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OCR Page 1 of 2Originally Processed With FOIA(s):
FOIA Number:
1998-0004-F[1]; 2005-0336-F
S
FOIA
MARKER
This is not a textual record. This is used as an
administrative marker by the George Bush Presidential
Library Staff.
Record Group/Collection:
George H.W. Bush Presidential Records
Collection/Office of Origin: Chief of Staff, White House Office of
Series:
Sununu, John, Files
Subseries:
White House Offices Files
OA/ID Number:
29183
Folder ID Number:
29183-005
Folder Title:
Science and Technology (1989) [3]: Bromley
Stack:
Row:
Section:
Shelf:
Position:
G
15
25
5
7
Withdrawal/Redaction Sheet
(George Bush Library)
Doc. No. / Type
Subject/Title
Date
Restriction
Classification
01. Note
From D. Allan Bromley to John Sununu
9/13/89
P-5
Re: NASP Funding (4 pp.)
02. Memo
From D. Allan Bromley to John Sununu
9/6/89
(b)(6)
Re: Oceans and International Environmental and Scientific Affairs
Nominee (1 pp.)
03. Memo
From D. Allan Bromley to POTUS
8/24/89
P-5
Re: Your Forthcoming Meeting w/PM Brian Mulroney of Canada
[2 copies] (2 pp.)
04. Memo
From D. Allan Bromley to POTUS
8/24/89
Re: Visit of Japanese PM [2 copies] (2 pp.)
05. Memo
From D. Allan Bromley to POTUS
8/24/89
(b)(6)
Re: National Science Board Memberships [2 copies] (2 pp.)
06. Memo
From D. Allan Bromley to POTUS
8/28/89
P
Re: Annual Science Counselor's Conference (1 pp.)
07. Memo
From D. Allan Bromley to POTUS
8/31/89
P-5
Re: Background Information on the Superconducting Super
Collider [2 copies] (16 pp.)
Page 1 of 2
Collection:
Record Group:
Bush Presidential Records
Office:
Chief of Staff to the President, Office of the
Series:
Sununu, John, Files
Subseries:
White House Offices File
WHORM Cat.:
File Location:
Science and Technology (1989) [3]: Bromley
Pinksheet Number: KO0526
OA/ID Number:
29183-005
Date Closed:
12/1/2004
FOIA/Sys Case #:
1998-0004-F[1]
Re-review Case #:
2005-0426-S
P-2/P-5 Review Case #:
Withdrawal/Redaction Sheet
(George Bush Library)
Doc. No. / Type
Subject/Title
Date
Restriction
Classification
08. Memo
From William Roper to John Sununu
9/1/89
P-5
Re: Status of the Americans with Disabilities Act (3 pp.)
Page 2 of 2
Collection:
Record Group:
Bush Presidential Records
Office:
Chief of Staff to the President, Office of the
Series:
Sununu, John, Files
Subseries:
White House Offices File
WHORM Cat.:
File Location:
Science and Technology (1989) [3]: Bromley
Pinksheet Number:
KO0526
OA/ID Number:
29183-005
Date Closed:
12/1/2004
FOIA/Sys Case #:
1998-0004-F[1]
Re-review Case #:
2005-0426-S
P-2/P-5 Review Case #:
THE WHITE HOUSE
WASHINGTON
John Sunnnu
Septiz,1989.
Haemth joughannest
your questions re Exxon oil
quilid in Alaska.
Summary aaswers are
a) several years will be low taxicity fn
b) Spice will nathe visible
after 2 to 3 years
c) Small quantities jotelectable
oil could person in sheltered
bays fn 20 years or more.
Allan
SEP 13 '89 0:23 LAB OSHA
PAGE. 02
1. Of the oil now left on the shoreline, how long will it remain?
The persistence of oil on the shoreline of Prince William Sound, the
Gulf of Alaska, and Kodiak will be governed by a variety of
considerations. Small quantities of detectable oil could remain in
sheltered, low-energy bays for a period of twenty years or more
(Research Planning Institute 1979). This was evidenced by the
METULA spill in Tierra Del Fuego and the ARROW spill in Chedabucto
Bay, Nova Scotia. (Owens 1971; Hann 1975; Blount 1978). Oil
deposited on high- energy, finer-grain beaches will be removed very
quickly - within 12 months. While there is a wide range of
shoreline types between these two extremes, the majority of the
shoreline affected by the EXXON VALDEZ spill would be classified as
moderate to high energy with a relatively short persistence of
surface oil.
2. How long will the oil be toxic to biota?
The toxicity of Prudhoe Bay Crude (PBC) is attributable to two broad
categories of petroleum hydrocarbons: low molecular-weight
aromatic compounds such as benzene and the middle-to-high
molecular weight aromatics such as the naphthalene series and
phenatharenes. The low-molecular weight compounds volatilized
very quickly and did not remain more than a few days after the spill.
In fact, none of these very toxic, very volatile compounds have been
detected in samples of oil from the contaminated shoreline. (Jim
Payne, SAIC, personal communication.)
However, studies by Andersen et.al. (1985) have shown medium-
term toxicity for Alaskan species (both juvenile and adult life stages)
associated with the medium-weight aromatics. This study is quite
appropriate for application in the Exxon Valdez spill because the
investigators tested PBC that had been fractionated to represent
fresh, moderately weathered, and heavily weathered oil. The
moderately weathered oil showed chronic toxicities that would be of
concern. But the heavily weathered fraction had essentially no
toxicity.
In late August, samples were collected from a shoreline in Prince
William Sound that had been heavily oiled but not yet treated. The
samples were from the surface and subsurface. The surface samples
showed a high degree of microbial degradation of the naphthalene
series, but only a small amount of the C3 naphthalenes remained.
SEP 13 '89 0:23 LAB OSHA
PAGE. 03
3
Therefore, the surface oil has very low toxicity; the only toxicity
remaining would be due to the phenathrenes but we expect to see
continued degradation, probably within the next year. We already
see significant losses of C1 phenathrenes in the surface samples. We
see evidence of the relatively low toxicity of the surface oil in that
there are large numbers of living organisms in the lower intertidal
zones of beaches that have not been washed.
However, the subsurface samples showed that most of the C3
naphthalenes remained, and the phenanthrenes showed almost no
weathering. The subsurface oil still has a moderate level of toxicity,
and the rates of weathering and detoxification by biodegradation will
be much slower. The oil that is not removed by winter storms will
probably take several years to be rendered non-toxic. But, the
subsurface oil is not readily available to aquatic organisms so there is
not much of a pathway of exposure or uptake. The subsurface oil is
not very mobile and will become increasingly less mobile over time.
The naphthalenes are known to leach out from beach sediments for a
period of up to one-half year. (Jim Payne, SAIC, personal
communication). But the high molecular weight aromatics have
essentially no water solubility and so they cannot enter the
biosphere if they remain buried in the beach sediments.
3. How long will the oil be visible?
Except in isolated conditions (for example, oil stranded above the
high tide line or oil which has been covered with sediment and then
re-exposed), visible oil should not be detectable after two to three
years, as evidenced by the AMOCO CADIZ and URQUIOLA spills
(Gundlach and Hayes 1977; Research Planning Institute 1978a;
Research Planning Institute 1978b). There could be leaching from
subsurface oil next summer, with a few scattered tarballs (Blumer et
al. 1973) remaining on the ocean surface.
4. Is there a way to clean the oil or make it non-toxic?
Continued efforts to enhance natural biological processes appears to
be the only effective method to deal with the oiling situation that
will remain next spring. Increasing oil viscosity is rendering hot,
high pressure water flushing increasingly less effective in dealing
with the current oiling situation. By spring, oil that remains deeply
SEP 13 '89 0:24 LAB OSHA
PAGE.04
PAGE.04
22:55 68. 21 SEP
4
buried in the sediments will be unreachable unless heavy equipment
is employed to uncover the surface sediments. We believe the
disruption of biological activity on the surface by this approach
would outway any benefit derived by removing buried oil.
5. How well do natural forces help cleanup the shoreline?
The extent to which natural processes effectively clean oil from the
shoreline depends a great deal on the degree of exposure of the
shoreline to wave activity. The more exposed sections of coast will
be quickly and completely cleaned: high wave action that thoroughly
tumbles shoreline sediments is clearly the most effective cleaning
mechanism.
Oil deeply buried in the interstitial spaces between sediment
particles will not be affected by continuous wave tumbling, but tidal
and groundwater flushing, coupled with microbial weathering, will
still be effective on a longer time scale. Studies to date have
indicated that natural microbial degradation is actively degrading the
oil at rates much greater than expected in the cold water
environment. However is not known how well microbial degradation
will be effective in dealing with the waxy and asphaltic fractions of
the oil.
6. What are the natural forces that help cleanup the shoreline?
Natural mechanical and biological weathering processes serve to
disperse and detoxify the oil on the shoreline over time. The
primary mechanical process is wave action and the associated
summer/winter cycle of sediment transport to and from the
shoreline. The eventual fate of the oil, however, is primarily
controlled by the rate that biological weathering results in the
breakdown and oxidation of the oil by specific bacteria.
BIBLIOGRAPHY
Anderson, J., 1985, Toxicity of PBC Oil On Alaskan Species; Proc. 1985
Oil Spill Conference, Am. Petrol. Inst., Washington, DC.
Blount, A. 1978. Two years after the Metula oil spill, Strait of
Magellan, Chile oil interaction with coastal environments. Columbia,
SEP 13 '89 0:24 LAB OSHA
PAGE.05
5039305
00.00 00. 01 ...
5
South Carolina: Coastal Research Division. Dept. of Geology,
University of South Carolina. Tech. Rept. No. 16-CRD. 214pp.
Blumer, M., M. Ehrhardt, and J. H. Jones. 1973. The environmental
fate of stranded crude oil. Deep-Sea Research 20(3): 239-259.
Gundlach, E. R. and M. O. Hayes. 1977. The Urquiola oil spill, La
Coruna, Spain; case history and discussion of methods of control and
clean-up. Mar. Pollut. Bull 8(6): 132-136.
Hann, R. W., Jr. 1975. Follow-up field survey of the oil pollution
from the tanker Metula. College Station, Texas: Civil Engineering
Department, Texas A&M University. Report to U.S. Coast Guard.
Keizer, P. D., T. P. Ahern, J. Dale, and J. H. Vandermeulen. 1978.
Residues of Bunker C in Chedabucto Bay, Nova Scotia, 6 years after
the Arrow spill. J. Fish. Res. Board Canada. vol. 35(5), pp. 528-535.
Owens, E. H. 1971. The restoration of beaches contaminated by oil in
Chedabucto Bay, Nova Scotia. Ottawa: Dept. of Energy, Mines and
Resources, Mar. Sci. Branch. Manuscr. Rept. Series No. 19. 78pp.
Research Planning Institute. 1978a. Investigations of beach
processes. In: The Amoco Cadiz Oil Spill, A Preliminary Scientific
Report (W. N. Hess, ed.). Boulder, Colorado: NOAA/EPA Special
Report. pp. 85-197.
