BC’s
Old Growth
Forest:
A Last Stand
for Biodiversity
April 2020
Karen Price, Ph.D., Rachel F. Holt, Ph.D., R.P.Bio
and Dave Daust R.P.F., M.Sc.
1

 Contents
6 Summary
12 Context
19 

Analysis methods

22 Results
46 Conclusions

COVER PHOTO JAKOB DULISSE
REPORT DESIGN ERIKA RATHJE
2

3

 Old forests meld light
and dark; their structural
complexity can include large
old living trees, large standing
dead snags, a multi-layered
canopy

4

5

 Current old growth status
Our analysis concludes the following:

Summary

•  The provincial total area of old forest (~13.2 million
hectares) matches our total.

The Province has appointed a task force to
investigate the state of BC’s old growth forest.
The panel will report to government in April 2020.
The old growth task force website1 shows a map of the
old growth forest in BC — and says “Based on government’s
working definition, old-growth forests comprise about
23% of forested areas, or about 13.2 million hectares”.
We have written this report because old growth cannot
be portrayed by a single number or map. Old forest
comes in many forms.
We have used publicly available provincial data and
definitions to examine the status of different types of old
forest found across the province in different ecosystems
(biogeoclimatic variants) and productivity classes. These
distinctions matter because while all forms of old growth
have inherent value, different types provide tremendously
different habitat, functional, cultural, spiritual and timber
values. BC’s globally rare high productivity forests have
particular value for their high biomass, structural complexity and stable carbon storage.

•  The vast majority of this forest (80%) consists of
small trees:
›  ~5.3 million hectares have site index 2 5 – 10m;
another ~5.3 million hectares have a site index
10 – 15m.
›  Small trees characterize many of BC’s natural old
forest types, including black spruce bog forests in
the northeast, subalpine forests at high elevation,
and low productivity western redcedar forests on
the outer coast.
›  Large areas of this old forest type remain because
the trees are too small to be worth harvesting
(under today’s prices).
•  In contrast, only a tiny proportion of BC’s remaining
old forest (3%) supports large trees:

›  These types of forests match most people’s vision
of old growth. They provide unique habitats,
structures, and spiritual values associated with
large trees.
›  Productive old forests are naturally rare in BC.
Sites with the potential to grow very large trees
cover less than 3% of the province. Old forests
on these sites have dwindled considerably due
to intense harvest so that only 2.7% of this 3% is
currently old (see pie chart). These ecosystems
are effectively the white rhino of old growth
forests. They are almost extinguished and will not
recover from logging.
›  Over 85% of productive forest sites have less than
30% of the amount of old expected naturally, and
nearly half of these ecosystems have less than 1%
of the old forest expected naturally. This current
status puts biodiversity, ecological integrity and
resilience at high risk today.

›  ~380,000 hectares have a site index 20 – 25m,
and only ~35,000 hectares of old forest have a
site index greater than 25m.

Old Growth Amount by Productivity Class
Old
Young

SEAN O’ROURKE FOR CONSERVATION NORTH

SI 5 – 10

1  https://engage.gov.bc.ca/oldgrowth/how-much-old-growth-is-in-b-c/
6

SI 10 – 15

SI 15 – 20

SI 20 – 25

SI > 25

2  Site index refers to the height of dominant or codominant trees at age 50; it is used as a measure of site productivity and to
estimate tree growth over time. For example, a site index class of 5 – 10 means tree seedlings will grow between 5 and 10m tall
in 50 years across the range of sites included in the class; similarly, a site index of 20 – 25 means trees are expected to grow
between 20 and 25m tall in 50 years.
7

 Old Growth Location

Key actions include the following:
•  Immediately stop harvesting the rarest of the rare.
›  Retain all old forest in any ecosystem with less
than 10% old remaining in order to preserve
opportunities to implement existing old forest
targets effectively.
›  Focus retention on higher productivity sites and
irreplaceable very old/ ancient forests.

In addition:
The transition from old forest harvest is imminent.
Without immediate action we will lose these globally
priceless values — and still have to deal with a volumebased industry that has not planned ahead for transition.
The provincial government must provide funding,
commitment and management authority to ensure that staff
can implement effective forest conservation. Little human
effort is tasked with protecting old forest values, while
much is focused on harvesting.

›  Where little to no old remains today, focus
retention on productive mature stands,
particularly in places with a long harvest history.

Province’s map

All but tiny trees (SI > 10m)

•  Improve implementation to ensure that old forest
retention protects the last remaining productive old
forests, and protects functional forests for the future.

