresses physical, chemical, biological, and geological
processes along coastal margins and in polar oceans. These areas provide key elements in
the transition between processes on land and the global ocean. Infrastructure issues include
satellite measurements in coastal oceans, computers, data management, and ships.
Critical Elements and Contributing Agencies
Coastal interactions with global ocean fluxes (NSF, Navy, USGS, NOAA, DOE)
Interactions of land and coastal ocean processes (NSF, NOAA, USGS, DOE)
Arctic ai r-sea-ice -biology interactions (Navy, NSF, NOAA)
Coastal erosion programs (USGS)
Satellite measurements in polar regions (NASA, NOAA, Navy, NSF)
Ice edge studies (NSF, Navy, NASA)
Coastal transition studies (Navy, USGS, NOAA)
Bilateral and Multi-lateral Programs (DOS, technical agencies)
Gaps
Further efforts needed in:
Coastal part of Global Ocean Flux Study
Global Scale Ocean and Margin Dynamics
Land/Sea Interface studies
Coastal vessels
Arctic System Science studies
Dedicated Ice programs
FY 89 Actions Required
NSF: Maintain Global Geosci 'ences growth, Coastal Ocean Dynamics and Fluxes (including
the coastal component of GOFS), Arctic system sciences, Land/Sea Interaction
USGS:Coastal erosion program
NOAA:Maintain coastal ocean and marine resource research and enhance research on
air-sea-ice biologic interactions and estuarine. science
DOE: Regional Marine Program, Shelf Edge Exchange Program (SEEP), California Basin
(CABS)
Navy: Ship Initiative, Increases in coastal and arctic sciences, Arctic oceanography
initiative
Projected Level of Effort
".Like the Global Ocean Lithosphere component, this program is largely agency-based at the
present time. Beginning in FY 1989, we look to increasing, parallel, support of interagency
programs. Projecting the total level of support including logistics is difficult beyond 1992.
Although global logistics requirements are less than for other components the diversity of
coastal and polar environments can still increase logistics costs.
3.0 Agency Programs
2.5
LLJ 2.0 Interagency Programs
0 .1.5
1.0
0.5
0.0
FY '86 FY '87 FY '88 FY '89 FY '90 FY '91 FY '92
24
�
Technology, Sensors and Sampling
The need for new technology ranging from sensor development to new sampling techniques is
evident all across the range of science components above. Specific items of technology are being
addressed as part of broader initiatives as noted below.
Critical Elements and Contributing Agencies
Global Ocean Structure: Large-scale measurement techniques (NSF, Navy, NOAA, NASA, DOE)
Global Climate: Air-Sea Interaction measurement techniques (NOAA, NSF, Navy, DOE, NASA)
Global Ocean Ecosystems: Biological Sampling techniques (Navy, NSF, NOAA, DOE)
Global Ocean Lithosphere: Cores, drilling, seismics, geochemistry (NSF, USGS, DOE)
Coastal Margins and Polar Oceans: Under-ice measurements, near-shore/wave zone
techniques, bottom dynamics measurement (Navy, NOAA, NSF, USGS, DOE)
Gaps
Further effort needed in:
Techniques to measure large-scale phenomena
Air-Sea Interaction packages
Biological sampling techniques
Under-ice and near-shore/wave zone techniques
Long-term, real-time, in-situ monitoring techniques
FY 89 Actions Required
NSF: Global Geosciences Instrumentation: large-scale techniques, air-sea interaction,
biological sampling
NOAA: New water mass tracer techniques .(e.g. freon); large-scale ocean observing
techniques; and air-sea interaction technology
USGS: Coastal instrumentation as part of Coastal Erosion program
DOE: New and improved isotopic tracer systems; Biological sampling
Navy: Instumentation/sensor development incentive, improved Arctic sensors, bio
optical/acoustical sensors, acoustic tomography
Projected Level of Effort
A steadily growing level of effort in support of global ocean programs is projected. Reflecting
the costs of instrument development, the level of effort is an order of magnitude less than those
of the field programs.