Research Planning Institute. 1978b. The Amoco Cadiz spill, third
follow-up survey of oil impact on the shoreline, July, 1978. Boulder,
Colorado: NOAA Environmental Research Laboratories. 67pp.
Research Planning Institute. 1979. Coastal Processes Field Manual
for Oil Spill Assessment. Boulder, Colorado: NOAA Office of Marine
Pollution Assessment. 172pp.
SEP 13 '89 0:25 LAB OSHA
PAGE. 06
for Dr. D.A. Bromley
6
Further Background Information on Oil Spill Cleanup
The effects of CLEANUP ACTIVITIES must also be considered in addition
to the effects of the oil spill.
The following is a summary of the effects of different kinds of
oil spill cleanup:
A work group on oil spill cleanup at a 1982 work-
shop divided cleanup methods into several generic
types, among them: natural cleansing, mechanical
removal, manual removal, sorbents, chemical disper-
sants, sinking agents, and burning. Four general
categories of ecological impacts that may result from
use of these cleanup methods were also identified:
1. Potential for substrate or habitat disruption.
Some cleanup methods disrupt the integrity or
change the quality of a substrate, and, therefore,
the associated organisms. Examples include the
use of heavy equipment on certain beach types
or high pressure flushing in marshes.
2. Potential for loss or disruption of community
structure,
Some cleanup techniques remove organisms
from the habitat that may have survived the initial
oiling, e.g., removal of organisms from a rocky in-
tertidal habitat through steam cleaning or high
pressure flushing.
3. Potential for increased likelihood of oil uptake.
This occurs when the cleanup technique exposes
organisms to additional oil; e.g., techniques which
increase penetration of oil into sediments, or in-
crease its availability to organisms.
4. Potential for increased oil re-entry to the
environment.
This may occur with cleanup techniques which
(a) reduce the viscosity of the oil (e.g., steam clean-
ing), (b) disturb an oiled substrate to remobilize
oil, (e.g., flushing without proper recovery of free
oil), or (c) incorporate oil into sediments where,
as erosion occurs, oil will be reintroduced into the
system.
from:
"Oil Spill Response and Ecological Impacts 15 Years Beyond Santa Barbara"
Marine Technology Society Journal, 18 (3), 43 - - 50. 1984
by Dr. June Lindstedt-Siva
(=
c..11
SEP 13 '89 0:25 LAB OSHA
PAGE. 07
7
More Background on effects of cleanup activities
Note the effects of steam cleaning on the environment
Steam Cleaning. Steam cleaning uses steam or high
temperature water under pressure to remove oil from
solid surfaces such as rocky shorelines, seawalls and
jetties.¹⁴ This technique effectively removes even high
viscosity oils, but it also removes any living organisms.
Complete removal of organisms means that the suc-
cessful process of establishing a rocky intertidal com-
munity must begin again, a process that may take 5-15
years.14 In addition, steam cleaning may increase
penetration of oil into surrounding sediments.²⁰
High Pressure Flushing. This technique (also called
hydroblasting) uses high pressure (greater than 100 psi)
water streams to remove oil from the substrate. Flushed
oil is then channeled to a recovery area.⁴ The method
is applicable to jetties, sea walls, piers, pilings and rocky
shores where it can effectively remove oil, However,
high pressure flushing also removes organisms. It is
particularly damaging to low energy, high productivity
shorelines or other habitats where recovery is slow.
Further impacts may result from increased oil penetra-
tion into sediments or from transport of equipment
over the oiled and adjacent habitats. This method was
used in a freshwater marsh with disastrous
consequences.20
from Siva (previous page reference)
THE WHITE HOUSE
WASHINGTON
John Sunamu
Septiz,1989.
Haemth youghannment
your questions re Exxon oil
fulld in Alaska.
Summary aaswers are
a) several years will be low toxicity fn
b) Spice will nathe visible
after 210 3 years
c) Small quantities jotetectable
oil could person in Sheltered
bays fn 20 years or more.
Allan
SEP 13 '89 0:23 LAB OSHA
PAGE. 02
1. Of the oil now left on the shoreline, how long will it remain?
The persistence of oil on the shoreline of Prince William Sound, the
Gulf of Alaska, and Kodiak will be governed by a variety of
considerations. Small quantities of detectable oil could remain in
sheltered, low-energy bays for a period of twenty years or more
(Research Planning Institute 1979). This was evidenced by the
METULA spill in Tierra Del Fuego and the ARROW spill in Chedabucto
Bay, Nova Scotia. (Owens 1971; Hann 1975; Blount 1978). Oil
deposited on high- energy, finer-grain beaches will be removed very
quickly within 12 months. While there is a wide range of
shoreline types between these two extremes, the majority of the
shoreline affected by the EXXON VALDEZ spill would be classified as
moderate to high energy with a relatively short persistence of
surface oil.
2. How long will the oil be toxic to biota?
The toxicity of Prudhoe Bay Crude (PBC) is attributable to two broad
categories of petroleum hydrocarbons: low molecular-weight
aromatic compounds such as benzene and the middle-to-high
molecular weight aromatics such as the naphthalene series and
phenatharenes. The low-molecular weight compounds volatilized
very quickly and did not remain more than a few days after the spill.
In fact, none of these very toxic, very volatile compounds have been
detected in samples of oil from the contaminated shoreline. (Jim
Payne, SAIC, personal communication.)
However, studies by Andersen et.al. (1985) have shown medium-
term toxicity for Alaskan species (both juvenile and adult life stages)
associated with the medium-weight aromatics. This study is quite
appropriate for application in the Exxon Valdez spill because the
investigators tested PBC that had been fractionated to represent
fresh, moderately weathered, and heavily weathered oil. The
moderately weathered oil showed chronic toxicities that would be of
concern. But the heavily weathered fraction had essentially no
toxicity.
In late August, samples were collected from a shoreline in Prince
William Sound that had been heavily oiled but not yet treated. The
samples were from the surface and subsurface. The surface samples
showed a high degree of microbial degradation of the naphthalene
series, but only a small amount of the C3 naphthalenes remained.
SEP 13 '89 0:23 LAB OSHA
PAGE. 03
3
Therefore, the surface oil has very low toxicity; the only toxicity
remaining would be due to the phenathrenes but we expect to see
continued degradation, probably within the next year. We already
see significant losses of C1 phenathrenes in the surface samples. We
see evidence of the relatively low toxicity of the surface oil in that
there are large numbers of living organisms in the lower intertidal
zones of beaches that have not been washed.
However, the subsurface samples showed that most of the C3
naphthalenes remained, and the phenanthrenes showed almost no
weathering. The subsurface oil still has a moderate level of toxicity,
and the rates of weathering and detoxification by biodegradation will
be much slower. The oil that is not removed by winter storms will
probably take several years to be rendered non-toxic. But, the
subsurface oil is not readily available to aquatic organisms so there is
not much of a pathway of exposure or uptake. The subsurface oil is
not very mobile and will become increasingly less mobile over time.
The naphthalenes are known to leach out from beach sediments for a
period of up to one-half year. (Jim Payne, SAIC, personal
communication). But the high molecular weight aromatics have
essentially no water solubility and so they cannot enter the
biosphere if they remain buried in the beach sediments.
3. How long will the oil be visible?
Except in isolated conditions (for example, oil stranded above the
high tide line or oil which has been covered with sediment and then
re-exposed), visible oil should not be detectable after two to three
years, as evidenced by the AMOCO CADIZ and URQUIOLA spills
(Gundlach and Hayes 1977; Research Planning Institute 1978a;
Research Planning Institute 1978b). There could be leaching from
subsurface oil next summer, with a few scattered tarballs (Blumer et
al. 1973) remaining on the ocean surface.
4. Is there a way to clean the oil or make it non-toxic?
Continued efforts to enhance natural biological processes appears to
be the only effective method to deal with the oiling situation that
will remain next spring. Increasing oil viscosity is rendering hot,
high pressure water flushing increasingly less effective in dealing
with the current oiling situation. By spring, oil that remains deeply
SEP 13 '89 0:24 LAB OSHA
PAGE.04
22:55 68, 21 d3S
PAGE.04
4
buried in the sediments will be unreachable unless heavy equipment
is employed to uncover the surface sediments. We believe the
disruption of biological activity on the surface by this approach
would outway any benefit derived by removing buried oil.
5. How well do natural forces help cleanup the shoreline?
The extent to which natural processes effectively clean oil from the
shoreline depends a great deal on the degree of exposure of the
shoreline to wave activity. The more exposed sections of coast will
be quickly and completely cleaned: high wave action that thoroughly
tumbles shoreline sediments is clearly the most effective cleaning
mechanism.
Oil deeply buried in the interstitial spaces between sediment
particles will not be affected by continuous wave tumbling, but tidal
and groundwater flushing, coupled with microbial weathering, will
still be effective on a longer time scale. Studies to date have
indicated that natural microbial degradation is actively degrading the
oil at rates much greater than expected in the cold water
environment. However is not known how well microbial degradation
will be effective in dealing with the waxy and asphaltic fractions of
the oil.
6. What are the natural forces that help cleanup the shoreline?
Natural mechanical and biological weathering processes serve to
disperse and detoxify the oil on the shoreline over time. The
primary mechanical process is wave action and the associated
summer/winter cycle of sediment transport to and from the
shoreline. The eventual fate of the oil, however, is primarily
controlled by the rate that biological weathering results in the
breakdown and oxidation of the oil by specific bacteria.
BIBLIOGRAPHY
Anderson, J., 1985, Toxicity of PBC Oil On Alaskan Species; Proc. 1985
Oil Spill Conference, Am. Petrol. Inst., Washington, DC.
Blount, A. 1978. Two years after the Metula oil spill, Strait of
Magellan, Chile oil interaction with coastal environments. Columbia,
SEP 13 '89 0:24 LAB OSHA
PAGE. 05
00.00 68, 01 ass
5
South Carolina: Coastal Research Division, Dept. of Geology,
University of South Carolina. Tech. Rept. No. 16-CRD. 214pp.
Blumer, M., M. Ehrhardt, and J. H. Jones. 1973. The environmental
fate of stranded crude oil. Deep-Sea Research 20(3): 239-259.
Gundlach, E. R. and M. O. Hayes. 1977. The Urquiola oil spill, La
Coruna, Spain; case history and discussion of methods of control and
clean-up. Mar. Pollut. Bull 8(6): 132-136.
Hann, R. W., Jr. 1975. Follow-up field survey of the oil pollution
from the tanker Metula. College Station, Texas: Civil Engineering
Department, Texas A&M University. Report to U.S. Coast Guard.
Keizer, P. D., T.P. Ahern, J. Dale, and J. H. Vandermeulen. 1978.
Residues of Bunker C in Chedabucto Bay, Nova Scotia, 6 years after
the Arrow spill. J. Fish. Res. Board Canada, vol. 35(5), pp. 528-535.