Projected future status
of old growth
Projecting the effect of current policy increases risk to
very high levels for almost all old forest in the province,
due to very low targets, and the lack of spatial management
in much of the province. Only areas where harvesting
cannot occur due to economics will have lower risk than
predicted, as these areas may not be harvested down to
the minimal target levels. In most areas with productive
forest in BC, risk will be higher than predicted in this
analysis, due to the current lack of effective implementation of old forest policies.
Productive sites (SI > 20)

Conclusions
and recommendations
Productive old forest has almost vanished across BC,
while large areas of low productivity inaccessible old
forest remain in some forest types. Retention of mature
forest is necessary in many ecosystems, particularly those
with long harvest history, to recruit old forest for the
future. Forest policy in BC relies upon the old forest
strategy to maintain biodiversity into the future — yet
that policy fails to maintain ecosystem diversity, thus
posing high risk to biodiversity and carbon storage
now, and higher risk into the future.
8

•  Develop and implement ecologically defensible
targets for old forest (e.g., minimum of 30%).

Current old forest retention targets provide a very low
bar and implementation pushes effectiveness of old forest
policy below even this bar. Priority actions to stop further
loss, and increase retention of representative old forest
must be taken immediately to reduce risk and maintain
and restore values into the future.
The report includes a series of detailed recommendations (see main report) to prevent the loss of the last
of the very rare and highly important productive old
forest, and to manage the remainder of the old forest to a
reduced risk level in future.

The details are complex, but
the big picture answers are
easy and clear. Immediate
action is needed:
Stop the bleed. Immediately
place a moratorium on logging
in ecosystems and landscapes
with very little old forest.

Reduce risk. Immediately
remove the 2/3 drawdown
to match minimum targets in
Biodiversity Guidebook.
Then revise targets based on
science to lower future risk.
Implement intent properly.
Design and revise spatial
OGMAs to capture the best
remaining old forest and
ensure they maintain functional
ecosystems.

JAKOB DULISSE

9

 Forest policy in BC relies
upon the old forest strategy to
maintain biodiversity into the
future — yet that policy fails to
maintain ecosystem diversity,
posing high risk to biodiversity
and carbon storage

TAYLOR ROADES

10

11

 Context
British Columbia’s identity relies on its forests.
BC has a world-famous coastal temperate rainforest, an almost unknown globally-unique inland
temperate rainforest, plus expanses of interior
forests as varied as conifer-deciduous mosaics
in the northern boreal ecosystems, towering
Douglas-fir and ponderosa pine trees scattered
in open grasslands in the south and rugged
mountainous forests.
Old forests provide cultural, social and economic
values, support world-renowned biodiversity, and store
huge amounts of carbon; yet the debate rages about how
much old forest exists, what it looks like, and where and
how much it should be protected.
This report will answer:
•  What types of old forest exist in BC?
•  How much old forest of each type exists in BC?
•  What types of forest are at highest risk today?
•  What actions should be a priority to maintain BC’s
old forest values?

12

JAKOB DULISSE

Why are old forests
important?
Forests develop over centuries and millennia, shaped
by disturbances that leave legacies. As they age, ecosystems change in structure, composition and function.
Recently-disturbed forests are full of light, feeding fast
development of herbs and shrubs; young naturallydisturbed forests are scattered with legacies from
previous forests that add structure. In contrast, many
mid-seral and mature forests are dense, dark and uniform
with little understory; those initiated by forest harvesting
are particularly simple in structure and composition. Old
forests meld light and dark; their structural complexity
can include large old living trees, large standing dead
snags, long downed logs, a multi-layered canopy, horizontal patchiness with canopy gaps that allow understory
growth, and hummocky micro-topography. The structural
complexity creates myriad habitats that, given sufficient
time, support diverse interacting communities of specialists
and generalists — from a rich soil micro-fauna to unique
canopy communities, from berry bushes to devil’s club,
from marten to caribou. These complex old growth
forests play critical ecological functions in harnessing the
sun’s energy through photosynthesis, storing carbon in
large live and dead trees, collecting, filtering, cooling and
transporting water, gathering nutrients from the atmosphere (e.g., via epiphytic lichens), providing nurse logs
for the next generation of trees, and building soil.

BC’s biodiversity depends, in large part, on old growth
forests. The structural diversity and long development
period of old growth forests drive their ecological importance. Forest biodiversity and ecosystem function are
inextricably intertwined. Functional ecosystems sustain
viable populations of adapted species; in turn, natural
biodiversity maintains ecosystem function and resilience.
Functioning old growth forests deliver ecosystem
services valued by people, including food, water, fuel, medicines and timber, recreation and tourism opportunities,
and cultural and spiritual values. Old growth is identified
by First Nations’ people as valued for traditional resource
use and the ability to harvest old growth trees such as
monumental cedar for cultural purposes, as well as for
spiritual and other values. Large landscapes dominated by
a distribution of natural ecosystems, including old forests,
also improve the ability to practice treaty and aboriginal
rights unencumbered by industrial footprint. People worldwide are sustained and nourished by the values found in
standing old forests. And BC’s forest industry has operated
on the accumulated capital created over centuries and
millennia, with old forest still being the primary type of
forest being harvested in this province today.