Agency Programs
3.0 Interagency ProgramE
2.5
M 2.0
0 1.5
1.0
W
0.5
0.01
FY '86 FY '87 FY '88 FY '89 FY 'go FY '91 FY '92
25
�
Facilities and Cent6rs for Global Ocean Sciencg
New facilities and Centers are important for the Global Ocean Science Program. Without a
global reach, our shipboard capability cannot produce the scale of measurements we need.
Without satellites, we cannot produce the global view essential for the program. Without
advanced computing, -there will be no way to handle the new data sets- and to make the
physically correct models essential to understanding interactions and predicting future
ocean behavior. Finally, we need major laboratory facilities for measurement and
calibration of samples and instruments.
Critical Elements and Contributing Agencies
A Global Fleet: operation, modernization, construction of research ships (NSF, Navy,
NOAA, USCG)
Satellites: Research and Operational (NASA, NOAA, Navy)
Computers: Supercomputing capabilities and Links (NSF, NOAA, Navy, DOE)
Major Laboratory Facilities: For example, the Accelerator Mass Spectrometer (AMS)
for 14C determinations, Natural Synchotron Light Source (NSF, DOE)
GVs
Further efforts needed in:
Satellite Ocean Color facility
NROSS capability
New Ship Construction
Supercomputer capabilities and links
FY 89 Actions Required
NSF: Advanced scientific computing capability, AMS, Research vessel modernization
Navy: Research vessel construction and modernization; NROSS approval
NASA: Sea-Wifs Ocean Color satellite instrument for Landsat-6, maintain TOPEX, NSCAT
NOAA; Advanced computing capabilities; research vessel modernization; specialized
facilities and research centers (NURP, Sea Grant program)
DOE: Super computer links
Projected Level of Effort
Because of the heavy demand of ocean sciences for facilities, the required support level is high.
To meet the needs of developing programs and large field efforts beginning in the early 1990s,
this component builds to a steady-state level by 1990. After that funds are needed largely for
replacement of existing facilities. Shared use of facilities by the U. S. and othercountries will
relieve the load on the U.S., hence the slight decrease in 1991 and 1992.
Agency Programs
E.9 Interagency Programs
3.0
2.5
0
Z:=
LU 2.o
16 1.5
-6 1.0
(D
0.5
0.0
FY '86 FY '87 IFY '88 FY '89 FY '90 FY '91 FY '92
26
�
Data Management Systems
New techniques for collecting global data require management systems to make that data
available in usable form to researchers and operational users. Both new satellite missions
(U.S. and international) and in-situ instruments will yield large quantities of global data-
that must be processed, archived, and accessible. We need to upgrade our national data
centers, to provide for joint university and/or industry links with government agencies,
and to establish networks that link data centers, research institutions, and supercomputing
centers. A new interagency committee on data management chaired by NOAA will provide
coordination for data management for earth sciences in general.
Critical Elements and Contributing Agencies
Research satellite data management systems (NASA, NSF)
Operational satellite data management systems (NOAA, Navy)
In-situ data management systems (NOAA, NSF, Navy, DOE)
National Data Centers/Interaction with users (NOAA, NASA,Navy)
Database management system for ocean sciences (Navy, NOAA)
GRps
Further efforts needed in:
Interagency data programs
Joint Govern me nt/U niversity/I ndustry data arrangements
Network development
Database management systems
International Links
FY 89'Actions Required
NSF: Global Geosciences (data management)
NOAA. Data management for global climate change studies; international data exchange;
general improvements to NOAA-wide data management capabilities. including systems
upgrades and quality control
Navy: Database management system
NASA: Maintain support for data and information systems; international data exchange
USGS: Geonet
DOE: C02 data management
Projected Level of Effort
This is an effort that will continually grow and be distributed roughly equally between agency
and interagency programs. The level of effort generally reflects the combination of rapidly
increasing need with a technology that is becoming more efficient and cost-effective.
3.0 Agency Programs
2.5
0 Interagency Programs
2.0
0 1.5
1.0
0.5
0.0
FY '86 FY '87 FY '88 FY 189 FY 190 FY '91 FY '92
27
�
Summary of Specific FY 1989 Required Actions
in summary, we list the FY 1.989 required actions that are identified as crucial by the Global
Ocean Science Program.
