The Water Report - Klamath Basin Science
Dr. T. B. Hardy vs Dave Vogel, Wildlife Biologist
Issue #11 January 15, 2005
In This Issue:
Klamath Fishery Science
Klamath Basin Water Resource Issues
Vogel Response
Hardy Response
KLAMATH BASIN SCIENCE
Editors’ Introduction
Throughout the West, heated debate over the science used to support water
management decisions continues to engage water users, public interest groups,
and the concerned government agencies. [See, Thabault, TWR #9; Luecke, TWR #3;
and Spain, TWR #1] Most of this issue of The Water Report has been dedicated
to a “pointcounterpoint” discussion of the science being applied to
decisions being made in the Klamath River Basin, which spans the southern
Oregon / northern California border.
The Klamath Basin may be reasonably viewed as a microcosm which includes many
of the contending uses currently being addressed in numerous Western river
basins, including: municipal; rural; irrigation; Tribal; hydropower;
fisheries; recreation; federal; and other interests.
Controversy in the Klamath River Basin is not new. Oregon’s adjudication
process to determine pre-1909 water rights in the Upper Basin, for instance,
has been on-going for decades. However, since 2001, when the US Bureau of
Reclamation — faced with a drought-limited water supply — cut off
irrigation water to 90% of the Bureau’s Klamath Project croplands to aid
fish species listed under the federal Endangered Species Act, the
ensuing public protests have been frequently featured in national news media.
The 2001 decision to shut off irrigation water in the Klamath Basin was based
in part on a study by Thomas Hardy that evaluated instream flow needs for coho
salmon in the Lower Klamath River — the “Hardy Phase I Report” (Hardy
Phase I). Hardy Phase I was used as the interim basis for the National Marine
Fisheries Service biological opinion for 2001 Klamath Project Operations.
David Vogel was and is a high profile critic of both
Hardy Phase I and the subsequent Hardy Phase II.
Dr. Hardy and Mr. Vogel generously agreed to have their views on the science
being used to support federal water management decisions in the Klamath Basin
published in The Water Report. After meeting the same deadline for submitting
their initial articles, each author was given two weeks to respond to the
other’s work.
Your editors flipped a coin to determine the order of presentation...
Dr. Hardy holds a PhD in Civil and Environmental Engineering, BS and MS
degrees in Biology and a BS in Secondary Education. He is a member and
Certified Fisheries Scientist of the American Fisheries Society, the American
Society of Civil Engineers, the American Society of Photogrametry and Remote
Sensing, the American Water Resources Association, the International
Association for Hydraulic Research and the International Aquatic Modeling
Group. He is on the Executive Committee of the International Aquatic Modeling
Group, and a member of the Steering Committee of the Ecohydraulics Section of
the International Association for Hydraulic Research. Dr. Hardy is
Associate Director of the Utah Water Research Laboratory at Utah State
University.
Mr. Vogel is a Senior Fisheries Scientist with Natural Resource Scientists,
Inc. in Red Bluff, California. He has a BS in Biology and a MS in Natural
Resources. Mr. Vogel has 30 years of experience which includes one year with
NOAA Fisheries and 14 years with the US Fish and Wildlife Service. He is a
scientific consultant on fishery research and management projects for state
and federal agencies, Indian tribes, municipalities, and water districts. He
has worked on west coast salmon issues for 25 years.
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KLAMATH FISHERY SCIENCE
CONTROVERSY IN THE KLAMATH RIVER BASIN
by Dave Vogel, Senior Scientist, Natural Resource Scientists, Inc.
The controversy regarding Klamath Basin fishery resources is not a recent
event. Controversy has existed for decades. The issues relate to many areas:
economic, social, ideological, ecological, and cultural, among others.
However, when all is said and done, the power to ultimately make the tough
decisions lies within the complex and intertwined political, legal,
regulatory, and scientific processes, the latter of which is discussed here.
My initial exposure to Klamath Basin fishery studies began more than two
decades ago while serving in both temporary and permanent assignments as the
US Fish and Wildlife Service (USFWS) Project Leader overseeing federal
Fisheries Assistance Office operations in northern California. I got my feet
wet (literally) 20 years ago when SCUBA diving and recording underwater video
footage of USFWS research activities on adult salmon migration in the Klamath
estuary and observing the Indian gill netting for salmon. At that time, the
disputes at the forefront pertained to allocation of the salmon harvest among
commercial, recreational, and Indian fishers and the transbasin water
diversion from the Trinity River (a
tributary to the lower Klamath River) to the Central Valley of California.
Today, our most prominent problems focus on water allocation in the Upper and
Lower Klamath River Basin. As customarily defined, the upper and lower Klamath
basins are upstream and downstream of Iron Gate Dam. Much of the present
controversy relates to the competing beneficial uses and the science (or lack
thereof) employed to justify the proposed partitioning of the Basin’s water.
Arguably, the recent catalyst for principal focus on Upper Basin water was the
1997 listing of the Southern Oregon - Northern California Coasts (SONCC) coho
salmon as a threatened species under the federal Endangered Species Act (ESA)
and the resultant ESA federal nexus provided by the US Bureau of
Reclamation’s Klamath Project (Klamath Project) agricultural irrigation
operations in the Upper Klamath Basin. This decision by itself may not have
been deemed so contentious if not for the prior listing of two fish species
(Lost River sucker and shortnose sucker) as endangered in 1988 in the Upper
Klamath Basin. [Note: There are other ESA-listed fish species intertwined with
the Klamath Basin controversies: winter run Chinook salmon, spring-run Chinook
salmon, steelhead trout, and Delta smelt in the Central Valley. Federal
biological opinions on Central Valley Project operations have incorporated the
Trinity River diversions to the Central Valley. For reasons of brevity, those
species will not be discussed in this article.]
Although the watershed supports a wide variety of fish populations,
present-day issues pertain mainly to ESA-listed species and Chinook salmon
(the latter of which is not ESA-listed, but is highly valued among Indians and
sport and commercial fishermen). [Other fish species are relevant (e.g.,
steelhead, green sturgeon, eulochon, lamprey, and others), but are not
discussed here.] This article will emphasize coho salmon issues, although,
because of ESA-caused interrelationships, the Upper Basin suckers will be
included as well. I will also suggest that the science and studies needed in
the Basin to improve resource management and reduce conflicts have been
convoluted as a result of the ESA.
Coho Salmon in the Klamath Basin
An example (among many) of debatable Klamath Basin fishery science topics is
the one pertaining to instream flows in order to maintain and enhance habitats
for young coho salmon. An instream flow investigation on the main stem Klamath
River has been underway for many years (dubbed “Hardy Phase II”). It was
elevated to prominence by the National Marine Fisheries Service’s (NMFS’)
decision to use the study’s draft preliminary results to partially justify
its ESA biological opinion on the Klamath Project’s alleged adverse effects
on coho. Hardy Phase II lacked sufficient data to quantify physical habitat
suitability characteristics for coho fry and, alternatively, used Chinook
salmon fry as a surrogate
for the threatened species. Because of this scientifically weakened
circumstance and incorrect assumptions on the species’ life history
attributes, the agency postulated that high water releases from the Iron Gate
Dam were necessary to “provide necessary and adequate survival levels to
avoid the likelihood of jeopardizing the continued existence of SONCC coho”
(Lent 2001). Specifically, NMFS stated “Under the proposed minimum flows
[from Iron Gate Dam], the amount of suitable physical habitat for these fish
could be dramatically reduced” and concluded that Klamath Project
operations, “would result in decreased carrying capacities for salmonid fry
in the mainstem Klamath River and displacement of fry into less suitable
habitat. Because of weak swimming abilities, fry are not well equipped to seek
suitable habitats after displacement. As a result, the survival of salmon fry
is expected to decrease under the proposed action.” (NMFS 2001) The combined
effect of the NMFS decision coupled with the USFWS’ biological opinion on
suckers resulted in the 2001 controversial shut-off of water deliveries to the
Klamath Project — a first in its 95-year history.
The primary habitats for fry and juvenile coho rearing are within the Klamath
River tributaries, not the main stem (Figure 2). This is attributable to the
fact that most coho spawn in tributaries to the Klamath (Synder 1931, CDWR
1965, Leidy and Leidy 1984, NRC 2004). Habitats for coho are customarily found
in smaller west coast tributaries (Scott and Crossman 1973, ODFW 1996, Flosi
and Reynolds 1991, Moyle 2002) that possess characteristics not found in the
main stem Klamath River. Fry and juvenile coho normally occupy small, shallow
streams where there are more structurally complex habitats (e.g., woody
debris) than are found in larger, mainstream river systems (Vogel and Marine
2000).
NMFS identified 51 tributaries to the Klamath River as important coho habitat
(NMFS 2002).