What types of old
forest exist in BC?
Old forests vary with climate, topography, nutrient and
moisture availability, disturbance history and age. Forest
types look and feel very different; they function differently
and provide different habitats and cultural resources.
At the broadest scale, forest ecosystems in BC are
defined by biogeoclimatic (BEC) zones. Wet and rich
Coastal Western Hemlock (CWH) and Coastal Douglas
Fir (CDF) forests on Vancouver Island grow massive trees
over the millennia between natural disturbances such as
large fire and windstorms. Interior Cedar Hemlock (ICH)
forests that form the inland temperate rainforest include a
high diversity of tree species that grow large on productive ground. Interior Douglas Fir (IDF) and Ponderosa Pine
(PP) forests in the southern interior were once dominated
by large, widely-spaced trees growing in meadows
maintained through frequent ground fires. High elevation

Engelmann Spruce — Subalpine Fir (ESSF) and Mountain
Hemlock (MH) forests grow very old, but rarely reach the
stature of their lower elevation neighbours. On the central
interior plateau, Sub-boreal Spruce (SBS) forests blanket
the landscape with relatively young forests dotted with
relatively rare old lodgepole pine or spruce stands passed
over by wildfire. Climatic variation overlaying landscape
form drives variation in moisture and temperature within
zones to create BEC variants. Combining these diverse
forests into a single old forest statistic hides meaningful
ecological patterns and trends.
Old forest can vary as much within single BEC variants
as among different BEC variants, driven by differences
in moisture and nutrient availability and defined by site
series within BEC variants. Sites within a single BEC
variant can be highly productive, growing large trees
quickly, or unproductive, with small trees growing slowly.
For example, on flat benches on eastern Vancouver
Island, magnificent Douglas-firs grew up to 100m tall;
nearby on rock bluffs, tiny, skinny trees eke out a living
overlooking the ocean. Similarly, in northeast BC, large
white spruce and cottonwoods growing along riparian
corridors differ from the matrix of black spruce muskeg.
These forests clearly provide different values, but are
often classified within the same BEC variant. Even at high
elevations, trees can be impressive in size on some sites
and wizened on others. Combining these different forests
into a single metric is very misleading.

STEPHEN SHARNOFF

13

 JAKOB DULISSE

These photos are illustrative of a range
of productivity in old forests. The low
productivity site (SI 5 – 10m) shows an old
coastal bog forest with small trees, while the
high productivity site in the inland temperate
rainforest (SI > 25) features massive trees.
Across this range — from low through medium
to high productivity — all these old forests
have value, but the biodiversity present, the
structures and functions all differ vastly. The
provincial government lumps all productivity
types together in their descriptions and
management of these forests.
High productivity

Low productivity
14

15

 16

How to maintain
important values?

What is an old
growth forest?

Assessing
ecological risk

Ecosystem representation is the scientific approach to
sustaining ecological integrity by maintaining a sufficient
area of each ecosystem type to support associated
species, processes and functions. Because forest types
support very different processes, functions and species,
effective representation must include all types of forest.
Maintaining ecosystem representation is the only practical approach to maintaining the diversity of habitats and
ecosystem functions because knowledge is insufficient to
maintain all species and functions individually — ecosystems are complex and interdependent and responses to
management are uncertain and frequently non-linear.
High productivity forests matter. These forests
have globally-significant structural complexity, allowing
a large number of species, including culturally important
animals such as grizzly bears and fur-bearers, to coexist.
By accumulating biomass quickly and storing huge
amounts of carbon, wet productive forests also play a
critical role in climate mitigation. They tend to be extremely
poorly represented in protected areas, and have been the
focus of harvest pressure over the last century.
Rare forest types matter. Some forest ecosystems
are common, widely spread over the province (e.g., high
elevation ESSF), while others are very limited in extent
and location (e.g., low elevation dry ponderosa pine dominated ecosystems). Within broad ecosystems, rare types
are valuable; for example, a rare old moist spruce forest
within a sea of younger lodgepole pine provides rare
structural complexity of particular value to biodiversity
in that landscape. High productivity forests are naturally
relatively rare across the province. Targeted harvesting
has made these forests unnaturally rare and at risk.
Low productivity forests matter. These forests
provide habitat for a certain cross-section of biodiversity 
— caribou in the boreal, a diversity of plant species,
cultural values. In general, low productivity forests are
considerably less at risk due to their lower timber value,
though in some parts of the province their condition is
significantly reduced by other industrial disturbances such
as fragmentation by gas development in the north-east.

Ecologically, old growth forests are natural ecosystems
that have developed sufficiently to include the structural
complexity and functional values designed by a landscape’s
natural disturbance regime. Where natural disturbances are
rare, the whole forest can be much older than their oldest
trees. These forests replace themselves over time as
small gaps open and fill with new young trees, providing a
dynamically stable environment for centuries.
Wet coastal and interior forests dominated by cedar
and hemlock stands are good examples of ecosystems
where forests can be many hundreds, if not thousands of
years old, and where the natural amount of old forest is
very high (50 — more than 90% of some landscapes).
In ecosystems with more frequent disturbances, tree age
is more uniform, with veteran trees representing legacies
of past disturbances. Warm, dry forests in the interior of
BC — typically dominated by lodgepole pine, Douglas-fir,
spruce, are examples of forests where old forests naturally
exist over a lower proportion of the landscape (25 – 60%
of the landscape), and where the age of the oldest forest
stands is rarely over 200 – 300 years in age.
In a forest management context, the province of
British Columbia defines old growth forests by simple
and somewhat arbitrary age criteria that vary across
ecosystems based on estimates of historical disturbance
regime. In general, wetter ecosystems are considered
old when older than 250 years and drier ecosystems
when older than 140 years. Age in provincial datasets is
estimated from air photos. Using age to define old forest
is a good start — but it fails to reflect variations in old
growth structure and complexity. In addition, estimated
age can be inaccurate, particularly for low productivity
forests, where short old trees look younger. And defining
old forests as older than 250 years ignores the important
differences between old, very old, and ancient forests.
In temperate rainforests, some forests are many thousands
of years old with structural and species complexity and
time for development far beyond 250 years.