Owens, E. H. 1971. The restoration of beaches contaminated by oil in
Chedabucto Bay, Nova Scotia. Ottawa: Dept. of Energy, Mines and
Resources, Mar. Sci. Branch. Manuscr. Rept. Series No. 19. 78pp.
Research Planning Institute. 1978a. Investigations of beach
processes. In: The Amoco Cadiz Oil Spill, A Preliminary Scientific
Report (W. N. Hess, ed.). Boulder, Colorado: NOAA/EPA Special
Report. pp. 85-197.
Research Planning Institute. 1978b. The Amoco Cadiz spill, third
follow-up survey of oil impact on the shoreline, July, 1978. Boulder,
Colorado: NOAA Environmental Research Laboratories. 67pp.
Research Planning Institute. 1979. Coastal Processes Field Manual
for Oil Spill Assessment. Boulder, Colorado: NOAA Office of Marine
Pollution Assessment. 172pp.
SEP 13 '89 0:25 LAB OSHA
PAGE. 06
for Dr. D.A. Bromley
6
Further Background Information on Oil Spill Cleanup
The effects of CLEANUP ACTIVITIES must also be considered in addition
to the effects of the oil spill.
The following is a summary of the effects of different kinds of
oil spill cleanup:
A work group on oil spill cleanup at a 1982 work-
shop divided cleanup methods into several generic
types, among them: natural cleansing, mechanical
removal, manual removal, sorbents, chemical disper-
sants, sinking agents, and burning. Four general
categories of ecological impacts that may result from
use of these cleanup methods were also identified:
1. Potential for substrate or habitat disruption.
Some cleanup methods disrupt the integrity or
change the quality of a substrate, and, therefore,
the associated organisms. Examples include the
use of heavy equipment on certain beach types
or high pressure flushing in marshes.
2. Potential for loss or disruption of community
structure,
Some cleanup techniques remove organisms
from the habitat that may have survived the initial
oiling, e.g., removal of organisms from a rocky in-
tertidal habitat through steam cleaning or high
pressure flushing.
3. Potential for increased likelihood of oil uptake.
This occurs when the cleanup technique exposes
organisms to additional oil; e.g., techniques which
increase penetration of oil into sediments, or in-
crease its availability to organisms.
4. Potential for increased oil re-entry to the
environment.
This may occur with cleanup techniques which
(a) reduce the viscosity of the oil (e.g., steam clean-
ing), (b) disturb an oiled substrate to remobilize
oil, (e.g., flushing without proper recovery of free
oil), or (c) incorporate oil into sediments where,
as erosion occurs, oil will be reintroduced into the
system.
from:
"Oil Spill Response and Ecological Impacts 15 Years Beyond Santa Barbara"
Marine Technology Society Journal, 18 (3), 43 - - 50. 1984
by Dr. June Lindstedt-Siva
SEP 13 '89 0:25 LAB OSHA
PAGE. 07
7
More Background on effects of cleanup activities
Note the effects of steam cleaning on the environment
Steam Cleaning. Steam cleaning uses steam or high
temperature water under pressure to remove oil from
solid surfaces such as rocky shorelines, seawalls and
jetties.¹⁴ This technique effectively removes even high
viscosity oils, but it also removes any living organisms.
Complete removal of organisms means that the suc-
cessful process of establishing a rocky intertidal com-
munity must begin again, a process that may take 5-15
years.14 In addition, steam cleaning may increase
penetration of oil into surrounding sediments.²⁰
High Pressure Flushing. This technique (also called
hydroblasting) uses high pressure (greater than 100 psi)
water streams to remove oil from the substrate. Flushed
oil is then channeled to a recovery area.⁴ The method
is applicable to jetties, sea walls, piers, pilings and rocky
shores where it can effectively remove oil, However,
high pressure flushing also removes organisms. It is
particularly damaging to low energy, high productivity
shorelines or other habitats where recovery is slow.
Further impacts may result from increased oil penetra-
tion into sediments or from transport of equipment
over the oiled and adjacent habitats. This method was
used in a freshwater marsh with disastrous
consequences.20
from Siva (previous page reference)
THE WHITE HOUSE
WASHINGTON
dolum Sununu
Syt13.1909.
Seonsider NASPan
un partant praject fn The US.
AG Huathed please it is
perilarsly close to being
wiped out. Heape That Theu
is Something we can do to
keepitaline at least along
The line pleanmended by
The Space Council.
Allan
SEP-12-'89 TUE 09:15 ID:
TEL. NO:
#832 P02
NASP. FUNDING
BACKGROUND:
- Original Reagan Budget provided NASP funding at $427M ($300M AF,
$127M NASA)
- First Bush Revision called for $227M ($100M DoD to be
transferred to NASA, $127M NASA) and program transfer to NASA
- Bush Revised after National Space Council review called for
$254M ($127M AF, $127M NASA) and continued DoD participation
CURRENT STATUS:
DoD
NASA
DOD
NASA
HASC
HAC/D
HSSTC
HAC/V
SASC
SAC/DI
SCOM
SAC/V
285
285
127
98
100
(0)
127
(0)*
- Prellminary staff mark positions prior to markup
TALKING POINTS:
- Program has had Intense review. Everyone agrees It should be
done and that $254M In FY 90 is rock bottom (from $320M In 89)
- National program with immense potential in terms of national
competitiveness, pride and balance of trade
- Industry has nearly matched the government Investment ($806M) In
NASP by providing approximately $700M through FY 89
- The National Space Council's credibility is on the line. $254M
is needed to execute the rephased NASP program that the Council
and the President approved
- The bottom line Is $254M - that's what is needed to execute the
rephased program
- Program has made significant technical progress
IMPACT:
- Below $254M the program is not NASP -- focus lost due to reduced
level of effort, loss of experienced people and Infrastructure
-- Only way to continue would be to stop work by five
contractors and Immediately down select to one engine and one
airframe contractor (greater risk, lost competitiveness, etc)
-- All generic technology work (e.g. technology maturation)
would be eliminated (again, greater risk, etc)
- Even at $254M the program has already been rephased by an
additional 2 1/2 years
Col Rausch, NASP Inter-Agency Office, 695-7866, 12 Sep 89
NASP FY 89 ACCOMPLISHMENTS
SEP-12-'89 TUE 09:15 ID:
- Continued fabrication of major structural demonstration
components including cryogenic tankage, wing/fuselage
attachment structure and a large fuselage section
- Continued to develop and refine the three X-30 airframe
contractor designs and their integration with engine
designs
- Conducted major review of contractor scramjet engine
designs and awarded two propulsion Phase IIC contracts
- Performed aerodynamic wind tunnel tests on the airframe
and engine contractor designs
TEL NO:
- Continued to make upgrades to computational fluid dynamics
codes and to validate them with wind tunnel data
- Began scale-up of durable high-temperature materials
- Conducted successful testing of designs for leading edge,
nose cap and actively cooled structures
- Completed upgrade of engine test facilities and continued
to check them out
- Continued high-speed ramjet/scramjet testing (component
and subscale engines)
#832 P03
11 Sep 89
*NASP
REVISED PROGRAM
BUDGET
SEP-12-'89 TUE 09:16 ID:
FY93
AREA
FY89
FY90
FY91
FY92
THRU 1/93
AIRFRAME
45
35
40
40
10
ENGINE
110
80
90
100
20
MATERIALS
70
60
60
60
20
TESTING
20
20
25
35
25
TEL NO:
TECH MAT
55
30
FOCUSED
5
14
47
55
20
TECHNOLOGY
- SUPPORT
15
15
15
15
5
TOTAL
320
254
277
305
100
#832 P04
Withdrawal/Redaction Sheet
(George Bush Library)
Document No.
Subject/Title of Document
Date
Restriction
Class.
and Type
02. Memo
From D. Allan Bromley to John Sununu
9/6/89
(b)(6)
Re: Oceans and International Environmental and Scientific
Affairs Nominee (1 pp.)
Collection:
Record Group:
Bush Presidential Records
Office:
Chief of Staff to the President, Office of the
Series:
Sununu, John, Files
Subseries:
White House Offices File
WHORM Cat.:
File Location:
Science and Technology (1989) [3]: Bromley
Date Closed:
12/1/2004
OA/ID Number:
29183-005
FOIA/SYS Case #:
1998-0004-F[1]
Appeal Case #:
Re-review Case #:
2005-0426-S
Appeal Disposition:
P-2/P-5 Review Case #:
Disposition Date:
AR Case #:
MR Case #:
AR Disposition:
MR Disposition:
AR Disposition Date:
MR Disposition Date:
RESTRICTION CODES
Presidential Records Act - [44 U.S.C. 2204(a)]
Freedom of Information Act - [5 U.S.C. 552(b)]
P-1 National Security Classified Information [(a)(1) of the PRA]
(b)(1) National security classified information [(b)(1) of the FOIA]
P-2 Relating to the appointment to Federal office [(a)(2) of the PRA]
(b)(2) Release would disclose internal personnel rules and practices of an
P-3 Release would violate a Federal statute [(a)(3) of the PRA]
agency [(b)(2) of the FOIA]
P-4 Release would disclose trade secrets or confidential commercial or
(b)(3) Release would violate a Federal statute [(b)(3) of the FOIA]
financial information [(a)(4) of the PRA]
(b)(4) Release would disclose trade secrets or confidential or financial
P-5 Release would disclose confidential advice between the President
information [(b)(4) of the FOIA]
and his advisors, or between such advisors [a)(5) of the PRA]
(b)(6) Release would constitute a clearly unwarranted invasion of
P-6 Release would constitute a clearly unwarranted invasion of
personal privacy [(b)(6) of the FOIA]
personal privacy [(a)(6) of the PRA]
(b)(7) Release would disclose information compiled for law enforcement
purposes [(b)(7) of the FOIA]
C. Closed in accordance with restrictions contained in donor's deed of
(b)(8) Release would disclose information concerning the regulation of
gift.
financial institutions [(b)(8) of the FOIA]
(b)(9) Release would disclose geological or geophysical information
PRM. Removed as a personal record misfile.
THE WHITE HOUSE
WASHINGTON
July 31, 1989
MEMORANDUM FOR JOHN H. SUNUNU
FROM:
D. ALLAN BROMLEY
Ann
SUBJECT:
Sea Level Raising
Herewith some input assumptions:
1. Earth's radius:
6378 km.
2. Earth's area:
5.10 X 10 6 (km) 2
3.
Antarctic Ice Volume:
(30 + 2.5) X 10 6 (km) 3
4. Arctic Ice Volume:
(3 + 0.25) X 10⁶ (km) 3
5. Roughly 15% of the Antarctic and 7.5% of the Arctic ice is below
current sea level.
6.
We neglect totally isostatic rebound phenomena -- i.e., rebound
of crust relieved of ice load and sinking of ocean floor under
additional water load -- since it is difficulty to get any
reliable figures.
On these assumptions, total melting of both polar caps would result in
a mean sea level rise of 60.5 meters with a rough uncertainty figure
of + 15 meters, i.e., 199 ± 49, say 200 + 50 feet.
The 20 foot figure comes from assuming that only one tenth of the
polar ice melts.