Klamath Project operations cannot physically influence those principal coho
spawning and rearing habitats. To some degree (depending on specific timing
and magnitude), the Klamath Project can change main stem flows and, therefore,
may affect habitat for adult coho upstream migration and downstream migration
of juvenile fish to the ocean. Contingent on many factors, the influence on
the main stem is attenuated in the reach downstream of the dam. However, very
few coho fry use the main stem. This should have been recognized as an
irrefutable biological fact. As this did not occur, much of the rationale for
implementing the ESA — which has focused on Klamath Project operation
effects on coho fry rearing
in the main stem — is questionable. Lacking supportive scientific data and,
more importantly, ignoring scientific data developed in the Klamath Basin and
other watersheds, the NMFS biological opinions presumed that specific, high
instream flows for coho rearing habitat were necessary in that area to avoid
adverse impacts on Klamath Basin coho populations (NMFS 2001, 2002). This is
one of the primary reasons NMFS concluded that ongoing Klamath Project
operations would jeopardize the continued existence of SONCC coho (Knowles
2002).
The NMFS biological opinions’ premise concerning coho rearing habitat in the
Klamath River was not convincing and subject to considerable scientific debate
for the following reasons:
1) The potential importance of coho rearing habitat in the main stem river was
not empirically
established through scientific research.
2) The biological opinion was in contrast to the preponderance of scientific
evidence developed in other rivers and streams and the known widespread
ecological regularity of rearing habitat characteristics for coho salmon.
3) The main stem Klamath River immediately downstream of Iron Gate Dam does
not contain the known habitat attributes preferred by coho based on the
available data. (Vogel 2003)
Ironically, NMFS’ own status report on the species states: “… coho
typically spawn and rear in small tributaries” (Weitkamp et al. 1995). As a
factual matter, the principal coho rearing habitats are within the numerous
Klamath River tributaries — which is not surprising given the well-knowncharacteristics
of coho rearing habitat (e.g., as previously described and by PMFC 1999, CDFG
2002). Furthermore, researchers have established that young Chinook and
coho salmon do not interact well and use significantly different habitats (Sandercock
1996; Healey 1996). The scientific evidence concerning Klamath Project effects
on coho fry rearing in the main stem Klamath River should not have been
debated to such a high degree, yet the practice remains. In my opinion, the
ESA unnaturally elevated the scientific debate and is stifling or misdirecting
the objective research needed to resolve the resource
conflicts on the river.
Implementation of the ESA in the Klamath Basin and the Federal Nexus
The Endangered Species Act states: “The purposes of this Act are to provide
a means whereby the ecosystems upon which endangered species and threatened
species depend may be conserved… .”
Despite this so-called “ecosystem approach” to species recovery advocated
by the USFWS and NMFS, their actions in the Klamath Basin over the past decade
amply demonstrate that the exact opposite has taken place. Those agencies have
and continue to focused on: 1) a single-species approach; and 2) Klamath
Project operations (Vogel 2004). This unfortunate circumstance has occurred
both in the Lower Basin with threatened coho issues and in the Upper Basin
with endangered sucker issues.
The science related to ESA-listed fish species in the Klamath Basin has
principally centered on federal actions (via ESA Section 7 consultations) and,
therefore, is not comprehensive or objective. The federal ESA nexus has
governed the focus of science in the Klamath watershed; truly objective
science would not be based on federal actions. Federal bureaucrats commit
their attention to those activities where they have the most control,
authority, or funding opportunities, not necessarily in areas where the
greatest benefits to species may be derived. It is not responsible to allocate
the majority of agency resources on efforts that would result in negligible
benefits to species recovery. This circumstance has
often occurred and is a fundamental flaw in the ESA; it diverts valuable
resources away from attention on species recovery.
Upper Basin.
At the time of the two sucker listings in 1988, the Klamath Project was not
identified as
having known adverse affects on the sucker populations. Numerous documents
prior to the listings made it evident that the USFWS would not focus on the
Klamath Project and cited a myriad of other factors limiting the suckers and
their habitats. However, four years later, using limited or no empirical data,
USFWS turned to the Klamath Project as their singular focus. This happened as
a result of the federal nexus and ESA Section 7 consultations. Paradoxically,
since the early 1990s, despite new beneficial, factual evidence on the
improving status of the species and lack of relationship with Klamath Project
operations, USFWS became even more centered on project operations and
increased restrictions on irrigators instead of paying attention to more
obvious, fundamental problems for the
species (Vogel 2004).
Lower Basin.
A similar circumstance occurred with NMFS during and after the 1997 coho
salmon
listing in the Lower Basin. The agency cited reasons to list coho salmon, but
excluded Klamath Project operations as a significant factor affecting the
species. Numerous other major factors limiting the species and its habitats
were cited as problems for recovery. However, shortly following the listing,
and with no supporting data, NMFS chose to center its attention on the Klamath
Project as the principal factor affecting coho salmon. Here again, ESA Section
7 consultations caused the shift in emphasis. This occurred despite
well-documented impacts on salmon that had been caused by other factors [e.g.,
over-fishing, logging, mining (W.M. Kier Assoc. 1991) and habitat degradation
in the tributaries (CH2M Hill 1985, W.M. Kier Assoc. 1991)].
Both agencies adopted a single-minded approach of focusing on Klamath Project
operations to artificially create high reservoir levels and high reservoir
releases. This puzzling, similar sequence of events has yet to be explained.
To date, there have been no compelling, empirical scientific data developed
that would justify changing from an ESA-advocated broad-spectrum approach for
species recovery in the upper and lower basins to a narrow, singular
non-ecosystem-based focus on Klamath Project operations (Vogel 2004).
Adding fuel to the fire, the two fish agencies developed biological opinions
on Klamath Project operations that created conflicts between Upper and Lower
Basin presumed fish needs. The USFWS mandated higher-than-historical reservoir
storage in the Upper Basin for questionable benefits to endangered suckers,
while NMFS mandated concurrent high releases from the same Upper Basin
reservoir for debatable needs of coho salmon. In uncoordinated fashion, they
further exacerbated the scientific uncertainties and difficulties in
implementation of such measures by using different hydrological water year
criteria. Additionally, the two biological opinions adversely impacted water
supplies to the Upper Basin’s National Wildlife Refuges, wetlands, and
surrounding farm land that support habitat and forage for hundreds of
non-listed species.
After external peer review of the two agencies’ actions, it was ultimately
determined that the scientific justifications for high reservoir levels and
high reservoir releases were not supported by empirical scientific evidence.
In fact, the agencies’ actions were contrary to the ESA’s approach for
using “the best available commercial and scientific data” and the ESA’s
so-called “ecosystem-based” approach.
Instream Flow for Salmon in the Main Stem Klamath River
Despite all the scientific research and funds expended on the Klamath River,
no entity has developed any data to support the premise that specific Iron
Gate releases over the past several decades has been a significant factor
limiting Klamath River salmon populations. Anglin (1994), in performing a
USFWS scoping evaluation in the lower river for the Yurok Tribe, concluded
that, “No specific streamflow conditions affecting anadromous fish
production were identified in the lower mainstem Klamath River, with the
exception of drought effects over the last several years.” Another agency
report concluded that,
“The evidence assembled does not indicate that localized flow effects are a
major limiting factor for anadromous fish in the Klamath River.” (NBS 1995).
Primary limiting factors for fish production were believed to be watershed
condition and water quality, degraded physical habitat, and under-escapement
of spawning populations (Anglin 1994). Nevertheless, the most recent attention
has been oriented toward Iron Gate Dam releases; the reason for which I
believe is ESA-driven, not science-driven.
In evaluating the draft Hardy Phase II report (Hardy and Addley 2001)
concerning the recent main stem instream flow study, the National Research
Council’s (NRC) final Klamath report stressed the importance of coho
habitats in the tributaries and the fact that Iron Gate releases would have
negligible effects on coho rearing in the main stem channel:
“The NRC committee read and discussed the draft Hardy Phase II report. The
committee saw the modeling approach as flawed by heavy reliance on analogies
between habitat requirements for Chinook salmon and habitat requirements for
coho salmon. Habitat requirements for Chinook salmon are better known, but the
behavior and environmental requirements of Chinook salmon differ substantially
from those of coho salmon. To the extent that this approach is carried forward
into the final report, the NRC committee’s skepticism about the validity of
the analogy would also be carried forward. In addition, the NRC committee, as
explained elsewhere in this chapter, concludes that rearing of coho in the
Klamath main stem is much less important than rearing of coho in tributaries,
which are the preferred rearing habitat of coho. Thus, the importance that can
be attached to regulation of flows in the main stem is probably less, in the
viewpoint of the committee, for coho than it would be for Chinook, for
example. Because the Hardy Phase II draft report does not deal with the
tributaries, the analysis in the draft Phase II diverged from the
committee’s analysis of the critical requirements for coho.” (NRC
2004)
NMFS’ 2001 biological opinion was flawed by misuse of the preliminary study
results in a “forced” application to the ESA Section 7 consultation for
Klamath Project operations. Additionally, the draft study report had not yet
been issued for external review. If NMFS had not used the draft study results
as a significant justification to argue for higher Iron Gate Dam releases for
coho, the 2001 decision on the Klamath Project water curtailment likely would
not have been so controversial. Nevertheless, NMFS again used the preliminary
study results from a review draft report (Hardy and Addley 2001) in developing
its 2002 biological opinion knowing that the report was not complete and could
change in its final version. Hopefully, the NRC’s peer review will assist in
avoiding such problems in the future.