Ecological risk assessment evaluates the chance that management activities (e.g., forest harvesting, road networks),
in combination with natural disturbance (e.g., wildfire, insect
outbreaks), will have important impacts on ecological
function, biodiversity or focal species. While ecosystems
have evolved to be resilient to natural disturbance, additional disturbance through industrial management can lead
to cumulative effects that push ecosystems beyond their
natural variability — so they no longer provide the range or
amount of values and services they did previously.
Understanding how much old forest is ‘needed’ to
maintain the wide range of associated values is a critical
input into risk assessment, and British Columbia has
embraced the scientific notion that managing forests in
relation to their natural patterns is likely the most effective
approach to minimize risk. The basic approach is that
the level of risk to ecological function, biodiversity and
resilience (i.e., the chance that ecological values will be
lost) increases as the amount of old forest decreases
relative to natural amounts.
Conservation science agrees that habitat loss leads
to declines in populations and ultimately loss of species.
In this case, ‘habitat loss’ is defined as changes to seral
stage distribution, particularly because old forest is
always reduced from the natural state by forest management. There is also evidence that changes in biodiversity
and forest structure are linked to shifts in ecosystem
function and resilience. Shifts in function mean that forest
ecosystems can pass a point whereby a particular species
may not be able to recover to former abundance even if
habitat is subsequently increased, and/or that ecosystems
are less able to withstand disturbance and they become
less resilient. Both linear loss, and thresholds are therefore
important to avoid before irreversible harm occurs.
Studies of habitat change suggest that risk to biodiversity and ecological function is low when more than
70% of natural forest remains, high when less than 30%
remains, and moderate between (Figure 1). This “risk
curve” is based on scientific literature from a wide range
of ecosystems and species — from mites in moss mats
to marten in boreal forest. For each particular species,
the data summarise how much loss of ‘habitat’ leads to

STEPHEN SHARNOFF

a threshold population response. Uncertainty about the
shape of the relationship is highest in the middle of the
range — as thresholds vary by ecosystem and species.
Applying the science to forested ecosystems involves
asking how much change in old forest can occur before
there is a population response across a range of species,
likely linked to changes in ecological function and
resilience. Because old forest has a diversity of special
elements and provides long time periods for colonization,
it is home to many specialist and ‘fairly specialist’ species.
BC retains old forest to maintain biodiversity because it is
associated with many species, because it provides many
functions (e.g., cooling water, storing carbon) compared
to younger forest, and because it is systematically
reduced from forested landscapes so is inherently at
risk. However, any seral stage type would show a similar
pattern: losing a large amount relative to natural would
lead to negative responses for organisms that specialize
on these habitats. If forestry decreased the amount of
young or mid-seral relative to natural, organisms that specialize on these seral stages would be at risk. However,
forest management increases rather than decreasing
these habitats. Some organisms depend on young natural
seral stages (e.g., recently burned snags). The risk curve
can be applied to this habitat too, suggesting that risk
increases as naturally-disturbed stands are salvaged.
17

 This risk relationship has been applied to BC’s coastal
forests.3,4 Because the approach relates risk to the
expected natural level of old forest in any ecosystem,
there is no evidence to suggest that the low risk threshold would not apply similarly in different forest types.
However, the high-risk threshold may be higher than 30%
of natural levels for ecosystems where natural disturbance
levels are high because the absolute level of forest may
be very low in these ecosystems. The habitat change/
threshold literature demonstrates that absolute amount
of habitat matters, particularly at low amounts. This
means that in ecosystems with naturally low amounts of
old forest, dropping down to 30% of that small amount
may lead to old forest being so scattered and patchy on
the landscape that it does not provide all the functions

expected from it — for example, security habitat for a
species may be too scattered across the landscape to be
functional if there is very little of it in total. In addition, the
smaller the amount of old forest, the more important it is
that that forest be found in functional patches — this is a
weakness in this analysis, that only the amount, and not
the condition of the remaining forest is assessed.
BC forest policy uses the concept of linking old forest
targets to the natural amount of old forest for individual
ecosystems, but does so in a way that allows a very large
reduction from the natural amount of forest for most
ecosystems in the province, and hence poses high risk to
values. In addition, it does not set a bar on the condition
of that old forest which in some areas may be a critical
gap in potential effectiveness. See Policy Implications.