Antarctica has an area of 5,100,000 square miles = 14.2 X 10⁶ (km) 2 so
that the mean ice depth in Antarctica is 2.1 km.
If we take the Ross Ice Shelf, assume this same mean thickness for
lack of more detailed information, we find that the volume in the
shelf ice is some 3.3 X 10⁶ (km) 3 so that if it were to break off and
melt we would get the approximately 20 foot rise that everyone talks
about.
I was surprised to find that the Antarctic ice volume is ten times
that in the Arctic. I had also forgotten that Antarctica at 5.1 X 10⁶
square miles has more than half the area of North America (9.4 X 10⁶
sq. mi.) and significantly larger area than Europe (3.8 X 10⁶ sq. mi.)
THE WHITE HOUSE
WASHINGTON
August 28, 1989
MEMORANDUM FOR THE PRESIDENT
FROM:
D. ALLAN BROMLEY
DAS
SUBJECT:
THE KYOTO PRIZE
Beginning in 1983, President Reagan established the
tradition of sending a brief note of congratulations to the
winners of the Kyoto prize. Three such prizes (in the
amount of $350,000.00 each) are awarded annually to promote
international scientific and literary cooperation and
specifically to recognize outstanding performance by
individuals.
In 1989 the three prizes will be awarded to Dr. Amos Joel,
Jr. (AT&T Bell Laboratories) for his pioneering work on
electronic switching in telecommunication networks; to Dr.
John Cage (Harvard University and the New School) for his
outstanding contributions to modern American music; and to
Dr. Izrail M. Gelfand (Moscow University) for his
fundamental work on functional analysis and generalized
functions in modern mathematics.
I have attached a draft of a letter that you might wish to
send.
Attachment
DRAFT LETTER FROM PRESIDENT BUSH TO WINNERS OF THE 1989
KYOTO PRIZE. WOULD BE READ BY APPROPRIATE PERSON FROM U.S.
EMBASSY, TOKYO AT THE AWARD CEREMONY IN KYOTO ON
NOVEMBER 10, 1989.
I am delighted to extend my warmest congratulations to the
1989 Kyoto Prize laureates -- Dr. Amos Joel, Jr. for his
pioneering contributions to telecommunications, Dr. Izrail
M. Gelfand for fundamental work in modern mathematics and
Dr. John Cage for his role in shaping much of modern
American music.
I would also congratulate the Imanori Foundation for its
establishment of the Kyoto Prize to recognize outstanding
creativity and inqenuity throughout the world.
The Kyoto Prize is particularly noteworthy because it
encompasses all of basic science, applied science, and the
expressive arts which, together, make such vital
contributions to the quality of all our lives. And, as a
truly international award it strengthens the essential bonds
of friendship and cooperation that link all the peoples of
the earth through their participation in, and contributions
to the pursuit of new knowledge and its application in
creative and innovative ways.
Today's winners of the Kyoto Prize add luster to an already
distinguished list of previous winners. I join their
communities, worldwide, in wishing them every success and
satisfaction in their continuing careers.
Governor Sununu
THE WHITE HOUSE
WASHINGTON
August 28, 1989
MEMORANDUM FOR THE PRESIDENT
FROM:
D. ALLAN BROMLEY
Gree
SUBJECT:
THE KYOTO PRIZE
Beginning in 1983, President Reagan established the
tradition of sending a brief note of congratulations to the
winners of the Kyoto prize. Three such prizes (in the
amount of $350,000.00 each) are awarded annually to promote
international scientific and literary cooperation and
specifically to recognize outstanding performance by
individuals.
In 1989 the three prizes will be awarded to Dr. Amos Joel,
Jr. (AT&T Bell Laboratories) for his pioneering work on
electronic switching in telecommunication networks; to Dr.
John Cage (Harvard University and the New School) for his
outstanding contributions to modern American music; and to
Dr. Izrail M. Gelfand (Moscow University) for his
fundamental work on functional analysis and generalized
functions in modern mathematics.
I have attached a draft of a letter that you might wish to
send.
Attachment
DRAFT LETTER FROM PRESIDENT BUSH TO WINNERS OF THE 1989
KYOTO PRIZE. WOULD BE READ BY APPROPRIATE PERSON FROM U.S.
EMBASSY, TOKYO AT THE AWARD CEREMONY IN KYOTO ON
NOVEMBER 10, 1989.
I am delighted to extend my warmest congratulations to the
1989 Kyoto Prize laureates -- Dr. Amos Joel, Jr. for his
pioneering contributions to telecommunications, Dr. Izrail
M. Gelfand for fundamental work in modern mathematics and
Dr. John Cage for his role in shaping much of modern
American music.
I would also congratulate the Imanori Foundation for its
establishment of the Kyoto Prize to recognize outstanding
creativity and inqenuity throughout the world.
The Kyoto Prize is particularly noteworthy because it
encompasses all of basic science, applied science, and the
expressive arts which, together, make such vital
contributions to the quality of all our lives. And, as a
truly international award it strengthens the essential bonds
of friendship and cooperation that link all the peoples of
the earth through their participation in, and contributions
to the pursuit of new knowledge and its application in
creative and innovative ways.
Today's winners of the Kyoto Prize add luster to an already
distinguished list of previous winners. I join their
communities, worldwide, in wishing them every success and
satisfaction in their continuing careers.
Document No. 068511
WHITE HOUSE STAFFING MEMORANDUM
in
DATE:
08/30/89
ACTION/CONCURRENCE/COMMENT DUE BY:
C.O.B. Tuesday 9/5
SUBJECT: PROPOSED EXECUTIVE ORDER ENTITLED "PRESIDENT'S COUNCIL OF
ADVISORS ON SCIENCE AND TECHNOLOGY"
ACTION FYI
ACTION FYI
VICE PRESIDENT
MCCLURE
SUNUNU
NEWMAN
SCOWCROFT
PORTER
DARMAN
STUDDERT
BATES
UNTERMEYER
BREEDEN
OSTP
CARD
CLERK
CICCONI
DEMAREST
FITZWATER
GRAY
HAGIN
REMARKS:
Please provide any comments/recommendations directly to my
office by C.O.B. on Tuesday, 08/05. Thanks.
RESPONSE:
James W. Cicconi
Assistant to the President
and Deputy to the Chief of Staff
Ext. 2702
EXECUTIVE OFFICE OF THE PRESIDENT
STATE
OFFICE OF MANAGEMENT AND BUDGET
WASHINGTON, D.C. 20503
THE DIRECTOR
August 21, 1989
MEMORANDUM FOR THE PRESIDENT
FROM:
Richard
Director G. Darman
SUBJECT:
Proposed Executive Order Entitled
"President's Council of Advisors on
Science and Technology"
SUMMARY: This memorandum forwards for your
consideration a proposed Executive order, prepared by the
Office of Science and Technology Policy, that would
establish a council to advise you on matters involving all
areas of science and technology.
BACKGROUND: On February 9, 1989, you announced your
intention to create, as soon as feasible, an advisory
council of distinguished individuals to advise you on issues
and topics involving science and technology. The proposed
Executive order would implement your decision by
establishing the "President's Council of Advisors on Science
and Technology" ("Council").
The Council would be composed of not more than 15
members, 14 of whom would be distinguished individuals
appointed by you from the private sector. The Director of
the Office of Science and Technology Policy would serve as
Chairman of the Council, and the Vice-Chairman would be
appointed by you from among the 14 private sector members.
The Council would advise you on matters involving all
areas of science and technology. It would conduct a
continuing review and assessment of developments in science
and technology and would invite panels of experts to
investigate and report to the Council on specific issues of
national consequence.
None of the affected agencies objects to the proposed
Executive order.
RECOMMENDATION: I recommend that you sign the attached
Executive order.
Attachment
U.S. Department of Justice
Office of Legal Counsel
Office of the
Washington, D.C. 20530
Assistant Attorney General
August 30, 1989
MEMORANDUM
Re: Proposed Executive Order entitled
"President's Council of Advisors
on Science and Technology
The attached proposed Executive Order has been submitted by
the Office of Science and Technology Policy in the Executive
Office of the President. The Office of Management and Budget,
with the approval of the Director, has forwarded it to this
Department for review of its form and legality.
The proposed Order will establish a council to advise the
President on matters involving all areas of science and
technology. The council, which would be composed of the Director
of the Office of Science and Technology and no more than fourteen
individuals from the private sector, would conduct a continuing
review and assessment of developments in science and technology
and would invite panels of experts to report to the council on
specific issues of national consequence.
The proposed Order is acceptable with respect to its form
and legality.
UPBan
William P. Barr
Assistant Attorney General
Office of Legal Counsel
OF
U.S. Department of Justice
Office of Legal Counsel
Office of the
Washington, D.C. 20530
Assistant Attorney General
August 30, 1989
The President,
The White House.
My dear Mr. President:
I am herewith transmitting a proposed Executive Order
entitled "President's Council of Advisors on Science and
Technology." This proposed Executive Order has been submitted by
the Office of Science and Technology Policy in the Executive
Office of the President. The Office of Management and Budget,
with the approval of the Director, has forwarded it to this
Department for review of its form and legality.
The proposed Executive Order is approved with respect to
form and legality.
Respectfully,
UPBan
William P. Barr
Assistant Attorney General
Office of Legal Counsel
PREMIDENT
EXECUTIVE OFFICE OF THE PRESIDENT
OFFICE SEATS UNITED
OFFICE OF MANAGEMENT AND BUDGET
WASHINGTON. D.C. 20503
August 21, 1989
Honorable Dick Thornburgh
United States Attorney General
Washington, D.C. 20503
Dear Mr. Attorney General:
Enclosed, in accordance with the provisions of
Executive Order No. 11030, as amended, is a proposed
Executive order entitled "President's Council of Advisors on
Science and Technology." The proposed Executive order,
which was prepared by the Office of Science and Technology
Policy in the Executive Office of the President, would
establish a council to advise the President on matters
involving all areas of science and technology.
On February 9, 1989, the President announced his
intention to create, as soon as feasible, an advisory
committee of distinguished individuals that would advise him
on issues and topics involving science and technology. The
proposed Executive order would implement his decision by
establishing the "President's Council of Advisors on Science
and Technology" ("Council").
The Council would be composed of not more than 15
members, 14 of whom would be distinguished individuals
appointed by the President from the private sector. The
Director of the Office of Science and Technology Policy
would serve as Chairman of the Council, and the
Vice-Chairman would be appointed by the President from among
the 14 private sector members.
The Council would advise the President on matters
involving all areas of science and technology. It would
conduct a continuing review and assessment of developments
in science and technology and would invite panels of experts
to investigate and report to the Council on specific issues
of national consequence.
Your staff may direct any questions concerning this
proposed Executive order to Mr. Mac Reed of this office
(395-5600).
This proposed Executive order has the approval of the
Director of the Office of Management and Budget.