Historical Iron Gate Dam releases have not been shown, and are unlikely to be
later demonstrated, to limit salmonid populations. Ample scientific research
and factual evidence have proven that a more ecologically-based approach is
needed for fishery restoration. This is particularly true of the Klamath River
Basin where so many elements are known to be limiting anadromous salmonid
production. The question is: What has been the relative effect of the main
stem Klamath River flow management on fish populations among all factors
affecting those populations? The best available information indicates numerous
factors, other than the recent historical flow regime, are of overriding
importance in influencing
Klamath River fishery resources. For example, unlike other watersheds
elsewhere where high flows are limited due to large upstream water storage
projects, Klamath main stem channel forming and maintenance flows have not
likely been a problem for the localized effects of Iron Gate Dam releases
because peak flows have not appreciably changed (CDWR 1981). However, armoring
of riverbed gravels below Iron Gate Dam has been identified as a potential
limiting factor (CDWR 1981, NBS 1995). Retention of gravels behind the
dam, not streamflow, has been among the most likely causes of this problem.
Physical stream channel rehabilitation and gravel replenishment measures have
been
recommended (CDWR 1981).
Given the current understanding of ecosystem-level responses and
state-of-the-art restoration ecology, there is no guaranteed expectation of
significant improvement in overall ecosystem function through measures
implemented on the part of the Klamath Project in isolation from other actions
that may occur elsewhere throughout the Basin. In fact, the National Research
Council’s Advisory Committee on Restoration of Aquatic Ecosystems cautioned:
“Restoration is different from habitat creation, reclamation, and
rehabilitation — it is a holistic process not achieved through the isolated
manipulation of individual elements.” (NRC 1992)
There is a need to shift the current focus to other scientific aspects on
streamflow. For the previously described reasons, the debate over coho rearing
habitats in the main stem Klamath River should subside. However, data on
important factors that may affect the fish populations such as water
temperatures, diseases, and outmigration flow are limited or lacking. For
example, because all juvenile salmonids must migrate from the main stem
channel to the ocean (in some instances over long distances) an objective
examination of a flow regime to accommodate that critical life stage is
warranted. Carefully controlled
experiments conducted by tagging and releasing juvenile fish under different
water operational scenarios would be valuable to test hypotheses of potential
effects of flow and resultant survival and recruitment to the adult life
phase. This focus is supported by the NRC final Klamath Report:
“The committee recognizes that main-stem flow may directly affect the coho
population at the time of downstream migration of smolts. While it is unclear
whether additional water would favor the success of this migration, it is also
clear, even in the absence of modeling, that NMFS can argue, given the absence
of data to the contrary, that there is some probability of benefit for the
smolts to be derived from minimum flows at the time of smolt migration, as
expressed in the NMFS biological opinion of 2002. Adaptive management
principles could be applied to this issue.” (NRC 2004)
I am not aware of any current comprehensive scientific investigations on these
topics in the Basin. Although numerous multi-disciplinary studies (which
include stakeholders) are underway in California’s Central Valley rivers and
elsewhere, they are long overdue for the Klamath basin. Recent successful
research and restoration projects by CALFED have demonstrated the value of
having key stakeholder involvement [see Thabault, TWR #]). Such an effort
should be integrated and placed in context with comprehensive watershed
restoration programs.
Peer Review and the National Research Council’s Klamath Report
Peer review has many forms and functions. It can provide balance and fair
treatment of relevant scientific information. Good science and the best
application of accepted scientific principles demand diversity in perspectives
and opinions. Execution of peer review should not be a facade of
“like-minded” individuals or agencies promoting or protecting their
hypotheses, policies, or positions. Peer review can help examination of data
with clear objectivity using widely accepted, fundamental scientific
principles (Vogel 2004) and help to prevent highly selective use of one-sided
information.
Until recently, many Klamath Basin fishery science issues, research studies,
and management decisions were largely non-peer reviewed. Although the fishery
agencies claimed to have conducted some form of “internal” peer review of
their biological opinions related to Klamath Project operations, they were not
performed in a manner conducive to allowing unbiased scientific review. In
2001, only selected individuals were included in the formulation of the two
final biological opinions that cut off water to the Klamath Project.
Furthermore, only certain information was used by the USFWS and NMFS, and
additional relevant, science-based information was either overlooked or
ignored. The agencies gave
greater weight to theoretical information to support an assumption for high
lake levels and high reservoir releases without acknowledging empirical data
that did not support their premise (Vogel 2002).
Because of the heated controversy over the federal government’s decision to
eliminate water deliveries to the Klamath Project in 2001, the National
Academy of Science was asked by the Department of Interior and Department of
Commerce to “evaluate the strength of scientific support for the biological
assessments and biological opinions on the three listed species, and to
identify requirements for recovery of the species” (NRC 2004). Although the
NRC Klamath committee agreed with many of the agencies’ decisions, after
extensive review, they ultimately concluded that there was insufficient
scientific support for the argument of high lake levels for suckers (Upper
Klamath Lake) and high Iron Gate Dam releases for coho. Notably, the peer
review committee members were unanimous in their conclusions on both
biological opinions.
Many of the most pertinent findings, conclusions, and recommendations of the
NRC Klamath
Committee were not new to the USFWS or NMFS at the time those agencies
developed their biological opinions on Klamath Project operations. The NRC
final report advocates a watershed approach, peer review, greater stakeholder
involvement, oversight of agency actions, focus on factors other than the
Klamath Project operations, reduction of resource conflicts, and incorporation
of the principles of adaptive management toward species recovery. Over the
past decade, much of the same and similar technical findings and
recommendations were reported to those two agencies, but were mainly ignored
(e.g., Vogel 1992, KBWUPA 1993, KBWUPA et al. 1994, KWUA et al. 2001, and
comments by the KWUA on the USFWS and NMFS biological opinions) (Vogel 2004).
Summary
There are recent signs of progress associated with scientific research and ESA
activities in the Basin. However, implementation of efforts toward species
recovery remains uncoordinated between agency programs and lacks meaningful
peer review in many important areas. Some individuals within the agencies are
in a state of denial over the findings and conclusions of the NRC’s final
Klamath report. Additionally, there is a trend among some groups to
spend time and funds unnecessarily on litigation when it comes to ESA issues;
this can result in scientific experts spending more time in court instead of
conducting important field research that may lead to species recovery. This
practice will stifle the scientific advancement of recovery efforts and divert
resources into unproductive venues.
Despite the NRC’s report, USFWS and NMFS still retain too much emphasis on
the Klamath Project (as indicated from the most recent biological opinions)
instead of moving towards a watershed-wide approach (Vogel 2004). The agencies
need to begin focusing on other, more-important factors affecting the species
and use more creative and inclusive methods to satisfy the ESA statute (NRC
2004). If the manner in which the ESA is administered in the Klamath Basin
does not change, it is unlikely that the coho or the suckers will ever be
delisted. This circumstance would not be based on biological reasons, but
caused by
procedural problems with the ESA that can inadvertently steer applied science
away from the most important issues (Vogel 2004).
FOR ADDITIONAL INFORMATION:
References for Preceding Article
Anglin, D.R. 1994. Lower Klamath RiverInstream Flow
Study: Scoping Evaluation for the Yurok Indian Reservation. Department
of Interior. U.S. Fish and Wildlife Service, Vancouver, Washington.
Interagency Agreement No. AG1J5200003. 46 p.
California Department of Fish and Game. 2002. Status Review
of California Coho Salmon north of San Francisco. Report to the California
Fish and Game Commission. April 2002.
California Department of Water Resources. 1965. North Coastal
Area Investigation: Appendix C: Fish and Wildlife. Bulletin No. 136. 364
p.
California Department of Water Resources. 1981. Klamath and
Shasta Rivers Spawning Gravel Enhancement Study. The Resources Agency.
Department of Water Resources, Northern District, Red Bluff, California. 178
p.
CH2M Hill. 1985. Klamath River Basin Fisheries Resource Plan.
For U.S. Department of the Interior.
Flosi, G. and F.L. Reynolds. 1991. California Salmonid Stream Habitat
Restoration Manual. August 1991.
California Department of Fish and Game.