Risk

High

Analysis methods
We used publicly available provincial data to
examine the amount of old forest in each ecosystem across the province, and compared this to
the amount of old forest that would be expected
under natural conditions.
Ideally, old forest representation analysis would examine individual ecosystems (represented best by site series
within Biogeoclimatic (BEC) variants) to capture differences in forest type. At the provincial scale, such data
are unavailable — and intractable. We therefore chose
to analyse productivity classes within groups of BEC
variants. This is an improvement for reflecting ecosystems
over ‘BEC only’ data, and is an approach used provincially
by the Chief Foresters’ office to determine timber supply
availability.

We used the most recent publicly available forest
inventory data for all analyses.5 We began with the
forested landbase and excluded areas beyond provincial
jurisdiction (private land). We also excluded primarily
non-forested ecosystems including alpine, subalpine
parkland, grassland and shrub dominated ecosystems.6
We defined productivity using site index (potential tree
height at age 50 based on Vegetation Resource Inventory
data) and removed ecosystems with a site index of lower
than 5m, as used by the Province of BC to define Crown
Forest LandBase at the strategic scale.
To capture broad ecosystem type, we analysed data by
biogeoclimatic variant, and lumped variants and subzones
into groups based on moisture class for some analyses
(e.g., SBSm includes SBSmc1, mc2, mh, mk1 etc). Other
classifications would be possible; we chose this method

5  Data are available for some, but not all Tree Farm Licenses
6  Alpine zones (BAFA, CMA, IMA); parkland subzones (subzones ending with “p”); BG, SWB zones

L
H

Low
0

M-H

M

30

L-M
70

100

Percentage of natural amount of ecosystem
Figure 1. Risk to ecological function, biodiversity and resilience based on the amount of an ecosystem remaining relative to
natural amounts. Colours show risk classes used on subsequent maps.

3  Price K, Roburn A, MacKinnon A 2009. Ecosystem-based management in the Great Bear Rainforest. Forest Ecology and
Management 258:495 – 503.
4  Coast Information Team. Ecosystem-Based Management EBM Planning Handbook. 2004.
https://www.for.gov.bc.ca/tasb/slrp/citbc/ebmplan.html
18

19

 About 400,000ha of remaining
old forest have SI > 20m,
representing less than 1%
of BC’s total forest area of
50 million ha.

as simple and transparent. To capture differences in
productivity within broad ecosystem, we analysed old
forest by site index classes (SI > 5, 5 – 10, 10 – 15, 15 – 20,
20 – 25, 25 – 30, > 30), where SI represents potential height
in metres at age 50. We combined classes to reach a total
forest area of > 5,000 ha within units to avoid misleading
results due to small area. Our analysis units hence use
site index groups within BEC groups, aiming to reduce
combining forests with massively different form, function
and human values, an approach very similar to that used
provincially for timber supply analysis.
To improve geographic resolution, we analysed BEC
variants by Landscape Units (areas defined by the provincial government as management units for old forest)
to examine how the condition of old forest varies with
geographic distribution within a BEC unit.
For each unit, we summed the current amount of old
forest following provincial age-based definitions7 for each
biogeoclimatic variant (250+ years for wetter ecosystems,
140+ years for drier ecosystems). We examined both
absolute amount of old forest and the proportion of
each unit that is old. We also examined the proportion
of each unit > 140 years and > 250 years for comparison,
in part because of issues with age unreliability which is

particularly apparent in some ecosystems (e.g., in some
lower productivity areas at high elevation and along the
coast there are known inventory issues because they
are of lower interest for forest harvesting and sometimes
have poor differentiation between mature and older
aged forests).
To assess risk to biodiversity, we estimated the percent
of old forest expected based on natural disturbance and
expressed the amount of current old forest as a proportion of expected old. We used Biodiversity Guidebook
1995 age definitions for BEC variants, and disturbance
rates for all ecosystems except those in the Great Bear
Rainforest, where we used more current information on
disturbance rates from the EBM Land Use Order.
In some cases, the age of old used here is younger than
science now suggests, and often disturbance rates were
over-estimated in the Biodiversity Guidebook (e.g. for wet
ICH ecosystems). In all cases that we are aware of, these
discrepancies will result in increased risk to ecosystems
than our analysis suggests.

7  Biodiversity Guidebook. Province of BC, 1995.

TAYLOR ROADES

20

21

 100

Results

Area (million ha)

80

How much and what
types of old forest
exist in BC?
The answer depends on the broad ecosystem, represented
by BEC variant, and the type within different ecosystems,
represented by productivity. We present results at three
scales: the entire province, BEC zone and BEC variant.
Within all scales, we divide forest into productivity classes.