NSF: Maintain Global Geosciences Growth
Advanced Scientific Computing
Ship Modernization
Ocean Instrumentation
Land/Sea Interaction
Coastal Ocean Dynamics and Fluxes
Artic Systems Science
NOAA: Large-scale ocean observing system, including global sea level
Global climate prediction including TOGA, ocean circulation trace gas and
historical proxy studies, satellite applications; climate modelling,
diagnostics and data management
Global marine ecosystems and fisheries-oceanography studies
Advanced computing capabilities
Research vessel modernization
Data management upgrades, including data management capabilities for global
climate studies
NASA: Sea-Wifs Color Scanner for Landsat-6, Maintain TOPEX,.NSCAT
Navy- NROSS approval
Ship Initiative
Ocean Instrumentation
Compute rs/Mode [ling
Database Management System
USGS: Geonet data system
Coastal Erosion Initiative
Multi-channel seismic studies, of the continental margin
DOE: Expansion of C02/Biology/Ocean Interactions Program
Development of Isotopic Tracer System
Shelf Edge Exchange Program Expansion
Supercomputer Network
Biologic Sampling Instrumentation
DOS: Strengthen and develop new bilateral and multilateral programs (in cooperation
with the technical agencies)
28
�
Level of Effort Summaries
Science and Infrastructure
The following table il lustrates the estimated level of effort for the science components and
infrastructure components and the relative agency and interagency contributions. In the
case of science, there is a rapid growth (by roughly a factor of 2) to FY 1989, and then a
relatively level activity. This reflects a build-up of field programs that will culminate in
the early 1990s simultaneously with the flight of satellite missions planned for that period.
The infrastructure programs show a similar structure, with some decrease after FY 1990
reflecting the fact that much of the necessary infrastructure will be in place by then.
29
�
06
Total GOSP Level of Effort Total GOSP Level of Effort
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The Unfinished Agenda
This plan for the U.S. Global Ocean Science Program is the beginning of a long-term
effort. Not all the issues can be addressed immediately. There are unfinished agenda items.
Prime among these are international cooperation and site and data access, and recruitment
of new scientists into the field.
We have emphasized the global aspect of ocean science and the need to pool resources
between the U.S. and other countries. Therefore we must cooperate in international
programs with oceanographic communities of other nations; several such international
programs have been discussed.
With the expansion of exclusive economic zones to cover much of the global ocean, we need
access to foreign waters. In all global programs, there is a need to make measurements in
waters that may be claimed by a particular country. The best way to make such
arrangements is to involve fully the scientists of the country in the program. We are
working hard to do this. For example, in the Ocean Drilling Program which is currently
circling the world, scientists from nations near the drilling operations are regularly
brought on board for joint projects. Even with these arrangements, however, clearances
are often denied. This problem is becoming worse, and we need new ways of addressing it.
We also need to address, at the earliest educational levels, the development of the next
cadre of scientists into the field. These programs offer a splendid opportunity for young
people to enter the field of science. As was stated at the very beginning of the report, an
educated human resource base is an overall rationale and requirement for the U.S. Global
Ocean Science Program over the long-term. In order to attract the best students into earth
sciences in general and ocean sciences in particular, we need to support the development of
exciting new educational programs including field work for students at all levels.
A Final Note
Ocean Science, perhaps more than any other, is global and international in the full sense of
the word. Our arena is international, our scientific colleagues are international, and we
work with many governments to collect and study the processes that shape our
environment. We have learned the ways of many different kinds of, organizations, ranging
from those under UNESCO to the non-governmental bodies of the International Council of
Scientific Unions, and we have worked directly with bilateral arrangements. We are now
looking to new programs and new facilities that will allow a new understanding of this
global resource. The U.S. Global Ocean Science Program can help put all this together.
31
�
Appendix A - Acknowledgements
The Working Group acknowledges helpful imputs and comments from many members of the
U.S., oceanographic community. Joint Oceanographic Institutions Incorporated provided
staff support for the work of the group and the development and production of the report.