Hardy, T.B. and R.C. Addley. 2001. Evaluation of Interim
Instream Flow Needs in the Klamath River: Phase 2. Draft Final Report.
Institute for Natural Systems Engineering, Utah Water Research Laboratory,
Utah State University, Logan, UT.
Healey, M.C. 1996. Life History of Chinook Salmon (Oncorhynchus
tshawytscha). Pages 313-393 in C. Groot and L. Margolis, eds. Pacific salmon
life histories. UBC Press, Vancouver, BC.
Kier, William M., Associates. 1991. Long Range Plan for the Klamath
River Basin Conservation Area Fishery Restoration Program. The Klamath River
Basin Fisheries Task Force.
Klamath Basin Water Users Protective Association. 1993.
Initial Ecosystem Restoration Plan for the Upper Klamath River Basin with
focus on endangered species recovery and water management improvements.
January 1993.
Klamath Basin Water Users Protective Association, Klamath
County, and Modoc County. 1994. Comments by the Klamath Basin Water Users
Protective Association, Klamath and Modoc Counties, on the draft Upper Klamath
River Basin Amendment to the Long Range Plan for the Klamath River Basin
Conservation Area Fishery Restoration Program and the Long Range Plan. January
17, 1994. 44 p.
Klamath Water Users Association, D.A. Vogel, K.R. Marine, and
A. J. Horne. 2001. Protecting the Beneficial Uses of Waters of Upper Klamath
Lake: a plan to accelerate the recovery of Lost River and shortnose suckers.
March 2001. 39 p.
Knowles, D. 2002. Letter from Donald R. Knowles, Director,
Office of Protected Resources, National Marine Fisheries Service, to Kirk
Rogers, Regional Director, US Bureau of Reclamation, re. NMFS biological
opinion on the Klamath Project operations. May 31, 2002. 2 p.
Leidy, R.A. and G.R. Leidy. 1984. Life Stage Periodicities of
Anadromous Salmonids in the Klamath River Basin, Northwestern California. US
Fish and Wildlife Service. Division of Ecological Services, Sacramento,
California. April 1984. 21 p. plus tables and appendix.
Lent, R. 2001. Transmittal letter from Rebecca Lent, Regional
Administrator, NMFS, to Karl Wirkus, US Bureau of Reclamation on the NMFS
biological opinion regarding the ongoing Klamath Project operations effects on
the SONCC coho salmon. April 6, 2001. 2 p.
Moyle, P.B. 2002. Inland Fishes of California. University of
California Press. 502 p.
National Biological Survey. 1995. Compilation of Phase I
reports for the Klamath River Basin. Prepared for the Technical Work Group of
the Klamath River Basin Fisheries Task Force. Mid-Continent Ecological Science
Center. Fort Collins, Colorado.
National Marine Fisheries Service. 2001. Biological Opinion:
Klamath Project Operations. April 6, 2001. 58 p.
National Marine Fisheries Service. 2002. Biological Opinion:
Klamath Project Operations. May 31, 2002. 102 p.
National Research Council (NRC). 1992. Restoration of Aquatic
Ecosystems. National Academy of Sciences Press, Washington, D.C. 552 p.
National Research Council. 2004. Endangered and Threatened
fish in the Klamath River Basin: Causes of Decline and Strategies for
Recovery. The National Academies Press, Washington, DC. 397 p.
Oregon Department of Fish and Wildlife. 1996. Coho Salmon:
Backgrounder. February 7, 1996. 4 p.
Pacific Fishery Management Council. 1999. Identification and
Description of Essential Fish Habitat, Adverse Impacts, and Recommended
Conservation Measures for Salmon. Amendment 14 to the Pacific Coast Salmon
Plan. PFMC pursuant to National Oceanic and Atmospheric Administration award
number NA07FC0026. 146 p.
Sandercock, F.K. 1996. Life History of Coho Salmon (Oncorhynchus
Kisutch). Pages 397-445 in C. Groot and L. Margolis, eds. Pacific salmon life
histories. UBC Press, Vancouver, BC.
Scott, W.B. and E.J. Crossman. 1973. Freshwater Fishes of Canada.
Fisheries Research Board of Canada, Bulletin 184. 966 p.
Snyder, J.O. 1931. Salmon of the Klamath River, California.
Division of Fish and Game of California. Fish Bulletin No. 34. 30 p.
Vogel, D.A. 1992. Preliminary Assessment of Potential Factors
Limiting Populations of the Lost River Sucker, Deltistes Luxatus, and
Shortnose Sucker, Chasmistes Brevirostris. Vogel Environmental Services. July
1992. 29p.
Vogel, DA. and K.R. Marine. 2000. Comments on the November
21, 2000 draft Biological Assessment for the Klamath Project. Letter to Bob
Davis, U.S. Bureau of Reclamation, Klamath Falls, OR, December 22, 2000.
Natural Resource Scientists, Inc. 5 p.
Vogel, D.A. 2002. Testimony before the before the United
States House of Representatives Committee on Resources, Hearing on HR 2829 and
HR 3705. March 20, 2002. 4 p.
Vogel, D.A. 2003. Salmon Rearing Habitats in the Main Stem
Klamath River. Natural Resource Scientists, Inc. February 2003. 36 p.
Vogel, D.A. 2004. Testimony before the before the United
States House of Representatives Committee on Resources (Subcommittee on Water
and Power), Oversight Field Hearing on The Endangered Species Act 30 Years
Later: The Klamath Project. July 17, 2004. 8 p.
Weitkamp, L.A., T.C. Wainwright, G.J. Bryant, G.B. Milner, D.J. Teel, R.G.
Kope, and R.S. Waples. 1995. Status Review of Coho Salmon from Washington,
Oregon, and California. September 1995. NOAA Technical Memorandum NMFSNWFSC-
24. 258 p.
KLAMATH BASIN WATER RESOURCE ISSUES
HARDY PHASE II
PERSPECTIVES FROM THE CENTER OF THE EVENT HORIZON
by Dr. Thomas B. Hardy, Ph.D, Associate Director, Utah Water Research
Laboratory
Introduction: On Perspectives
Most individuals on the planet know that no two objects may exist at the same
location at the same time. This simple fact of physics in small or great
measure underlies some of the differences in perceptions surrounding the Hardy
Phase II instream flow recommendations. For example, say we have many
individuals (Klamath Basin) observing an event horizon (Hardy, Phase I/II).
Every observer will, by our aforementioned physics fact, have to occupy a
different location (or time). Therefore they must have a different viewpoint
and hence, perceptions of the event. These differences are magnified further
because they are dependent on an individual’s ability to even detect an
event, let alone differing capacities to understand what they are observing.
Two people standing before a radio tower both see the
tower (event), but the one with a working radio perceives something else
entirely. Studies into the mechanisms of cognitive thought clearly show that
perceptions of an event are filtered through an individual’s current frame
of reference (how an event is interpreted based cumulative experience) and
state-of-mind. An individual’s frame of reference and/or state-of-mind is
influenced by such factors as native cognitive abilities, cumulative
experiences, health, preconceptions, expectations, as well as a myriad of
other factors that influence both at any given instant. That there are many
viewpoints, leading to different perceptions, and ultimately expressions via
personal opinions arising from an event like the
Hardy Phase II report should therefore be of no surprise. The proof of these
tenets is easily found by even a casual reading of the local, regional, and
national paper articles, affidavits in the seemingly endless rounds of
litigation, and various web pages dedicated to water and fish issues in the
Klamath River Basin over the last several years.
This article addresses my perceptions of the Hardy Phase II event and
specifically the broad array of diametrically opposing perceptions, which
range from “lack of peer review” to “best available science” to
“junk science.” As the principal author of the report, I am sure that most
will agree that I have a rather unique perspective in that I am at the center
of the event horizon looking out. In essence, I have observed the observers
and their interpretations of Hardy Phase II, expressed across a wide spectrum
of opinions. When I examine press releases, web pages, and many other
forms of communication highlighting these differing perceptions and opinions,
I truly wonder if some are viewing the same event, confusing Phase II
with an X-Files episode (‘The truth is out there’), or when more
pragmatically minded, attribute these differences to that famous line from the
American movie classic Cool Hand Luke, “What we have here is a failure to
communicate.”
In the remaining pages of this article, I will strive to rectify many apparent
misperceptions using well-documented facts from my unique view at the center
of the event while looking out. I fully understand that it is likely a
disparate range of perceptions will exist after reading this
article and that some individuals will continue to dispute the facts. After
all, everyone is entitled to their opinion even if they choose to actively
ignore the fact(s). I suggest we all have a good laugh and remember, “Never
let the facts get in the way of a good controversy.”