Old forest at the provincial scale
•  About half of the vast BC landbase, 50 of 95 million
hectares, can grow trees that reach at least 5m tall
in 50 years (SI> 5), with decreasing proportions in
the higher productivity classes (Figure 2).
•  Of the 50 million hectares that grows trees: 30% is
expected to grow very small trees (SI 5 – 10; generally not considered worth harvesting); of that 35%
(~5.3 million hectares) is old today;
›  35% is expected to grow small trees (SI 10 – 15);
of that 29% (~5.26 million hectare) is old today;
›  25% is expected to grow medium sized trees (SI
15 – 20); of that 18% (~2.3 million hectares) is old
today;
›  7% is expected to grow large trees (SI 20 – 25);
of that 10% (~380,000 hectares) is old today;
›  3% is expected to growth very large trees (SI
> 25); of that 2.7% (~35,000 hectares) is old today.
Overall, the proportion of old forest in each site index
class decreases as forest productivity increases (Figure 3).
22

60

40

20

0

The Figure 4 maps (see page 24) show the distribution
of old forest in different productivity classes (green over
a yellow base showing all forest). The top left map shows
old forest in all forested ecosystems (SI > 5). Moving
through the maps, the forest shown represents an
increasingly high productivity range, with a decreasing
total of old forest. The bottom right map shows the
distribution of higher productivity (SI > 20) old forest 
— with hardly any visible on the map. This corresponds
to the relatively small proportion of land that can grow
higher productivity stands, and the vanishingly small
proportion of that land that remains old forest in this
category (see Figure 3 and 4 together). Overall:

SITE INDEX

Area of BC

Forested area

Old Forest

○ 5 – 10 ○ 10 – 15 ○ 15 – 20 ○ 20 – 25 ○ > 25 ○ Non-forest

Figure 2. How much forest, and old forest exists in BC by productivity class as defined by Site Index groups.

Old
Young

•  There are large areas of low productivity old forest,
with short, skinny trees, at high elevations along
mountain ranges on the coast and interior and in
the northeast (Figure 4).
•  Very little old forest of any productivity class
remains on the interior plateau or southern interior.
•  There are scattered pockets of higher productivity
old forest areas in areas of the mainland coast,
some in the inland temperate rainforest and in
valleys in the northeast. Most patches are too small
to be visible at this provincial scale. Overall, about
400,000ha of remaining old forest have SI
> 20m, representing less than 1% of BC’s total
forest area of 50 million ha. This productive old
forest is therefore extremely rare in BC.

SI 5 – 10

SI 10 – 15

SI 15 – 20

SI 20 – 25

SI > 25

Figure 3. Proportion of BC’s forest in each productivity class as defined by site index groups. Of the ~50 million ha of forest,
the area in each SI group (e.g. 5 – 10; 10 – 15) is represented by the area of each circle, and the proportion of each SI group that is
old is shown in green.

23

 Old forest by BEC zone
•  Old forest in any productivity class is very rare in
the CDF, IDF and PP zones; these zones lie nearest
to high human populations and are at low elevation.
Many BECs have less than 5% old forest with others
at < 1% remaining.

The proportion of old forest varies by BEC zone (Figure 5).
•  Most biogeoclimatic zones have a higher proportion of old forest on low productivity sites (Figure
5), and there is a decline in old forest with higher
productivity.

•  Only the BWBS in the northeast of BC has more
than a quarter of productive sites that are old.

•  This pattern is particularly clear in coastal units;
in the CWH and MH 40 – 55% of low productivity
ecosystems (site index 5 – 15m) is old, whereas only
6% of high productivity sites (site index > 20m) is old.
Naturally, over 80% would be expected to be old.

•  All zones except for low productivity forests in the
drier ESSF and BWBS forests have considerably
less old forest than expected based on historic
disturbance regimes (compare columns to lines in
Figure 5).

•  The drier ESSF zone and wetter ICH show a similar
pattern, but proportion of old forest drops more
rapidly between very low (site index < 10m) and low
(site index < 15m) productivity sites.

SI > 5

SI > 10

100

Proportion of old forest (%)

80

60

40

20

SI > 20

○ SI > 5 ○ SI > 10 ○ SI > 15 ○ SI > 20

te
r

r

we
t

dr
ie

SB
S

S

PS

SB

SB

PP

S
M

H
M

F
ID

te
r
we
t

H
IC

H

dr
ie

r

te
r
IC

r
ES

SI > 15

SF
we
t

SF
dr
ie

H
W

ES

C

DF
C

BW

BS

0

Expected

Figure 4. Where is current old forest by productivity class? Old definitions use provincial criteria. Old growth greater than each
site index cut-off is shown in green. Yellow shows all other forest (younger or lower site index).

Figure 5. Amount of old forest in each productivity class within broad ecosystems (biogeoclimatic zone). Floating bars show the
proportion expected to be “old” (provincial definitions) under natural disturbance; for example, ICH drier shows proportion
> 140 years and target for > 140 years while ICH wetter shows proportion > 250 years and target for > 250 years.