32
�
Appendix B
Attendees, Reston Workshop on Ocean Research Priorities
J. Baker, Joint Oceanographic Institutions Incorporated
J. Carey, National Oceanic and Atmospheric Administration
R. Corell, University of New Hampshire
F. Eden, Joint Oceanographic Institutions Incorporated
E. Frieman, Scripps Institution of Oceanography
G. Gross, National Science Foundation
G. Hill, United States Geological Society
M. Katsouros, National Academy of Sciences
J. Kermond, National Association of State Universities and Land Grant Colleges
A. Maxwell, University of Texas at Austin
W. Merrell, National Science Foundation
J. McCarthy, Harvard University
W. McCloskey, Office of Naval Research
T. Offield, United'States Geological Survey
J. Orcutt, Scripps Institution of Oceanography
N. Ostenso, National Oceanic and Atmospheric Administration
J. Perry, National Academy of Sciences
D. Spencer, Woods Hole Oceanographic Institution
S. Wilson, National Aeronautics and Space Administration
Additional Reviewers of Reporl
D. Boesch, Louisiana Universities Marine Consortium
F. Spiess, Scripps Institution of Oceanography
W. Munk, Scripps Institution of Oceanography
33
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Appendix C
Members U.S. Global Ocean Science Program
Agency Member
Department of Commerce (NOAA) Michael Hall, Alan Thomas
Department of Defense (ONR) Thomas Spence, David Evans
Department of Defense (OCNAV) Robert Feden
Department of Energy Helen McCammon
Department of the Interior David Barna
Department of the Interior (USGS) Gary Hill
Department of State William Erb, William Sullivan
Department of Transportation (U.S. Maritime Admin.) William Creelman
Department of Transportation (Ice Operations Division) Richard Hayes
Environmental Protection Agency Peter Jutro
National Aeronautics and Space Administration Stanley Wilson
National Science Foundation Grant Gross
Office of Science and Technology Policy Robert Chapman
Chairman Robert Corell
34
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Appendix-13 - Glossary
AMS - Accelerator Mass Spectrometer
ARCSS - Arctic Systems Science
AVHRR - Advanced Very High Resolution Radiometer
CAC - Climate Analysis Center
CAMP - Circum Atlantic Mapping Program
CMAN - Coastal Marine Automated Network
CPMP - Circurn Pacific Mapping Program
DARPANet - Defense Advanced Research Project Agency Network
DMSP - Defense Meteorological Satellite Program
EEZ - Exculsive Economic Zone
EROS - Earth Resources Observation Systems
ERS-1 - European Remote Sensing Satellite No. 1-
FCCSET - Federal Coordinating Council on Science, Engineering and Technology
FNOC - Fleet Numerical Oceanographic Center
GEDIP - Global Environmental Data Information Program
GEONEt - Geological Survey Network
GEOSAT - Navy's Geodetic Satellite Mission
GFDL - Geophysical Fluid Dynamics Laboratory
G & G Archive - Geolgical and Geophysical Archive
GLORIA - Sidescan Sonar System
GLOSS - Global Ocean sea Level System
GOES - Geostationary Operational Environmental Satellite
GOFS - Global Ocean Flux Study
GRM - Geopotential Research Mission
GSGP - Global Sedimentary Geology Program
GSP - Greenland Sea Project
HEBIBLE - High Energy Benthic Boundary Layer Experiment
IGIBP - International Geosphere-Biosphere Program
IGCP - International Geological Correlation Program
IGOSS - Integrated Global Ocean Services System
ILP - International Lithosphere Program
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LIMEX - Laborador Ice Margin Experiment
LOBO - Longterm Ocean bottom Observations
MIZEX - Marginal Ice Zone Experiment
MPBL - Marine Planetary Boundary Layer
NCAR - National Center for Atmospheric Research
NGWLG - Next Generation Water Level Gauge
NMC - National Meteorological Center
NNODDS - Navy/NOAA Ocean Data Distribution System
NODC - National Ocean Data Center
NODS - NASA Ocean Data System
NOMSS - National Oceanic and Meteoric. Support System
NSCAT - NASA Scatterometer for flight on NROSS
NROSS - Navy Remote Ocean Sensing Satellite
NURP - National Undersea Research Program
OPC - Ocean Products Center
OTS/IWP - Ocean Turbulence Surface/internal Wave Processes
PIPOR - Program of International Polar Ocean Research
POES - Polar Operational Environmental Satellite
SCOR - Scientific Committee on Oceanic Research
SEAS - Shipboard Environmental Data Acquisition System
Sea-WiFS - Wide-field sensor (color scanner) flight on Landsat-6
SPAN - Space Physics Analysis Network
STRESS - Shelf Transportation Experiment: Slopes and Shelves
SYNOPS - Synoptic Ocean Prediction
TOGA - Tropical Ocean Global Atmospheric Program
TOPEX - Ocean Topography Experiment
UNIDATA - University Data Network
UNOLS -University National Oceanographic Laboratory System
VENTS - Vents-Ocean Ridge Crest Program
WCRP -World Climate Research Program
WOCE - World Ocean Circulation Experiment
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Appendix E - Bibliography
A Program for In ternational Polar Ocean Research (PIPOR), PIPOR Science Working
Group Report, European Space Agency, ESA SP-1074, September, 1985.