Hardy Phase I and Phase II Reports
First, it will be helpful to put both the Hardy Phase I and Phase II efforts
into their proper
perspective(s), that is, from the center of the event looking out. In the
beginning (not to be confused by creation or the big bang), the federal
government and others were actively engaged in the Oregon adjudication of the
Upper Klamath Basin. Within that context, the federal government’s water
needs encompassed wildlife refuges, wild and scenic rivers, several federal
land management agencies operating under numerous congressional mandates
(e.g., the Endangered Species Act; the Organic Act; and the Multiple Use
Sustained Yield Act), tribal water rights, and its inherent tribal trust
responsibilities.
It is the responsibility of the federal Department of Justice to represent the
collective federal interest as the “United States” in these types of
matters. It should be apparent to most that settlement of its federal and
tribal water claims in Oregon would ultimately have a direct bearing on the
amount and timing of water leaving Oregon and flowing into the Lower Klamath
River in California.
I have heard from reliable sources that the same federal government has these
same basic needs, mandates and tribal trust responsibilities downstream of
Oregon in California. Knowing what would be required downstream prior to
agreeing to what will be left upstream seems like a rational based fact to me,
and so I agreed to be of assistance when asked by Uncle Sam to help. I am
reasonably certain that the request for assistance was not predicated on my
photogenic characteristics as evidenced by some of the more recalcitrant web
sites about the Klamath. Furthermore, I am not an expert because I wear a coat
and tie, carry a briefcase and come from out-of-town. To wit, I exclusively
wear Hawaiian shirts and Birkenstocks (yes, even in winter in Utah) and I am
never home enough not to be from out-of-town. As a factual matter, it helps
that I am a recognized national and international expert within this complex
multidisciplinary area of science and engineering. I am, after all, a member
of a National Academy of Science committee reviewing the instream flow program
and technical approaches being proposed by Texas to guide the state in it’s
instream flow and water allocation strategies.
Contrary to urban legend in some parts of the Klamath Basin, I was not asked
to conduct an
“Instream Flow Incremental Methodology” (IFIM) type of study [see
Stalnaker, C., B.L. Lamb, J. Henriksen, K. Bovee, and J. Bartholow. (1995).
The Instream Flow Incremental Methodology – A Primer for IFIM. US Department
of the Interior, National Biological Service, Washington, D.C. Biological
Report 29, March 1995]. An IFIM based study by its very definition would have
required a broad level of stake-holder involvement across a broad spectrum of
private, city, county, state, federal, and nongovernmental organizations, and
to the informed reader, a protracted time frame. This lag-time in particular
would not meet the government’s needs in the adjudication process. Instead,
I was asked to evaluate available existing information and make my best
professional recommendation of the instream flow needs in the Lower Klamath
River. The recommendation (Hardy Phase I) would provide the
government with some rational basis to guide their settlement efforts in the
Oregon adjudication.
My experience over the years in all matters related to instream flow issues
has given me a well developed inner sense to be prescient to the likely
presence of turbulent waters ahead. A feeling rather like what one gets when
standing across the room from a coffee table, having turned off the lights,
then proceeding to walk boldly across the room stopping (preferably) just
short of the table. Most individuals will get a very distinct “feeling” of
impending contact well short of the table that increases in intensity as they
perceive (in total blackness) they are near the table. This sense of impending
contact (I call it a cringe) can be mitigated of course with the use of shin
guards. Given an innate desire to avoid severe
shin trauma, I requested and was granted “permission” to seek technical
assistance and input during Phase I that ultimately carried forward into Phase
II. In our metaphorical world, I sought to protect my shins by assembly of a
technical review team composed of representatives of the US Fish and Wildlife
Service; Bureau of Reclamation; Bureau of Indian Affairs; US Geological
Survey; the National Marine Fisheries Service; the Yurok, Hoopa Valley, and
Karuk Tribes (given the government’s trust responsibilities) ; and the
California Department of Fish and Game as the state level resource management
agency. Note that
this request was limited to entities with legislative or governmental
requirements for management of the aquatic resources, and most importantly
from a technical perspective, extensive on-the-ground experience with the
fisheries resources within the Lower Klamath River. I also made it clear to
the technical team from the outset that I was seeking technical input, and had
a general desire for some form of concurrence within the group if possible,
but at the end of the day, it was my responsibility to make the
recommendations. After all, it would be my shins, not theirs, that would be
vulnerable to contact with the table.
After initiation of Phase I, it became apparent that no site-specific data
from the Lower Klamath River commonly utilized in the modeling and assessment
of physical habitat based needs of the aquatic resources existed upon which to
make recommendations for instream flows. That fact lead to the use of
recognized hydrologic based instream flow assessment methods and the now
famous (or infamous depending on your frame of reference) Hardy Phase I
recommendations. As an important aside, again contrary to many perceptions,
the Phase I work was reviewed by the various technical representatives of the
resource agencies and the general public-at-large within the Klamath Basin
while in draft form.
Comments (where deemed technically defensible and germane to the issue at
hand) were incorporated into the final document and recommendations. Having
clearly recognized the limitations and biases inherent in the estimates
derived from the Phase I work (I am not saying they were wrong or “junk
science”), Phase II was started as a means to obtain the requisite
site-specific data necessary to employ other state-of-the-art instream flow
assessment methods.
The Technical Team (and others) were asked to provided input and technical
peer review for each of the following steps of the Phase II process:
• Study design
• Study reach selection
• Study site selection
• Field methods
• Hydrology modeling
• Hydraulic modeling calibration and simulations
• Water quality modeling
• Species and life stage periodicities
• Species and life stage habitat suitability criteria development and
validation
• Habitat modeling development and validation
• Integration of study results
• Instream flow recommendation methodology
• Preliminary Draft Report
• Draft Report
I will note at this juncture that the Draft Phase II report was sent out for
general public review after receiving and incorporating (where germane) the
technical team comments on the preliminary draft report. I also sent the draft
report to several internationally recognized instream flow experts (all
non-USA based) with no history or vested interest in the Klamath River. I
undertook this independent peer review external to the formal Klamath review
process on my own initiative (I added padding to my shin guards). I have (and
continue) to hear some individuals claim that the Hardy Phase II work lacks
peer review. The basis of this perception is not borne out by the facts.
The Phase II efforts also took on a more collaborative nature with the
technical team. Collaborative modeling efforts were undertaken by US
Geological Survey and the US Bureau of Reclamation for water quantity and
water quality modeling for the Lower Klamath River. The US Fish and Wildlife
Service, the California Department of Fish and Game, and the Yurok, Hoopa, and
Karuk Tribes provided collaborative work on fish distributions, habitat
mapping, habitat suitability curve data collection and analyses, and
miscellaneous supporting fieldwork. As documented in the Hardy Phase II
report, all technical study components — ranging from study design, reach
delineation, study site selection, field
methodology (both physical and biological), hydraulic modeling, and habitat
modeling — were systematically reviewed by the technical team prior to their
adoption and/or implementation within Hardy Phase II. This warrants some
further clarification given the misperceptions of some parties.
The technical review process entailed much more than a simple comment matrix
based on a classical review process of the draft report. Technical team
meetings were typically multi-day events almost on a monthly basis during
Phase II. These meetings involved extensive and detailed discussions (at time
even arguments) on quality of data, methods, analytical and modeling
approaches, and even just plain old differences in opinions. For example,
during the evaluations of the study reaches and site selection, the team
examined the whole lower river and worked through the selection of sites to
the point of where the study site should start and where it should end.
Remember, the team is composed of individuals who have extensive experience on
the river through countless hours of sampling. During the review of the
hydraulic model calibration and simulation results, the team examined the
modeling results for water surfaces and velocities at measured and simulated
flows cross-section - by - cross-section and at times vertical-by-vertical.
This type of intensive review process of the modeling included simulating a
known flow rate at the Trees of Heaven study site and then the team went into
the field to compare the spatial pattern of the velocity predictions against
the patterns of flow in the river at each of the cross sections. The model
worked well, for those who wonder about the outcome of this particular
activity. This level of technical review far exceeds any level of peer review
associated with referred journal articles and is most
like the technical reviews that are undertaken during a litigation process, to
which I am also intimately familiar. This again makes the contentions of
“lack of peer review” and “junk science” ring hollow in my ears.
My own independent peer reviews and Klamath based review process resulted in
comments from 19 agencies, organizations, and individuals comprising 726
individual comments. The vast majority of comments were editorial in nature,
or suggestions for improving clarity (i.e., many are redundant, having been
identified by more than one reviewer). Some comments were inexplicably
recycled from Phase I and had nothing to do with Phase II. Several were
advocacy-based position statements (i.e., nothing to do with technical or
editorial issues) and I will recommend to the submitter(s) that it might be
better to direct these to someone else. The remaining technical-based comments
are, in my experience as a submitter
and as a reviewer for several international peer reviewed technical journals,
typical of those received when submitting an article for publication and
indicative of an article that would be accepted for publication after
revision.