Sincerely,
Robert 6 Dannes
Robert G. Damus
Acting General Counsel
Enclosures
EXECUTIVE ORDER
PRESIDENT'S COUNCIL OF ADVISORS ON SCIENCE AND TECHNOLOGY
By the authority vested in me as President by the
Constitution and laws of the United States of America, and
in order to establish, in accordance with the provisions of
the Federal Advisory Committee Act, as amended (5 U.S.C.
App. 2), an advisory committee on science and technology, it
is hereby ordered as follows:
Section 1. Establishment. There is established the
President's Council of Advisors on Science and Technology
("Council"). The Council shall be composed of not more than
15 members, 14 of whom shall be distinguished individuals
from the private sector to be appointed by the President.
The Director of the Office of Science and Technology Policy
shall serve as Chairman of the Council. The Vice-Chairman
shall be appointed by the President from among the 14
private sector members. The Chairman shall report directly
to the President.
Sec. 2. Functions. (a) The Council shall advise the
President on matters involving all areas of science and
technology.
(b) In the performance of its advisory duties the
Council shall conduct a continuing review and assessment of
developments in science and technology, and shall, through
the Chairman, report thereon to the President whenever
requested.
(c) The Chairman may, from time to time, invite panels
of experts to investigate and report to the Council on
specific issues of national consequence.
Sec. 3. Administration. The heads of Executive
agencies shall, to the extent permitted by law, provide the
Council and its panels such information with respect to
scientific and technological matters as required for the
purpose of carrying out its functions.
(b) Members of the Council shall serve without any
compensation for their work on the Council. However,
members appointed from among private citizens of the United
States may be allowed travel expenses, including per diem in
lieu of subsistence, as authorized by law for persons
serving intermittently in the government service (5 U.S.C.
5701-5707).
(c) Any expenses of the Council shall be paid from the
funds available for the expenses of the Office of Science
and Technology Policy.
(d) The Office of Administration shall, on a
reimbursable basis, provide such administrative services as
may be required.
Sec. 4. General. Notwithstanding any other Executive
order, the functions of the President under the Federal
Advisory Committee Act, as amended, except that of reporting
to the Congress, which are applicable to the Council, shall
be performed by the Office of Administration in accord with
the guidelines and procedures established by the
Administrator of General Services.
(b) The Committee shall terminate on June 30, 1991,
unless sooner extended.
THE WHITE HOUSE,
THE WHITE HOUSE
WASHINGTON
August 24, 1989
MEMORANDUM FOR
FROM:
JOHN D. ALLAN H. SUNUNU BROMLEY DaB.
SUBJECT:
MEMORANDA FOR PRESIDENT BUSH
Enclosed herewith are three memoranda that I would
appreciate your bringing to the President's attention.
Two of them relate to Head of State meetings and when you
get back I would like to discuss with you some appropriate
tasking of NSC and OSTP to provide the necessary science and
technology briefings for the President prior to such
meetings in the future.
I hope the weather in Maine has been as glorious as it was
in northern Canada!
Enclosures
THE WHITE HOUSE
WASHINGTON
August 24, 1989
MEMORANDUM FOR THE PRESIDENT
FROM:
D. ALLAN BROMLEY
eyee
SUBJECT:
YOUR FORTHCOMING MEETING WITH
PRIME MINISTER BRIAN MULROONEY OF CANADA
I am told that Prime Minister Mulrooney has been briefed in
depth about Canada's proposed major new accelerator complex
in Vancouver and may well wish to discuss with you a hoped
for U.S. contribution to its construction.
The Canadians propose to ask the United States to provide
$15 million per year over the next 5 years for a total of
$75 million; this represents roughly one-sixth of the total
facility cost. Once constructed, the Canadian government is
prepared to commit to providing the entire operating support
while U.S. scientists will utilize 30 to 35 percent of the
available research time.
This will be a unique facility in the international particle
physics community. It has been reviewed in detail by high
level committees reporting to NSF and DOE with the
recommendation that the project represents a very
cost-effective approach to giving the U.S. scientific
community access to research fields characterized by the
very high particle beam intensities that it will make
available.
The prospect has the acronym KAON (K mesons, antiprotons and
nucleons) and is projected as a truly international
facility. It is anticipated that Japan, Germany and Italy
will contribute $50, 30 and 30 million, respectively, to the
construction costs -- with additional contributions
anticipated from Britain, France and others.
This Canadian initiative will make unnecessary the
construction of an equivalent U.S. facility that had been
under consideration for some time at the Los Alamos National
Laboratory.
It has high visibility -- both scientifically and politically
-- in Canada and I consider that U.S. participation at the
level indicated would represent an excellent U.S.
investment. DOE, will, I believe include it in the FY 1991
budget submission.
Again, I would welcome the opportunity to provide any more
detailed information concerning this activity that you might
find useful.
THE WHITE HOUSE
WASHINGTON
August 24, 1989
MEMORANDUM FOR THE PRESIDENT
FROM:
D. ALLAN BROMLEY
eyee
SUBJECT:
YOUR FORTHCOMING MEETING WITH
PRIME MINISTER BRIAN MULROONEY OF CANADA
I am told that Prime Minister Mulrooney has been briefed in
depth about Canada's proposed major new accelerator complex
in Vancouver and may well wish to discuss with you a hoped
for U.S. contribution to its construction.
The Canadians propose to ask the United States to provide
$15 million per year over the next 5 years for a total of
$75 million; this represents roughly one-sixth of the total
facility cost. Once constructed, the Canadian government is
prepared to commit to providing the entire operating support
while U.S. scientists will utilize 30 to 35 percent of the
available research time.
This will be a unique facility in the international particle
physics community. It has been reviewed in detail by high
level committees reporting to NSF and DOE with the
recommendation that the project represents a very
cost-effective approach to giving the U.S. scientific
community access to research fields characterized by the
very high particle beam intensities that it will make
available.
The prospect has the acronym KAON (K mesons, antiprotons and
nucleons) and is projected as a truly international
facility. It is anticipated that Japan, Germany and Italy
will contribute $50, 30 and 30 million, respectively, to the
construction costs -- with additional contributions
anticipated from Britain, France and others.
This Canadian initiative will make unnecessary the
construction of an equivalent U.S. facility that had been
under consideration for some time at the Los Alamos National
Laboratory.
It has high visibility -- both scientifically and politically
-- in Canada and I consider that U.S. participation at the
level indicated would represent an excellent U.S.
investment. DOE, will, I believe include it in the FY 1991
budget submission.
Again, I would welcome the opportunity to provide any more
detailed information concerning this activity that you might
find useful.
THE WHITE HOUSE
WASHINGTON
August 24, 1989
MEMORANDUM FOR THE PRESIDENT
FROM:
D. ALLAN BROMLEY
ans
SUBJECT:
VISIT OF JAPANESE PRIME MINISTER
Among the items that Prime Minister Toshiki Kaifu will wish
to discuss with you during his forthcoming visit to
Washington is the question of Japanese contribution to the
cost of the Superconducting-Supercollider He has been
extensively briefed by a relative who happens to be a
physicist and by the director of Japan's major accelerator
facility (KEK).
The amounts that have been mentioned in earlier discussions
range from $500 million to $1 billion and my informal
channels tell me that the Japanese are prepared to go for
the upper end of this range -- but with conditions that may
be difficult to sell to the Congress, although potentially
of value to the successful completion of the project.
I would welcome an opportunity to brief you on this question
at whatever level of detail you might find interesting
and/or useful.
CC: Governor Sununu
THE WHITE HOUSE
WASHINGTON
August 24, 1989
MEMORANDUM FOR THE PRESIDENT
FROM:
D. ALLAN BROMLEY
Das.
SUBJECT:
VISIT OF JAPANESE PRIME MINISTER
Among the items that Prime Minister Toshiki Kaifu will wish
to discuss with you during his forthcoming visit to
Washington is the question of Japanese contribution to the
cost of the Superconducting-Supercollider. He has been
extensively briefed by a relative who happens to be a
physicist and by the director of Japan's major accelerator
facility (KEK).
The amounts that have been mentioned in earlier discussions
range from $500 million to $1 billion and my informal
channels tell me that the Japanese are prepared to go for
the upper end of this range -- but with conditions that may
be difficult to sell to the Congress, although potentially
of value to the successful completion of the project.
I would welcome an opportunity to brief you on this question
at whatever level of detail you might find interesting
and/or useful.
CC: Governor Sununu
Withdrawal/Redaction Sheet
(George Bush Library)
Document No.
Subject/Title of Document
Date
Restriction
Class.
and Type
05. Memo
From D. Allan Bromley to POTUS
8/24/89
(b)(6)
Re: National Science Board Memberships [2 copies] (2 pp.)
Collection:
Record Group: Bush Presidential Records
Office:
Chief of Staff to the President, Office of the
Series:
Sununu, John, Files
Subseries:
White House Offices File
WHORM Cat.:
File Location:
Science and Technology (1989) [3]: Bromley
Date Closed:
12/1/2004
OA/ID Number:
29183-005
FOIA/SYS Case #:
1998-0004-F[1]
Appeal Case #:
Re-review Case #:
2005-0426-S
Appeal Disposition:
P-2/P-5 Review Case #:
Disposition Date:
AR Case #:
MR Case #:
AR Disposition:
MR Disposition:
AR Disposition Date:
MR Disposition Date:
RESTRICTION CODES
Presidential Records Act - [44 U.S.C. 2204(a)]
Freedom of Information Act - [5 U.S.C. 552(b)]
P-1 National Security Classified Information [(a)(1) of the PRA]
(b)(1) National security classified information [(b)(1) of the FOIA]
P-2 Relating to the appointment to Federal office [(a)(2) of the PRA]
(b)(2) Release would disclose internal personnel rules and practices of an
P-3 Release would violate a Federal statute [(a)(3) of the PRA]
agency [(b)(2) of the FOIA]
P-4 Release would disclose trade secrets or confidential commercial or
(b)(3) Release would violate a Federal statute [(b)(3) of the FOIA]
financial information [(a)(4) of the PRA]
(b)(4) Release would disclose trade secrets or confidential or financial
P-5 Release would disclose confidential advice between the President
information [(b)(4) of the FOIA]
and his advisors, or between such advisors [a)(5) of the PRA]
(b)(6) Release would constitute a clearly unwarranted invasion of
P-6 Release would constitute a clearly unwarranted invasion of
personal privacy [(b)(6) of the FOIA]
personal privacy [(a)(6) of the PRA]
(b)(7) Release would disclose information compiled for law enforcement
purposes [(b)(7) of the FOIA]
C. Closed in accordance with restrictions contained in donor's deed of
(b)(8) Release would disclose information concerning the regulation of
gift.
financial institutions [(b)(8) of the FOIA]
(b)(9) Release would disclose geological or geophysical information
PRM. Removed as a personal record misfile.
THE WHITE HOUSE
WASHINGTON
August 24, 1989
MEMORANDUM FOR JOHN H.
FROM:
D. ALLAN SUNUNU BROMLEY DaB.
SUBJECT:
MEMORANDA FOR PRESIDENT BUSH
Enclosed herewith are three memoranda that I would
appreciate your bringing to the President's attention.