A Strategy for a National Ocean Science Program: Understanding the Global Ocean, Report
to the Ocean Principals Group of a Workshop held in Reston, VA, November,1986.
Changing Climate and the Oceans, Oceanus Magazine, special issue, Vol. 29, no. 4, winter
1986/87, Woods Hole Oceanographic Institution.
Continental Margins - Geological and Geophysical Research Needs and Problems, National
Academy of Sciences,'1979.
Earth System Sciences Overview: a Program for Global Change, NASA Earth System
Science Committee, (appointed by NASA Advisory Council), F. Bretherton, chairman.
May, 1986.
FY 1988 Global Geosciences Program, National Science Foundation, Directorate for
Geosciences and the Directorate for Biological, Behavioral, and Social Sciences, July
1987.
Global Change in the Geosphere-Biosphere, Initial Priorities for an lGBP, U.S. Committee
fo( an IGBP, Jack Eddy, chairman. National Academy Press, 1986.
Global Ocean Flux Study: Proceedings of a Workshop, National Academy Press, Washington,
D.C., 1984.
Greenland Sea Project: An International Plan of the Arctic Ocean Sciences Board, National
Academy Press,1987.
Marine Minerals: Exploring Our New Ocean Frontier, U.S. Congress, Office of Technology
Assessment, OTA-0-342, U.S. Government Printing Office, July, 1987.
Oceanography From Space: A Research Strategy for the Decade 1985-1995. Part 1. Joint
Oceanographic Institutions Incorporated, July, 1984.
Oceanography From Space: A Research Strategy for the Decade 1985-1995. Part 2:
Proposed Measurements and Missions, Joint Oceanographic Institutions Incorporated,
July, 1984.
Opportunities in the Geologic Sciences, Board of Earth Sciences, National Academy Press,
1983.
Report of the Conference on Scientific Ocean Drilling, Joint Oceanographic Institutions for
Deep Earth Sampling (JOIDES), November 16-18, 1981.
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Report of the Conference on Scientific Ocean Drilling, Jo int Oceanographic Institutions for
Deep Earth Sampling (JOIDES), July 6-8, 1987 (in press).
Scientific Plan for the World Ocean Circulation Experiment, World Climate Research
Program, World Meteorological Organization, Geneva, 1986.
Scientific Plan for the World, Climate Research Programme, World Climate Research
Programme (WCRP) Publications Series No. 2, September, 1984.
System Concept for Wide- Fie Id-of-View Observations of Ocean Phenomena From Space,
Report of the Joint EOSAT/NASA SeaWiFS Working Group, August, 1987.
The International Geosphere-Biosphere Programme: A Study of Global Change, ICSU Ad Hoc
Group on Global Change, August, 1986.
The Joint Global Ocean Flux Study; Proceedings of a Meeting of the ICSU Scientific
Committee for Oceanic Research Meeting, 17-19 February, 1987.
The Mid Oceanic Ridge - A Dynamical Global System: Proceedings of a Workshop, Ocean
Studies Board, National Academy Press (in press).
The Polar Regions and Climatic Change, Polar Research Board, National Academy Press,
1984.
Tropical Oceans/Global Atmosphere: An International Scientific Plan, World. Climate
Research Program, World Meteorological Organization, Geneva, 1985.
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