My perception of the scientific credibility of the Phase II work is not as
egocentric or self-serving as some might at first blush conclude, especially
given the oft-heard mantra within the Klamath Basin of “junk science” and
“lack of peer review.” In my admittedly subjective attempt to clarify
others’ view of these perceptions from the center of the event horizon
surrounding the Phase II work, I offer the following facts. The paper Field
Validation of Behavioral Based Physical Habitat Modeling of Chinook Fry in the
Klamath River, extracted from the draft Hardy Phase II report, was presented
at the 5th International Symposium on Ecohydraulics held in Madrid, Spain, on
the 12th-17th of September 2004. The international scientific committee
for the symposium accepted the paper for presentation after peer
review. More pointedly, based on the strength of the paper, which includes the
site-characterization and hydrodynamic modeling approaches used in Phase II,
the paper Validation of Behavioral Based Escape Cover Modeling in the Lower
Klamath River, which expands on the previous paper to include all fry and
juvenile life stages analyzed in the draft report, was solicited for inclusion
in an upcoming special peer reviewed issue of the International Journal of
River Basin Management. Some Klamath reviewers maintain that the habitat
modeling for fry was not scientifically defensible in the Klamath based on
their
observations of fish in different rivers — but to date these reviewers have
not provided Klamath specific data to support that position.
The paper
The Ecological Niche Basis for Envelope Habitat Suitability Curves in Instream
Flow
Assessments was also accepted and presented at the same symposium. This paper,
as the title suggests, lays out the ecological basis for envelope curves and
relies on the results from Phase II as the case example. [Editor’s note: an
“envelope curve” envelops information from distinct sources into a single
curve.] One might conclude that this supports the science behind the
development and use of the generic envelope curves used for some life stages
in the Phase II report that were nonetheless criticized in some of the
technical comments as a non-valid approach. Finally, I gave one of the invited
keynote lectures — Incorporation of Fish Behavior in Physical Habitat Models
— using the Phase II technical work as the basis for the talk. These facts,
as seen from the center of the event horizon, provide a very different
viewpoint relative to those who continue to doubt the scientific credibility
or lack of peer review in Hardy Phase II.
Another way of judging the scientific defensibility of the methods that were
adopted and applied in Phase II is to compare them against some recognized
standard, apart from the peer review elucidated above. I will direct the
readers to the work of the Instream Flow Council (“IFC”— see website:
www.instreamflowcouncil.org/ifchome.htm)
and their publication Instream Flows for Riverine Resource Stewardship (IFC
2004). This book represents nearly five years of dedication from its 16 state
and provincial fish and wildlife agency authors from across the US and Canada,
and reflects one of the outcomes of the federally funded National Instream
Flow Program Assessment (NIFPA). The project
brought together the instream flow coordinators of fish and wildlife agencies
from every state in the United States for the purpose of assessing the
weaknesses, strengths and challenges of each state’s instream flow program.
The effort included a detailed assessment of each state’s instream flow
program that ultimately led to the formation of the IFC to implement many of
the NIFPA recommendations and maintain an international network of instream
flow professionals. An example from the Hardy Phase II work is used as an
example of how to properly validate habitat modeling. Secondly, I would direct
readers to the European Union’s COST 626 program represented by the work of
the European Aquatic Modeling Network (“EAMN”— see website:
www.bygg.ntnu.no/~borsanyi/eamn-web/index.htm).
Scientists and engineers from over 17 countries with the specific objective to
define the state-of-the-art in methods and modeling of riverine habitats
comprise the EAMN. There assessments are contained on the links within their
web pages. Readers taking the time to examine the materials from these two
groups will clearly see that the field collection methods, analytical methods,
modeling approaches and framework for interpretation of the results that were
used in Hardy Phase II are identified as state-of-the-art at the national and
international levels. No Twinkies here.
A few minor facts will also help to dispel (hopefully) some additional
misperceptions about Hardy Phase II. The primary reason the report had not
been finalized after receipt of the peer review evaluations and Klamath review
comments is that the flows provided to me by the federal government had been
developed as part of the Oregon adjudication alternative dispute resolution
process. Unfortunately, permission to use the data (as required by that
process) was not obtained and the government’s request to use the
information after the fact was apparently blocked by one or more of the
parties in the Oregon Klamath Basin Adjudication. Therefore, any of the
information that relied upon these flows (read
recommendations) could not be utilized in a litigative setting — not that
the Klamath suffers from a lack of litigation. Importantly, it was not due to
some technical flaw, nor did it represent junk science or lack of peer review.
In the last few months, I have been provided alternative flows to what was
used in Phase II by the Bureau of Reclamation that would permit the Phase II
analyses to be re-run and the report completed. This work is currently
underway. In addition, Phase II will include an additional evaluation of
instream flow recommendations based on new work within the Bureau of
Reclamation for estimated no-project flows, but are not anticipated to be
ready for my use until at least March 2005.
Meanwhile, the technical team has been broadened to encompass a wider group of
individuals with a technical interest in working toward the next version of
the Phase II recommendations. This team has started from the beginning and
undertaken a technical review of all the Phase II steps outlined above,
engaged in discussions related to various technical comments received during
the draft Phase II review, and reviewed the incorporation of several
additional years of fisheries data and supporting analyses. Although
this second full technical review has yet to lead to any substantive
alteration of the analyses (nor do I anticipate any), I keep in mind that the
public as well as the National Academies of Science will review the updated
Phase II work.
What other people perceive is, of course, dependent on their viewpoint, frame
of reference, and state-of-mind when observing an event. In some way, I hope
that this article has helped to reduce the existing perceived differences in
views based on a fuller understanding of the facts at the center of the event.
In my subjective opinion, the Hardy Phase II work and resulting
recommendations when compared to national and international standards clearly
employed the best available scientific methods under an intense peer review
process. For those who continue to hold a different view, I would suggest that
in this context denial is not a river in Egypt, but an intransigent position
to keep their perceptions consistent with their existing frame of reference.
FOR ADDITIONAL INFORMATION:
Mr. Vogel’s Response:
RE: THE IMPORTANCE OF DIFFERENT PERSPECTIVES AND STAKEHOLDER INVOLVEMENT
“Facts”
As an initial matter, there appears to be a considerable difference in opinion
among some as to what constitutes a scientific “fact” regarding Klamath
River technical issues. For instance, presenting draft study results or draft
computer model outputs at a science conference or in a publication does not
necessarily make the information factual. Additionally, simply because a
person works or contracts for a natural resource agency, doesn’t mean that
what the person writes constitutes reliable scientific fact.
Scientists are generally vigilant to ensure there is a distinction between
what may be considered a fact, hypothesis, opinion, or conjecture. To date,
much of the technical debate on Klamath River instream flows for fish has
focused on differences in scientific opinions, not facts. In particular, some
individuals have adopted the strategy: “If you say it enough, it will become
a fact.”
For example, several years ago, I recall a Klamath River Task Force meeting
where a heated debate ensued between the California Department of Fish and
Game (DFG) and the US Bureau of Reclamation over an issue on Klamath instream
flows. An individual from the DFG expressed the belief that a document with
DFG letterhead should have been considered the authoritative “best available
scientific information” — and therefore a scientific “fact” —
instead of discussing the possible technical merits of the letter’s
contents. That type of attitude is prevalent and has constrained scientific
endeavors on the Klamath River. Agency policies and positions can get in the
way of productive scientific inquiry.
It is usual and customary for researchers to clearly articulate their methods
and openly display results of data collected in their research. This allows
other scientists to determine if the results and conclusions can be
appropriately derived from the methods employed and perhaps replicate the
research to help corroborate or refute the original investigation. The
fundamental nature of science is to always question, seek new knowledge, and
find different ways of studying natural phenomena, a philosophy that has not
been embraced by all on the Klamath River.
Instream Flow Modeling
Much of the recent Klamath instream flow debate has centered on simulating how
fish may respond to hypothetical flow scenarios. Some involved parties have
used draft computer model outputs from the recent instream flow study in an
attempt to justify very high instream flows in a region where it is unproven
that historical flows have limited fish populations. Among numerous reasons,
the topic is subject to debate because the technique of modeling how fish
interact with riverine hydraulics is in its infancy. Often termed a “paper
fish exercise,” meshing computer modeling of hydraulics with predicted fish
behavior is an evolving endeavor. Human interpretation of fish behavior is
limited by the difficulty in collecting unbiased, meaningful data on fish in a
natural setting. This is why instream flow modeling
efforts are sometimes termed “state-of-the-art” and not portrayed as the
final definitive tool to accurately quantify flows for fish. Also, models can
be easily manipulated to derive different outcomes and, consequently, the
outputs can be subject to widely different interpretations. Model parameters
can be “tweaked” to have the outputs show what one wants to see; the
results are only as good as the underlying assumptions. To date, some of the
biological principles on the Klamath flow study have been highly questionable
and, therefore, the model outputs have been justifiably suspect.