Two of them relate to Head of State meetings and when you
get back I would like to discuss with you some appropriate
tasking of NSC and OSTP to provide the necessary science and
technology briefings for the President prior to such
meetings in the future.
I hope the weather in Maine has been as glorious as it was
in northern Canada!
Enclosures
THE WHITE HOUSE
WASHINGTON
August 28, 1989
MEMORANDUM FOR THE PRESIDENT
FROM:
D. ALLAN BROMLEY
SUBJECT:
ANNUAL SCIENCE COUNSELOR'S CONFERENCE
Each year the Department of State sponsors a conference in
Washington on current science, technology and environment
(STE) issues for the benefit of its 24 embassy-based STE
officers worldwide. The conference is an opportunity for
the officers to hear presentations from senior U.S.
officials, to raise questions, and to offer views on these
issues from the overseas perspective.
This year's conference is scheduled for September 25-27,
1989. I will be presenting some of your Administration's
views on science and technology policy at a luncheon on the
26th. Other invited speakers include DOE Secretary James
Watkins, NASA Administrator Richard Truly, EPA Administrator
William Reilly, NSF Director Erich Bloch, Nobel Laureate
James Watson, and presidents of the National Academies of
Science and Engineering.
The conference has been endorsed by the Committee on
Science, Space and Technology, which in 1988 submitted a
Congressional Resolution commending these officers for their
outstanding performance. The officers will meet with the
committee during this year's conference.
I believe that this conference offers an excellent
opportunity for you to make a few remarks about the value of
international scientific and technological cooperation and
in particular U.S. commitment to management of the global
environment. I hope that you will consider speaking to
these counselors if your schedule permits; they can play key
roles in transmitting your thoughts and plans in the foreign
capitals where they serve.
cc: Governor Sununu
2
THE WHITE HOUSE
WASHINGTON
August 31, 1989
INFORMATION
MEMORANDUM FOR THE PRESIDENT
FROM:
D. Allan Bromley
ЭМБ,
SUBJECT: Background Information on the Superconducting Super
Collider (SSC)
I. SUMMARY
The SSC is a large, expensive, accelerator construction
project requiring over $1 billion in funds from other
nations for completion. It is the single largest research
instrument ever proposed. A complete background on what the
SSC is, how it fits within the spectrum of currently
designed or in-use high energy physics particle accelerators,
and a sketch of present plans for international cost-sharing
is presented.
II. DISCUSSION
Attached is a fairly long paper on high energy physics and
the SSC construction project; the key aspects are covered in
a one page summary. The major reason for providing you with
this information at this time is that, as noted in my recent
memorandum, OSTP staff have been informed of the possibility
that the Japanese Prime Minister will bring up with you the
issue of his country's financial participation in the SSC.
Several recent developments make this likely:
O
Both Houses of Congress have finally declared support
for SSC construction.
O
The SSC Laboratory in Texas has been established and
has begun the real design and development work of the
project.
The leadership in the Japanese Government has changed
to one interested in excellent relations with the
United States.
O
Several other countries -- including Canada and the
European nations supporting The European Center for
Nuclear Research (CERN) in Switzerland -- are asking
the Japanese for substantial contributions to their own
high energy physics accelerator facilities.
International support for the SSC has been, from the
outset, an integral part of this Administration's proposal
to build this high energy physics facility. Visible
Presidential support for this concept of international
cooperation is essential in such high level meetings as the
upcoming one with the Japanese Prime Minister if the
necessary cooperation and participation are to be obtained.
The Prime Minister needs to be aware of how important you
believe such an agreement would be to both nations: that
this cooperation will benefit both nations not only through
people-to-people exchanges and consequent mutual cultural
understanding but also through the mutual expansion of
mankind's scientific knowledge and horizons.
The SSC promises to take its researchers back to the
conditions existing only tiny fractions of a second after
the initial "Bang of Creation", it promises to resolve one
of the greatest mysteries left in the study of our universe
-- why and how does matter acquire mass? -- and it promises
to take us ever closer to, if not indeed to the realization
of Einstein's dream of a complete understanding of the
structure of all matter and of the forces through which it
acts. This is truly a great adventure and one of the
triumphs of the human intellect.
I would welcome the opportunity to provide you with any
further information regarding SSC and its planned
utilization that you might find of interest.
The Superconducting Super Collider:
A High Energy Physics Facility
Summary
The Superconducting Super Collider (SSC) will be the largest
basic research facility ever built. It will collide two beams of
hydrogen nuclei (protons) together by accelerating them through
nearly 10,000 superconducting magnets in a tunnel 53 miles in
circumference. It will take eleven years to build and cost
almost $6 billión.
Your Administration is committed to the construction of the SSC.
The commitment was made with the understanding that funding the
SSC would not be at the expense of other ongoing science
programs and that one-third of the total project funding should
be provided by non-Federal sources such as the host state and
foreign countries that will share in the scientific and
technological benefits accruing from the SSC. Cost-sharing in a
project of this size is entirely appropriate since other nations
as well as the U.S. will have access to, and benefit from, the
facility.
The SSC will be a facility operating within the well developed
traditions of international scientific collaboration in high
energy physics experiments. The SSC will be operated by DOE for
the benefit of all qualified scientific users, foreign and
domestic. As currently envisaged, the SSC will be a truly
international facility, with mutual and equitable contributions
and benefits shared by the participating nations. Depending upon
the nature and extent of their financial commitments, the
participating nations will be allocated an appropriate share
either in the development or management structure of the SSC.
The SSC should provide many incentives for participation by
foreign countries. In addition to the prestige associated with
involvement in the world's largest frontier science facility,
collaboration on the SSC will provide unique educational
opportunities for young scientists and valuable engineering
experience on challenging, state-of-the-art systems.
The major potential contributing foreign countries include Japan,
Canada, Italy, France, the Federal Republic of Germany, South
Korea, India, and Switzerland. These same countries are also
expected to contribute detectors for specialized experiments and,
perhaps, operating funds once the SSC facility has been completed
and is in operation.
BACKGROUND
Experimental research in high energy physics involves
accelerating beams of elementary particles - protons and
electrons - essentially to the speed of light, aiming the beams
at various targets, and then studying the new forms of matter
resulting from the collisions. That these new forms of matter
result can be seen by applying Einstein's equation E=mc2. This
relationship implies that the energy of a particle (E) and its
mass (m) are alternate characteristics. The "trick" in high
energy physics is to deliver ever more energy into ever smaller
volumes so that some at least of this energy materializes in the
form of new, previously unknown particles or states of matter.
Thus, in this field there is a continual push to accelerate the
beams of protons or electrons to ever higher energies -- to probe
ever deeper into matter.
To perform such studies, the structure of physicists continuously
push the state of the art of technology. They have developed
advanced detectors, high speed electronics, new concepts in
particle accelerators and new approaches in which beams of
protons (or electrons) are aimed at each other and collide with
twice the energy of either beam.
Federal funding programs supporting such research continually
face the problem of bringing large accelerators and expensive
state-of-the-art detector systems on-line to enable this field to
continue to make progress. Currently our high energy physics
programs support three major U.S. facilities used to accelerate
elementary particles:
Stanford Linear Accelerator Center in California (SLAC)
managed by Stanford University,
Fermi National Laboratory (Fermilab) Batavia, Illinois,
managed by the University Research Associates (URA),
and
Alternating Gradient Synchrotron (AGS) at Brookhaven on
Long Island managed by Associated Universities
Incorporated (AUI).
These facilities are available to all qualified experimenters
from national laboratories and universities and to similarly
qualified foreign scientists. In this country alone, these basic
research programs provide support and operating expenses for 148
experimental groups from 72 universities and laboratories to use
these facilities. (The total American community is about 2,000
to 2,500 professional physicists.)
Fermilab, just outside of Chicago, is currently the most powerful
high energy physics accelerator in the world. It holds the
world's record for accelerator energies at one trillion electron
volts (TeV). Its projected lifetime is ten years or longer,
depending on the wealth of physics it will uncover from
proton-proton collisions.
SLAC, an electron accelerating facility, is also competitive with
the other most powerful electron accelerator in Europe, the Large
Electron Positron (LEP) Ring at CERN in Geneva, Switzerland.
The AGS at Brookhaven, a currently operating joint high energy
and nuclear physics facility, will be the "front-end" for a
unique future new accelerator, called RHIC (Relativistic Heavy
Ion Collider), designed to investigate collisions of large atomic
nuclei. Operating together, the AGS and RHIC will give the U.S.
a nuclear physics capability unmatched in today's world.
The Superconducting Super Collider
The Superconducting Super Collider (SSC) is the name given to the
"next generation" high energy physics accelerator facility. The
main accelerator will have a beam energy of 20 TeV. This is 20
times more than the world's currently most-energetic accelerator
located at Fermilab. The Collider itself will consist of two
rings of superconducting magnets (nearly 10,000 in all) and
associated electrical systems in a common tunnel. The magnets
will channel a beam of protons around the tunnel. The tunnel is
53 miles in circumference. The project also includes the
associated office and laboratory facilities (buildings,
structures, and utilities) required to support the technical
systems.
The total project cost is currently estimated to be $5.9 billion
over 11 years with the facility becoming available to researchers
in FY 1998. This estimate is based on a conceptual design report
that does not take into account, for example, site-specific
features nor the actual difficulty of mass producing super-
conducting magnets and thus the cost estimate is acknowledged to
be very approximate.
The Reagan Administration committed to the project in January
1987. The commitment was made with the understanding that
funding for the SSC would not be at the expense of other ongoing
science programs and that one-third of the total project funding
should be provided by non-Federal sources such as the host State
and foreign countries that will share in the scientific and
technological benefits accruing from the SSC. (See attached.)
Cost-sharing in a project of this size is entirely appropriate
since other nations as well as the U.S. will have access to and
benefit from the facility.
In January of this year, the site for the project was chosen to
be Waxahachie, Texas, thirty miles from Dallas.
It can be argued that the spin-offs from SSC-related research
should be of considerable value to American industry. For
example, U.S. industry does not currently have the capability to
produce superconducting magnets in large quantities. These
magnets can be useful to the "computer chip" industry and the
nuclear medicine instrumentation industry. Currently, only Japan
has this capability but the Europeans are now attempting to
develop it.
Planned Spending on SSC as presented to Congress for FY 1990
(BA $ in Millions)
1988
1989
1990
1991
1992
1993
1994
1995
1996
1997
1998
Totals
Total Project Funding
$33
$99
$278
$593
$694
$750
$760
$832
$882
$833
$140
$5,894
Est. non-Federal Share
0
0
$28
$200
$200
$300
$300
$300
$300
$172
0
$1,800
Federal Share
$33
$99
$250
$393
$494
$450
$460
$532
$582
$661
$140
$4,094
The detectors necessary for the facility are another example.
They will require both new materials for high radiation
environments and new signal processing techniques and software.
Such electronics will have a myriad of other uses particularly in
defense systems such as are envisioned in current Strategic
Defense Initiative projects. In the past, many if not most, of
the breakthroughs in the signal processing area have come from
basic research projects in the physical sciences.