24

25

 CWH and CDF > 140 years

CWH and CDF > 250 years

IDF > 250 years

100

100

100

100

80

80

80

80

60

60

60

60

40

40

40

40

20

20

20

20

0

CDFm

CWHx

CWHd

CWHm

CWHw

○ 5 – 10 ○ 10 – 15 ○ 15 – 20 ○ 20 – 25 ○ 25 –30 ○ 30+

CWHv

Expected

0

CDFm

CWHx

CWHd

CWHm

CWHw

○ 5 – 10 ○ 10 – 15 ○ 15 – 20 ○ 20 – 25 ○ 25 –30 ○ 30+

ESSF > 140 years

CWHv

Expected

0

IDFx

IDFd

IDFm

IDFw

○ 5 – 10 ○ 10 – 15 ○ 15 – 20 ○ 20 – 25 ○ 25 –30 ○ 30+

ESSF > 250 years

Expected

0

100

80

80

80

80

60

60

60

60

40

40

40

40

20

20

20

20

ESSFm

ESSFu

ESSFw

○ 5 – 10 ○ 10 – 15 ○ 15 – 20 ○ 20 – 25 ○ 25 –30 ○ 30+

ESSFv

Expected

0

ESSFx

ESSFd

100

80

80

60

60

40

40

20

20

ICHd

ICHm

ESSFw

ESSFv

Expected

ICH > 250 years

100

ICHx

ESSFu

○ 5 – 10 ○ 10 – 15 ○ 15 – 20 ○ 20 – 25 ○ 25 –30 ○ 30+

ICH > 140 years

0

ESSFm

ICHw

○ 5 – 10 ○ 10 – 15 ○ 15 – 20 ○ 20 – 25 ○ 25 –30 ○ 30+

ICHv

Expected

0

0

SBSd

SBSm

SBSu

IDFm

IDFw

Expected

SBS > 250 years

100

ESSFd

IDFd

SBS > 140 years

100

ESSFx

IDFx

○ 5 – 10 ○ 10 – 15 ○ 15 – 20 ○ 20 – 25 ○ 25 –30 ○ 30+

100

0

26

IDF > 140 years

SBSw

○ 5 – 10 ○ 10 – 15 ○ 15 – 20 ○ 20 – 25 ○ 25 –30 ○ 30+

SBSv

Expected

0

SBSd

SBSm

SBSu

SBSw

○ 5 – 10 ○ 10 – 15 ○ 15 – 20 ○ 20 – 25 ○ 25 –30 ○ 30+

SBSv

Expected

Figure 6. Proportion of each unit (site index class within biogeoclimatic variant group) that is old. Floating bars show the
expected amount of old forest based on historical disturbance regimes.

ICHx

ICHd

ICHm

ICHw

○ 5 – 10 ○ 10 – 15 ○ 15 – 20 ○ 20 – 25 ○ 25 –30 ○ 30+

ICHv

Expected

27

 Old forest by BEC variant

Risk to old forest biodiversity

Within BEC zones, in general, dry and moist BEC variants
have less old forest remaining than wet and very wet ecosystems (Figure 6 shows examples for 5 zones). Patterns
vary across zones due to differing natural disturbance
regimes and harvesting history. In the high elevation
ESSF, all moisture classes have similar amounts of low
productivity old forest (70 – 85%); these stands are not
targeted for harvest and experience low natural disturbance. Conversely, wetter CWH variants have more old
low productivity stands than drier variants, likely partly
due to lower rates of natural disturbance in the wetter
variants, and partly to higher harvest history. The amount
of high productivity old forest varies by moisture class in
some zones (e.g., ICH and ESSF have higher amounts in
wet and very wet variants); other zones have uniformly
low levels of high productivity old forest (e.g., CWH and
SBS), likely reflecting harvest history.
The amount of old forest on low productivity sites
is closer to the amount expected based on historical
disturbance. Low productivity ecosystems have more old
forest than expected in several zones. This pattern is due
in part to fire suppression (particularly in the SBS) and in
part to potential overestimation of disturbance regimes
(particularly in the ESSF).8
Site index determined from old growth stands may not
accurately represent the full productivity of a site into the
future — and in fact the province bumps up the estimated
productivity of a stand once it is harvested (this leads to
an increased estimation of volume that can be harvested
today; an assumption that may or may not be fulfilled in
the future). However — although specific stand level Site
Index may not be accurate, we have no reason to believe
that the trends shown through this analysis are incorrect
at a strategic level. Overall, old productive forest, particularly in dry and moist variants, is very very rare and is far
below the level expected naturally almost everywhere in
the province.

The series of maps on page 29 show the distribution of
risk geographically for ecosystems in different productivity
classes, and coloured up for each LU/ BEC combination.
Risk is shown in 5 classes (high to low) comparing the
amount of old forest in each BEC and productivity type
today with that expected naturally. If there is 70% of the
natural amount of old forest, risk is low (green), and if
< 30% of the natural amount of old, risk is high (red), with
three intermediate classes outlined below. Each map shows
a different subset of the forested landbase — in the top left
all forest > 5 SI is shown. There is a range of risk levels:
•  Risk to old forest biodiversity within forests sufficiently productive to grow commercial trees (site
index > 10m) is high in much of the southern interior,
the central plateau, and Vancouver Island (Figure
7). These forests have been disturbed by cumulative
effects of wildfire, insect disturbance and forest
harvest.