There are reasons why modeling fish behavior is a complex task. Observations
of fish in a natural, existing riverine environment are difficult, let alone
predicting fish behavior in future, changed hydraulic conditions. For example,
during the Hardy Phase II fish data collection effort, the workers
understandably had major difficulties in sampling the large river and were
greatly constrained in their ability to acquire biological data for the study.
Based on conducting underwater observations of fish in dozens of rivers for
more than two decades, I and others believe important mistakes were made in
the Klamath fish sampling program that resulted in significant, but
unintentional, bias. Use of alternative sampling and observation techniques
could have minimized that problem. This is one reason, among several, why some
initial biological assumptions on the Klamath River are so radically different
from the
enormous preponderance of scientific research performed on other rivers.
Importantly, written documentation of the principal fish sampling effort and
data collected years ago for the flow study has yet to be completed even in
draft form (only generally verbalized). Given that circumstance, it’s
difficult to see how a report on the overall instream flow study dependent on
those data can be considered “peer reviewed” and factual. It is proper
scientific protocol to first disclose the detailed methods and data before
reviewers can judge the scientific and technical merits of a draft or final
report.
To date, the allegations on presumed fish preferences in the Klamath River
have resulted in draft computer-modeled “idealized” or “optimized”
fish flows that are so high as to flood over the river banks into the
terrestrial vegetation. According to preliminary analyses, that circumstance,
if implemented, would cause the river flows to be seasonally higher than would
be naturally available, absent storage in reservoirs. I suspect that further
examination will reveal that, given ESA constraints in the Upper Basin
previously mentioned, there is insufficient water storage and natural flows to
meet all the perceived needs for fish in the watershed. If the computer
modeling exercise ultimately results in such an outcome, it will
do nothing to advance pro-active efforts toward conflict resolution in the
Basin. Indeed, instead of performing the flow study, it would have been more
cost-effective for those advocating the high instream flows to simply demand
the entire water supply in the drainage. It’s also important to emphasize
that the instream flow study is only one facet of a multitude of issues facing
the Klamath Basin today. There has yet to be a serious comprehensive effort to
bring together the diverse interest groups toward problem resolution.
Interestingly, the Upper Basin and Lower Basin water needs were (arguably)
satisfied for nearly a century until an artificially-induced ESA regulatory
crisis created the present conflict. In that time, there have been years of
high salmon runs and productive agriculture. As previously described, no one
has yet to demonstrate that the historical mainstem Klamath instream flow
regime has been a factor limiting the fish populations; other factors have
been considered to be of overriding importance.
Benefits of Different Perspectives (Scientific and Otherwise)
It may be comforting to be surrounded with like-minded individuals that
eagerly approve one’s work, as long as the outcome is mutually agreeable.
Whether it is real or perceived, many of the involved agencies in the recent
Klamath flow study are believed to be advocates for higher flows without
supporting scientific justification. Having previously worked for the US Fish
and Wildlife Service for 14 years, my experience is that the agency rarely
admits mistakes or changes its position on hotly contested resource topics,
even when confronted with new, valid scientific information contradicting the
agency’s position.
The potential problem of advocacy among scientists has been described by
others:
“An attempt by the scientist to simultaneously be a science information
provider and a position advocate is an inherent conflict of interest.” Mills
(2001)
“Finally, the public should be wary of salmon technocrats offering policy
positions under the guise of science. Many salmon technocrats have strong
personal views on the desirability of restoring wild salmon runs to the
Pacific Northwest, but such beliefs reflect personal values and preferences,
not scientifically derived conclusions. Embellishing such personal views with
the language of science adds a deceiving veneer of credibility.” Lackey
(2000)
Although it is a view not shared by all, I believe the advocacy approach
violates the basic precepts of science. A researcher must be his/her own
worst/best critic. Additionally, for issues of major importance, the
researcher should actively seek other viewpoints and must be willing and
accepting of receiving technical critique of their work (ideally,
constructive), even if the comments are diametrically opposed to the original
research results. No scientist wants to admit their progeny is flawed, but
that is a great benefit of effective peer review: preventing non-objective
parental affection to one’s work. This does not mean that a scientist must
accept all technical criticisms, only those well-founded in scientific
principles. For example, it wasn’t until release of the NRC’s final
Klamath report that the technical underpinnings of alternative scientific
perspectives from the status quo on the Klamath saw the light of day. There
were many individuals that did not welcome the NRC’s final report. However,
both favorable and unfavorable reviews must be examined with objectivity to
ensure the least-biased product useful to other scientists and
decision-makers.
Recent inclusion of other participants into the last part of the instream flow
study efforts, although a welcome gesture (albeit overdue), does not resolve
the most important and inherent problems. The study’s design, assumptions,
selection of sampling sites, and methods were already decided and field data
were already collected making it too late to correct mistakes made in the
early phases. There are three important reasons why other interests and
scientific perspectives would have been valuable in the early portions of the
study. It could have: 1) helped to prevent inadvertent bias in early study
phases that
would carry through to the end product; 2) made it difficult for other
stakeholders to criticize after the fact if they had been part of the process
early on; and 3) developed the critically important element of trust among
diverse stakeholders. In the Klamath flow study, this omission wasn’t a
matter of oversight or lack of stakeholder interest. In fact, other key
stakeholders were purposefully excluded from those early, essential phases of
the field study. In this regard, I believe the flow study effort started on
the wrong foot and was a serious policy mistake caused by the federal
government, not by the study’s participants.
Clearly, another more integrated and inclusive approach for the Basin is
needed to resolve the perceived or real conflicts for water. What’s
currently lacking in the Klamath Basin is group brainstorming among a broad
diversity of individuals, stakeholders, and disciplines. It can be a
productive tool in developing solutions to environmental issues. Such an
approach can bring out fresh new perspectives and serve as a catalyst toward a
wider range of innovative alternatives than if only a limited number of people
are involved (Vogel 1992). After decades of controversy in California’s
Central Valley, agencies and stakeholders embarked on a different path than
that followed on the Klamath. State and federal agencies (CALFED) found that
it was essential to include all the key stakeholders in the process of
resolving conflicts over water. As a result, because of this collaborative
endeavor, major efforts are underway in the Central Valley on ecosystem
restoration and water supply
improvements, among other measures. I and others (e.g., NRC Klamath science
committee, Klamath Water Users Association) have suggested this CALFED-type of
approach for the Klamath Basin because doing so would greatly increase the
chances of conflict resolution. CALFED identified six “solution
principles” which guide their program: affordable, equitable, implementable,
durable, reduce conflicts in the system, and no significant re-directed
impacts. None of these elements can be used to characterize the recent course
on the Klamath. Actually, one could argue that the Klamath has been operating
under the opposite six principles.
In conclusion, I have found that the Basin is composed of numerous
stakeholders and interest groups each having their own legitimate claim in the
Basin’s resources and serious beliefs in how those resources should be
managed. For example, Lower Basin groups have a well-founded, long-term stake
in the fishery resources, whereas the Upper Basin stakeholders have a
well-established basis in land stewardship. Regardless of the stakes or
beliefs, they are valid, not right or wrong. Periodically, some of the groups
attempt to bridge their differences and work toward a common goal. But,
unfortunately, some other interest group or agency subsequently uses a legal,
political, or regulatory mechanism to often
derail that proactive approach and resorts to a strident, divisive stance.
Barring some media outlets that appear to relish portraying a “fish versus
farms” controversy, the true stakeholders sometimes attempt to resolve their
differences at the ground level using a bottom-up approach. They should
continue to advance in that direction because the top-down government method
has not functioned well. It’s difficult to resolve conflicts when only one
side is sitting at the table.
References
Lackey, R.T. 2000. “Restoring Wild Salmon to the Pacific
Northwest: Chasing an Illusion?” In: What We Don’t Know About Pacific
Northwest Fish Runs – An Inquiry Into Decision-Making. Patricia Koss and
Mike Katz, Eds., Portland State University, Portland, OR. p. 91 – 143.
Mills, T.J. 2001. Position Advocacy by Scientists Risks
Science Credibility. Stream Notes. Stream Technology Center, Rocky Mountain
Research Station, Fort Collins, CO. 3 p.
Vogel, D.A. 1992. “Resolution of Environmental Issues in
the Environmental Age” In: Achieving Consensus on Water Policy in
California. Pp. 137 – 147. Edmund G. “Pat” Brown Institute of Public
Affairs. California State University, Los Angeles, CA. 300 p.
Dr. Hardy’s Response to Mr. Vogel’s Initial Article:
Mr. Vogel does an excellent job in highlighting the complex nature of water
allocation issues
throughout the entire Klamath River Basin. In particular, I concur with Mr.