The SSC, it can also be argued, would be of considerable benefit
to education. Such a facility would inspire young people to
pursue careers in science and technology because of the unique
challenge it would provide both to build and to use in the
pursuit of new fundamental knowledge. Over 100 U.S. universities
are currently projected to utilize this facility.
Congress, State and local governments, leaders of major academic
institutions and some business leaders have expressed strong
support for the SSC and have encouraged the timely construction
of this unique scientific facility.
Finally, several countries including Japan and Italy, after
visits from Department of Energy over the past 18 months, seem
likely to support the project with financial or in-kind
contributions and through participation during construction,
operation, or in the particular experiments carried out in the
facility by highly qualified physicists from these nations.
In short, there will be many supporters for this project both
inside and outside the community it will serve.
International Cost Sharing
Your Administration has proposed that the SSC be located in the
U.S. and built mainly with Federal funds. Of the one-third
non-Federal funding for the project, the State of Texas has
raised $1 billion and offered as much as $700 million to defray
the cost of the construction project. That leaves at least $1
billion to be obtained through international participation in the
project. The high energy physics community has traditionally
been international and cooperative. The increasing costs of high
energy physics accelerators and the number of smaller machines
that have been or will be decommissioned because they are no
longer competitive, will reinforce this tradition.
The SSC is not the only possibility for the "next generation"
high energy physics machine. An upgrade to a European
accelerator -- the so called LEP machine (Large Electron Positron
Ring) at CERN -- to be called the Large Hadron Collider (LHC), is
considered to be a less powerful alternative to the SSC, if the
U.S. would not go forward with current SSC construction plans.
Because LHC would be based upon the existing LEP facility, it
could be built much faster and more cheaply than the SSC.
It would, however, have an energy of only one-third that of the
SSC (i.e., 5-8 TeV) and would have only one-tenth of the possible
collisions thus making very rare forms of matter undiscoverable.
Although the LHC would not be competitive with the SSC, if it
were the only "next generation" facility, it would enable the
Europeans to retake the lead in high energy physics research.
In addition to the LHC, the Soviets, Japanese and Chinese have
large particle accelerators under construction, all of which will
be very expensive. Of these, only the Soviet accelerator at
Serpukhov would be a competitor for the LHC.
Recognizing the cooperative character of research in high energy
physics, the SSC has been designed to be a facility operating
within the traditions of international scientific collaboration
in high energy physics experiments. The SSC will be operated by
DOE for the benefit of all qualified scientific users, foreign
and domestic.
As currently envisaged the SSC will be a truly international
facility, with mutual and equitable contributions and benefits
shared by the participating nations. Depending upon the nature
and extent of their financial commitments, the participating
nations will be allocated an appropriate share either in the
development or management structure of the SSC.
The SSC should provide many incentives for participation by
foreign countries. In addition to the prestige associated with
involvement in the world's largest frontier science facility,
collaboration on the SSC will provide unique educational
opportunities for young scientists and valuable engineering
experience on challenging, state-of-the-art systems.
In addition, options currently under consideration in the
organization of the SSC Laboratory which could help stimulate
greater foreign investment may include a seat on the Board of
Overseers, special recognition of country contributions, seats on
advisory committees, management positions, appointment of
distinguished fellows/professors, and direct hire of foreign
professional nationals.
The major potential contributing foreign countries include Japan,
Canada, Italy, France, Federal Republic of Germany, South Korea,
India, and Switzerland. These same countries are also expected
to contribute detectors for specialized experiments and, perhaps,
operating funds once the SSC facility has been completed and is
in operation. Formal international cooperative agreements will
be pursued in the immediate future through diplomatic channels
once the current interagency plan for International Cooperation
on the Superconducting Super Collider has been cleared.
THE WHITE HOUSE
WASHINGTON
August 31, 1989
INFORMATION
MEMORANDUM FOR THE PRESIDENT
FROM:
D. Allan Bromley
SUBJECT: Background Information on the Superconducting Super
Collider (SSC)
I. SUMMARY
The SSC is a large, expensive, accelerator construction
project requiring over $1 billion in funds from other
nations for completion. It is the single largest research
instrument ever proposed. A complete background on what the
SSC is, how it fits within the spectrum of currently
designed or in-use high energy physics particle accelerators,
and a sketch of present plans for international cost-sharing
is presented.
II. DISCUSSION
Attached is a fairly long paper on high energy physics and
the SSC construction project; the key aspects are covered in
a one page summary. The major reason for providing you with
this information at this time is that, as noted in my recent
memorandum, OSTP staff have been informed of the possibility
that the Japanese Prime Minister will bring up with you the
issue of his country's financial participation in the SSC.
Several recent developments make this likely:
Both Houses of Congress have finally declared support
for SSC construction.
The SSC Laboratory in Texas has been established and
has begun the real design and development work of the
project.
The leadership in the Japanese Government has changed
to one interested in excellent relations with the
United States.
Several other countries -- including Canada and the
European nations supporting The European Center for
Nuclear Research (CERN) in Switzerland -- are asking
the Japanese for substantial contributions to their own
high energy physics accelerator facilities.
International support for the SSC has been, from the
outset, an integral part of this Administration's proposal
to build this high energy physics facility. Visible
Presidential support for this concept of international
cooperation is essential in such high level meetings as the
upcoming one with the Japanese Prime Minister if the
necessary cooperation and participation are to be obtained.
The Prime Minister needs to be aware of how important you
believe such an agreement would be to both nations: that
this cooperation will benefit both nations not only through
people-to-people exchanges and consequent mutual cultural
understanding but also through the mutual expansion of
mankind's scientific knowledge and horizons.
The SSC promises to take its researchers back to the
conditions existing only tiny fractions of a second after
the initial "Bang of Creation", it promises to resolve one
of the greatest mysteries left in the study of our universe
-- why and how does matter acquire mass? -- and it promises
to take us ever closer to, if not indeed to the realization
of Einstein's dream of a complete understanding of the
structure of all matter and of the forces through which it
acts. This is truly a great adventure and one of the
triumphs of the human intellect.
I would welcome the opportunity to provide you with any
further information regarding SSC and its planned
utilization that you might find of interest.
The Superconducting Super Collider:
A High Energy Physics Facility
Summary
The Superconducting Super Collider (SSC) will be the largest
basic research facility ever built. It will collide two beams of
hydrogen nuclei (protons) together by accelerating them through
nearly 10,000 superconducting magnets in a tunnel 53 miles in
circumference. It will take eleven years to build and cost
almost $6 billión.
Your Administration is committed to the construction of the SSC.
The commitment was made with the understanding that funding the
SSC would not be at the expense of other ongoing science
programs and that one-third of the total project funding should
be provided by non-Federal sources such as the host state and
foreign countries that will. share in the scientific and
technological benefits accruing from the SSC. Cost-sharing in a
project of this size is entirely appropriate since other nations
as well as the U.S. will have access to, and benefit from, the
facility.
The SSC will be a facility operating within the well developed
traditions of international scientific collaboration in high
energy physics experiments. The SSC will be operated by DOE for
the benefit of all qualified scientific users, foreign and
domestic. As currently envisaged, the SSC will be a truly
international facility, with mutual and equitable contributions
and benefits shared by the participating nations. Depending upon
the nature and extent of their financial commitments, the
participating nations will be allocated an appropriate share
either in the development or management structure of the SSC.
The SSC should provide many incentives for participation by
foreign countries. In addition to the prestige associated with
involvement in the world's largest frontier science facility,
collaboration on the SSC will provide unique educational
opportunities for young scientists and valuable engineering
experience on challenging, state-of-the-art systems.
The major potential contributing foreign countries include Japan,
Canada, Italy, France, the Federal Republic of Germany, South
Korea, India, and Switzerland. These same countries are also
expected to contribute detectors for specialized experiments and,
perhaps, operating funds once the SSC facility has been completed
and is in operation.
BACKGROUND
Experimental research in high energy physics involves
accelerating beams of elementary particles - protons and
electrons - essentially to the speed of light, aiming the beams
at various targets, and then studying the new forms of matter
resulting from the collisions. That these new forms of matter
result can be seen by applying Einstein's equation E=mc2. This
relationship implies that the energy of a particle (E) and its
mass (m) are alternate characteristics. The "trick" in high
energy physics is to deliver ever more energy into ever smaller
volumes so that some at least of this energy materializes in the
form of new, previously unknown particles or states of matter.
Thus, in this field there is a continual push to accelerate the
beams of protons or electrons to ever higher energies -- to probe
ever deeper into matter.
To perform such studies, the structure of physicists continuously
push the state of the art of technology. They have developed
advanced detectors, high speed electronics, new concepts in
particle accelerators and new approaches in which beams of
protons (or electrons) are aimed at each other and collide with
twice the energy of either beam.
Federal funding programs supporting such research continually
face the problem of bringing large accelerators and expensive
state-of-the-art detector systems on-line to enable this field to
continue to make progress. Currently our high energy physics
programs support three major U.S. facilities used to accelerate
elementary particles:
Stanford Linear Accelerator Center in California (SLAC)
managed by Stanford University,
Fermi National Laboratory (Fermilab) Batavia, Illinois,
managed by the University Research Associates (URA),
and
Alternating Gradient Synchrotron (AGS) at Brookhaven on
Long Island managed by Associated Universities
Incorporated (AUI).
These facilities are available to all qualified experimenters
from national laboratories and universities and to similarly
qualified foreign scientists. In this country alone, these basic
research programs provide support and operating expenses for 148
experimental groups from 72 universities and laboratories to use
these facilities. (The total American community is about 2,000
to 2,500 professional physicists.)
Fermilab, just outside of Chicago, is currently the most powerful
high energy physics accelerator in the world. It holds the
world's record for accelerator energies at one trillion electron
volts (TeV). Its projected lifetime is ten years or longer,
depending on the wealth of physics it will uncover from
proton-proton collisions.
SLAC, an electron accelerating facility, is also competitive with
the other most powerful electron accelerator in Europe, the Large
Electron Positron (LEP) Ring at CERN in Geneva, Switzerland.
The AGS at Brookhaven, a currently operating joint high energy
and nuclear physics facility, will be the "front-end" for a
unique future new accelerator, called RHIC (Relativistic Heavy
Ion Collider), designed to investigate collisions of large atomic
nuclei. Operating together, the AGS and RHIC will give the U.S.
a nuclear physics capability unmatched in today's world.
The Superconducting Super Collider
The Superconducting Super Collider (SSC) is the name given to the
"next generation" high energy physics accelerator facility. The
main accelerator will have a beam energy of 20 TeV. This is 20
times more than the world's currently most-energetic accelerator
located at Fermilab. The Collider itself will consist of two
rings of superconducting magnets (nearly 10,000 in all) and
associated electrical systems in a common tunnel. The magnets
will channel a beam of protons around the tunnel. The tunnel is
53 miles in circumference. The project also includes the
associated office and laboratory facilities (buildings,
structures, and utilities) required to support the technical
systems.