Vogel that unless tributary issues affecting the anadromous stocks are
resolved, the prospects for recovery will remain tenuous. I will not comment
here on issues he discusses pertaining to the Upper Klamath Basin since the
focus of my article is Hardy Phase II. Specifically, I will focus on the
elucidation of facts that, once understood, jeopardize the foundation
underlying Mr. Vogel’s tenets and criticisms related to Hardy Phase II.
Mr. Vogel asserts: “Hardy Phase II lacked sufficient data to quantify
physical habitat suitability characteristics for coho fry and, alternatively,
used Chinook salmon fry as a surrogate for the threatened species. Because of
this scientifically weakened circumstance and incorrect assumptions on the
species’ life history attributes… .”
Factually, insufficient data existed to develop site-specific habitat
suitability curves for coho fry, so a review of available literature curves
was undertaken. These data were reviewed and the corresponding habitat
suitability envelope curve for coho fry were utilized for the analysis of coho
fry physical habitat (see Hardy Phase II Pages 136-138 for source data and
final envelope curves for coho fry). In no circumstance was chinook fry
utilized as a surrogate for coho fry. The Hardy Phase II report makes no
“incorrect” assumptions regarding differences between coho and chinook fry
life history traits and indicates: “… based on the simulation results for
chinook fry and coho fry, and known life history strategies, we believe that
the simulation results to be competent to use in the instream flow
evaluations. Habitat simulation results for coho closely parallel the results
shown for chinook fry in terms of the spatial distribution and magnitudes of
suitable habitat.” (See Hardy Phase II Page 186.)
In the remaining paragraphs of this section of Mr. Vogel’s article, he cites
to a number of studies to support his tenets of “...incorrect assumptions on
species’ life history attributes...” that coho utilize habitats “…that
possess characteristics not found in the main stem Klamath River …very few
coho fry use the main stem. This should have been recognized as an irrefutable
biological fact… .” He goes on to assert that Hardy Phase II
determinations were “…Lacking supportive scientific data and, more
importantly, ignoring scientific data developed in the Klamath basin and other
watersheds…”
Vogel then follows with these three tenets:
“1) The potential importance of coho rearing habitat in the main stem river
was not empirically established through scientific research.
2) The biological opinion was in contrast to the preponderance of scientific
evidence developed in other rivers and streams and the known widespread
ecological regularity of rearing habitat characteristics for coho salmon.
3) The main stem Klamath River immediately downstream of Iron Gate Dam does
not contain the known habitat attributes preferred by coho based on the
available data. (Vogel 2003)” (End quote)
(Please note: Vogel (2003) has not been peer reviewed and contains data mainly
from the
Sacramento River.)
I am reminded of Sergeant Joe Friday in the classic television show Dragnet.
When seeking the truth from a witness would say “All we want are the facts,
ma’am.”
Mr. Tom Shaw, a Supervisory Fishery Biologist in the Arcata US Fish and
Wildlife Service
(USFWS) Office was kind enough to provide the following facts:
• Coho spawning was observed in the main stem Klamath River in 2004 at
locations similar to surveys conducted in 2001.
• In 2004, redds were located in the main channel, split channel, and side
channel areas of the main stem Klamath River, with the majority located
between Iron Gate Dam and the Scott River.
• Coho fry have also been captured in chinook sampling efforts at traps in
the main stem Klamath River located below Bogus Creek, the I-5 Bridge, and
above the Scott River confluence.
• In 2002, over 4,000 fry were captured at these three locations.
Based on juvenile chinook sampling efficiencies, it is estimated that a total
of over 1.2 million coho fry passed these three combined trapping locations,
yet Mr. Vogel asserts ‘… very few coho fry use the main stem.’ During
the chinook fry electrofishing surveys, USFWS have also noted numerous coho
using the edge-water habitats in the main stem cohabitated by chinook
fry/juveniles. I am not disputing Mr. Vogel in that the main spawning and
rearing of coho occur in tributaries, however, one cannot ignore coho in the
main stem Klamath River in the face of these facts and in particular in light
of their listed status under the Endangered Species Act. Nor can one ignore
that they are utilizing many of the same habitats as chinook fry/juveniles,
which supports the assumptions and modeling approaches utilized in Hardy Phase
II.
Mr. Vogel (as well as others) anchor many of their tenets on this quote from
the National Research Council’s (NRC’s) final Klamath report which states:
“The committee saw the modeling [Hardy Phase II] approach as flawed by heavy
reliance on analogies between habitat requirements for Chinook salmon and
habitat requirements for coho salmon. Habitat requirements for Chinook salmon
are better known, but the behavior and environmental requirements of Chinook
salmon differ substantially from those of coho salmon. To the extent that this
approach is carried forward into the final report, the NRC committee’s
skepticism about the validity of the analogy would also be carried forward.”
With all due respect to Mr. Vogel and the NRC Committee, it is a factual
matter (if you read the report) that Hardy Phase II never utilized chinook
habitat requirements for coho habitat requirements in any analogous manner (or
for any other species or life stage for that matter). The Committee (and Mr.
Vogel) simply got it wrong. Different habitat suitability curves for each
species and life stage were used to develop species and life stage specific
habitat versus flow relationships subsequently used in making the flow
recommendations. It is interesting to note, that when I presented ‘Field
Validation of Habitat Modeling in the Lower Klamath River’ (i.e., Hardy
Phase II) at the Lower Klamath Science Symposium
(Humboldt State University, June 7-9, 2004) Dr. Peter Moyle who was a member
of the NRC committee cited above, approached me after the talk and made the
following comment: “That was brilliant and needs to be published in the peer
reviewed literature.” His words not mine!
Mr. Vogel further asserts that the “NMFS’s 2001 biological opinion was
flawed by misuse of the preliminary study results …” and that “... the
draft study report had not yet been issued for external review.” He further
lays claim to this “lack of peer review” in regard to the NMFS’s 2002
biological opinion for the Klamath Project operations. In fact, at the time of
the NMFS’s 2001 (and 2002) biological opinion(s), the modeling results up to
and including the relationships between flow and habitat for each species and
life stage had undergone extensive and critical review as highlighted in the
body of my article. Contrary to Mr. Vogel’s opinion, I believe that given
the level of critical technical review that the Hardy Phase II work was
subjected to prior to NMFS’ formulating their biological opinions, that NMFS
in fact relied on “the best available commercial and scientific data.”
Mr. Vogel puts forward the tenet that no scientific evidence exists that would
support the contention that higher flow releases below Iron Gate Dam would be
of any substantive benefit to the fisheries. In his words “Despite all the
scientific research and funds expended on the Klamath River, no entity has
developed any data to support the premise that specific Iron Gate releases
over the past several decades has been a significant factor limiting Klamath
River salmon populations.” Au Contraire, mon amie! In my analysis of the
flow regimes below Iron Gate Dam in Hardy Phase II, which considered both
physical habitat and water quality, I concluded that the “… assessment of
the temperature simulation results is that flows below 1000 cfs exacerbates
these deleterious temperature conditions and places the anadromous
species at greater ecological risk.” (Hardy Phase II, Page 242).
Mr. Vogel further postulates that to resolve these disparate views of the
importance of flows within the main stem Klamath River that “Carefully
controlled experiments conducted by tagging and releasing juvenile fish under
different water operational scenarios would be valuable to test hypotheses of
potential effects of flow and resultant survival and recruitment to the adult
life phase.” One might argue that just this type of experiment has been
conducted (sans juvenile tagging) within the main stem Klamath River although
the “Law of Unintended Consequences” ultimately determined the outcome. In
August of 2002, flow releases below Iron Gate Dam were 666 cfs (a scary number
for sure) and then rose to 767 cfs during early September. Both flow levels
were well below my ecological risk flow level. By mid-September, the largest
recorded fish kill in the history of the Klamath River occurred where it was
estimated that over 30,000 (including coho) anadromous fish literally went
belly-up. The primary management response was to increase the releases below
Iron Gate Dam to 1,300 cfs in an effort to abate the fish kill. I would submit
to the reader (and Mr. Vogel) that this is pretty strong empirical evidence
that flows (at times) do make a difference in the main stem Klamath River.
Conclusion
Aside from these contentious issues regarding different perceptions and points
of view highlighted above, I believe that Mr. Vogel and I are of one mind.
Specifically, the most fruitful way forward to resolve water allocation issues
in light of salmon recovery efforts is to take a holistic approach where the
Klamath Basin is viewed in its entirety. Furthermore, I agree with Mr. Vogel,
that the way forward will be best served by collaborative efforts aimed at
understanding the science rather than continuation of the polarization that
arises within the litigation arena.
Finally, I leave the reader with a quote from Mark Twain: “Researchers have
already cast much doubt on the subject and if they continue their studies we
shall soon know nothing at all.”
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