The total project cost is currently estimated to be $5.9 billion
over 11 years with the facility becoming available to researchers
in FY 1998. This estimate is based on a conceptual design report
that does not take into account, for example, site-specific
features nor the actual difficulty of mass producing super-
conducting magnets and thus the cost estimate is acknowledged to
be very approximate.
The Reagan Administration committed to the project in January
1987. The commitment was made with the understanding that
funding for the SSC would not be at the expense of other ongoing
science programs and that one-third of the total project funding
should be provided by non-Federal sources such as the host State
and foreign countries that will share in the scientific and
technological benefits accruing from the SSC. (See attached.)
Cost-sharing in a project of this size is entirely appropriate
since other nations as well as the U.S. will have access to and
benefit from the facility.
In January of this year, the site for the project was chosen to
be Waxahachie, Texas, thirty miles from Dallas.
It can be argued that the spin-offs from SSC-related research
should be of considerable value to American industry. For
example, U.S. industry does not currently have the capability to
produce superconducting magnets in large quantities. These
magnets can be useful to the "computer chip" industry and the
nuclear medicine instrumentation industry. Currently, only Japan
has this capability but the Europeans are now attempting to
develop it.
Planned Spending on SSC as presented to Congress for FY 1990
(BA $ in Millions)
1988
1989
1990
1991
1992
1993
1994
1995
1996
1997
1998
Totals
Total Project Funding
$33
$99
$278
$593
$694
$750
$760
$832
$882
$833
$140
$5,894
Est. non-Federal Share
0
0
$28
$200
$200
$300
$300
$300
$300
$172
0
$1,800
Federal Share
$33
$99
$250
$393
$494
$450
$460
$532
$582
$661
$140
$4,094
The detectors necessary for the facility are another example.
They will require both new materials for high radiation
environments and new signal processing techniques and software.
Such electronics will have a myriad of other uses particularly in
defense systems such as are envisioned in current Strategic
Defense Initiative projects. In the past, many if not most, of
the breakthroughs in the signal processing area have come from
basic research projects in the physical sciences.
The SSC, it can also be argued, would be of considerable benefit
to education. Such a facility would inspire young people to
pursue careers in science and technology because of the unique
challenge it would provide both to build and to use in the
pursuit of new fundamental knowledge. Over 100 U.S. universities
are currently projected to utilize this facility.
Congress, State and local governments, leaders of major academic
institutions and some business leaders have expressed strong
support for the SSC and have encouraged the timely construction
of this unique scientific facility.
Finally, several countries including Japan and Italy, after
visits from Department of Energy over the past 18 months, seem
likely to support the project with financial or in-kind
contributions and through participation during construction,
operation, or in the particular experiments carried out in the
facility by highly qualified physicists from these nations.
In short, there will be many supporters for this project both
inside and outside the community it will serve.
International Cost Sharing
Your Administration has proposed that the SSC be located in the
U.S. and built mainly with Federal funds. Of the one-third
non-Federal funding for the project, the State of Texas has
raised $1 billion and offered as much as $700 million to defray
the cost of the construction project. That leaves at least $1
billion to be obtained through international participation in the
project. The high energy physics community has traditionally
been international and cooperative. The increasing costs of high
energy physics accelerators and the number of smaller machines
that have been or will be decommissioned because they are no
longer competitive, will reinforce this tradition.
The SSC is not the only possibility for the "next generation"
high energy physics machine. An upgrade to a European
accelerator -- the so called LEP machine (Large Electron Positron
Ring) at CERN -- to be called the Large Hadron Collider (LHC), is
considered to be a less powerful alternative to the SSC, if the
U.S. would not go forward with current SSC construction plans.
Because LHC would be based upon the existing LEP facility, it
could be built much faster and more cheaply than the SSC.
It would, however, have an energy of only one-third that of the
SSC (i.e., 5-8 TeV) and would have only one-tenth of the possible
collisions thus making very rare forms of matter undiscoverable.
Although the LHC would not be competitive with the SSC, if it
were the only "next generation" facility, it would enable the
Europeans to retake the lead in high energy physics research.
In addition to the LHC, the Soviets, Japanese and Chinese have
large particle accelerators under construction, all of which will
be very expensive. Of these, only the Soviet accelerator at
Serpukhov would be a competitor for the LHC.
Recognizing the cooperative character of research in high energy
physics, the SSC has been designed to be a facility operating
within the traditions of international scientific collaboration
in high energy physics experiments. The SSC will be operated by
DOE for the benefit of all qualified scientific users, foreign
and domestic.
As currently envisaged the SSC will be a truly international
facility, with mutual and equitable contributions and benefits
shared by the participating nations. Depending upon the nature
and extent of their financial commitments, the participating
nations will be allocated an appropriate share either in the
development or management structure of the SSC.
The SSC should provide many incentives for participation by
foreign countries. In addition to the prestige associated with
involvement in the world's largest frontier science facility,
collaboration on the SSC will provide unique educational
opportunities for young scientists and valuable engineering
experience on challenging, state-of-the-art systems.
In addition, options currently under consideration in the
organization of the SSC Laboratory which could help stimulate
greater foreign investment may include a seat on the Board of
Overseers, special recognition of country contributions, seats on
advisory committees, management positions, appointment of
distinguished fellows/professors, and direct hire of foreign
professional nationals.
The major potential contributing foreign countries include Japan,
Canada, Italy, France, Federal Republic of Germany, South Korea,
India, and Switzerland. These same countries are also expected
to contribute detectors for specialized experiments and, perhaps,
operating funds once the SSC facility has been completed and is
in operation. Formal international cooperative agreements will
be pursued in the immediate future through diplomatic channels
once the current interagency plan for International Cooperation
on the Superconducting Super Collider has been cleared.
6822
THE WHITE HOUSE
WASHINGTON
August 31, 1989
MEMORANDUM FOR JOHN R. SIMPSON
Director, United States Secret Service
Department of Treasury
SUBJECT:
Secure Telephones for Former Presidents
In my discussions with former Presidents Reagan, Ford, and
Carter each expressed a desire to talk with President Bush via
a secure telephone. A secure communications network will
facilitate the timely exchange of information on
fast-breaking, sensitive situations, and ensure the privacy of
Presidential conversations.
To assure network compatibility request USSS install a STU-III
in each of the above former Presidents' offices. The
Director, White House Situation Room is the focal point for
this initiative.
Brent Scowcroft
CC: Chief of Staff
Director, White House Military Office
THE WHITE HOUSE
WASHINGTON
September 1, 1989
MEMORANDUM FOR GOVERNOR SUNUNU
FROM:
WILLIAM L. ROPER WOR
SUBJECT:
Status of Americans with Disabilities Act
The Americans with Disabilities Act (ADA) will be the second
order of business when the Senate reconvenes on Wednesday,
September 6. Senator Kennedy's staff hopes the Senate will
finish the bill on Thursday or Friday. The Kennedy staff and the
civil rights community expect our cooperation in ushering the
bill through the Senate in a smooth manner, and may ask that you
or the President contact recalcitrant Senators.
Committee Report
The Kennedy and Harkin staff were most accommodating in the
development of the committee report. After meeting with the
business community and reviewing comments from within the federal
government, we offered 73 changes to a 90 page document. The
Kennedy-Harkin staff accepted 68 of the changes. In sum, it was
a smooth process that produced a document that should alleviate
some of the uneasiness in the business community about what the
legislation requires.
Resolved and Unresolved Issues
One of the issues identified as "open" at the conclusion of
our negotiations with the Senators, intrastate regulation of
telecommunications, has been resolved. It appears that the FCC,
OMB, and the Senate will reach agreement that enforcement would
be through the FCC with a three year implementation period,
rather than the two years allowed in the current draft. The
agreement will be reflected in a floor amendment. We now believe
this issue likely will be resolved early next week.
One remaining issue emerged in our discussions with the
business community about the meaning of the statutory language
and the report - - the business community's uneasiness about
whether self-confessed drug addicts whose addiction does not harm
their workplace performance are within the scope of those
protected by the ADA. It is clear that both addicts whose
current use is determined by a drug test and those whose use
impairs performance are not protected by the ADA.
-2-
While we expressed the view that the ADA cannot be read to
cover the self-confessed addict, the Kennedy-Harkin staff
believes the self-confessed addict is covered. Because we could
not reach consensus, we agreed to disagree.
The business community may seek to amend the ADA to include
language which explicitly allows complete discretion to fire
addicts. We met this week with business groups to explain the
drug-related provisions, including the fact that the business
community's highest priority -- preserving drug testing -- had
been achieved. At the close of the meeting the business
representatives concluded that they needed to consult beyond
Washington before reaching a conclusion. We have not yet heard
their conclusion. This is a most delicate situation, and I will
keep you apprised of its status.
The Kennedy/Harkin staff put together the attached proposed
colloquy on the meaning of the bill language with respect to
drugs. We have shared this colloquy with the business community
and are awaiting their response.
Summary
Next week will be the key time for the ADA bill in the
Senate. It appears that it is set for quick passage. The one
possible problem is the drug provisions in the bill.
In general, the Administration is satisfied with the ADA on
the drug issue. In particular, Bill Bennett's staff is also
satisfied. Given that next week is both ADA week and drugs week,
it will be important that ADA and the Drug Strategy be
consistent. On Tuesday, we hope to determine (1) the current
state of the business community's thinking on this subject, and
(2) Bill Bennett's personal views on ADA's treatment of drug
issues.
CC: Roger Porter
Attachment
Colloquy
Senator (
L: I would appreciate it, Mr. Chairman, if I
could have clarification of an issue of particular concern to
many business owners. As you know, there is currently an
effort underway to establish drug-free workplaces in our
nation. Will anything in the ADA inhibit such efforts? In
particular, if an employer administers a test of illegal drugs,
and refuses to hire all applicants who test positive and fires
all employees who test positive, would such individuals have a
claim of discrimination under the ADA? That is, can we assure
employers that they will not face litigation under the ADA by
current users of illegal drugs and alcohol?
Senator Harkin/Kennedy: Yes, we can assure them of that fact,
because applicants or employees who test positive on a test for
illegal drugs would not have a claim under the ADA. In fact,
the bill deals directly with this issue of concern.
The ADA explicitly states that nothing in the Act
prohibits or restricts either drug testing or empoloyment
decisions taken on the basis of such drug tests. Therefore, an
applicant who is tested and not hired because of a positive
test result for illegal drugs, or an employee who is tested and
is fired because of a positive test result for illegal drugs,
does not have a cause of action under the ADA. The mere fact
that an employer performed a test which actually measured the
current use of illegal drugs, and that the test was positive
for use of illegal drugs, is sufficient to end any alleged
claim. Of course, people who use controlled substances under medical supervision
pursuant to a valid medical prescription, would be unaffected
by this provision of the Act.
So, I think we can assure employers, without hesitation,
that they will not face litigation under the ADA on the part of
current users of illegal drugs and alcohol who test positive on
drug tests administered by the employer.