SI > 5

SI > 10

SI > 15

SI > 20

•  Low productivity ecosystems have sufficient old
forest to pose low risk to biodiversity in most of the
north of the province, much of the west including
the Great Bear Rainforest, the west coast of Haida
Gwaii, Clayoquot Sound, and in high elevation
forests along mountain ranges (Figure 7).
•  Higher productivity forests have been reduced
sufficiently far from natural amounts that risk to
biodiversity is high for most ecosystems and across
most of the province.
•  Even in areas with considerable low productivity
forest (e.g., coastal mountains), the high productivity forests of the valleys have been harvested.
•  Analyses exclude private land, much of which has
been converted from forest to other uses (e.g.,
Lower Mainland and Peace Valley) or almost completely harvested (e.g., east of Vancouver Island).

Figure 7. Risk to forest biodiversity calculated as the amount of each biogeoclimatic variant within a landscape unit that is
old as a proportion of the amount expected based on historic disturbance regime. Risk classes: > 70% of historic = Low;
58 – 70% = L – M; 44 – 57% = Med; 31 – 43% = M – H; < 30% = High. Landscape units with no forests above a productivity level are
coloured dark grey. Note that the maps show a decreasing amount of forest — the top left includes all forest > 5 SI, whereas the
8  In many places, inventoried areas of old forest before harvest exceed estimates based on disturbance regimes, even in areas with
low wildfire frequency.
28

bottom right includes only risk in LU’s where there is forest with SI > 20.
29

 Proportion of LU x BEC variant units (%)

Looking at LU / BEC combinations (the unit defined by
the province to manage old forest), the number of units
at low ecological risk declines from 32% (1,407/4,373
in forests with a site index of > 5m, to 5% (80/1,583) in
forests with a site index of > 20m (Figure 8).

Table 2. Proportion of landscape units within BEC variant groups with very low amounts of old forest relative to natural
amounts. All cells with more than 0 units are at extremely high risk; colour shows cells with 1 – 32%, 33 – 66%
and > 67% of units with less than the specified amount (< 10% or < 1%) of natural old forest.
< 1 0 % OF NATURAL OLD FOREST
SI > 5

100

○ High

SI > 20

0

1

10

21

○ Medium-High

BWBSm

0

1

3

13

0

0

0

8

○ Medium

BWBSw

3

0

0

100

3

0

0

0

○ Low-Medium

CDFm

88

88

88

94

88

88

88

88

CWHx

85

85

89

90

49

49

53

62

CWHd

38

38

45

64

5

6

8

18

CWHm

8

8

12

32

2

2

2

11

CWHw

3

5

15

77

0

0

5

35

CWHv

4

4

12

73

0

0

1

20

ESSFx

17

36

30

100

7

24

25

100

ESSFd

10

16

36

83

6

12

15

33

ESSFm

45

66

84

87

21

47

71

87

ESSFw

39

57

84

88

9

23

56

83

ESSFv

30

34

44

5

6

19

ICHx

100

100

100

100

100

100

100

100

ICHd

4

4

14

66

0

0

0

20

Table 1. Percent of units (BEC variant x LU) with very low

ICHm

26

33

57

83

8

10

22

61

amounts of old forest.

ICHw

6

10

35

73

2

1

8

44

ICHv

2

4

25

58

0

0

2

48

IDFx

71

71

90

100

42

44

70

100

IDFd

73

74

91

100

37

38

66

97

IDFm

94

94

94

100

78

81

91

100

IDFw

8

9

16

58

4

4

0

17

MHm

3

2

19

83

0

0

5

38

MHw

0

0

0

0

MSx

3

10

46

100

0

2

37

60

MSd

4

6

20

67

1

2

2

31

MSm

7

7

0

0

0

0

PPx

73

90

100

54

71

75

SBPSx

17

30

80

100

4

4

67

100

SBPSd

24

33

80

100

0

0

40

100

SBPSm

13

17

50

67

0

2

24

33

SBSd

6

6

22

56

1

2

4

20

SBSm

2

3

27

45

0

0

5

28

SBSw

56

69

79

90

30

38

54

79

SBSv

44

50

88

100

13

18

50

94

>20

Productivity (Site Index Threshold)

Figure 8. Proportion of biogeoclimatic variants within landscape units at each risk level.

30

SI > 15

26

20

Similarly, looking at LU / BEC combinations — many
units have less than 10% of the amount of old forest
expected naturally (Table 1). The proportion of units
with less than 10% of natural old forest increases with
productivity (reading down the < 10% column in Table
1). In high productivity LU / BEC combinations, more
than two-thirds of units (1090/1583 = 69%) have < 10%
of natural old, nearly half of units (682/1583 = 43%) have
< 1% of natural and more than one-third of units (569/1583
= 36%) have no old forest whatsoever (reading across the
Site Index > 20 row in Table 1).
All biogeoclimatic variant groups except the MHw
(mountain hemlock wet) have landscape units with less
than 10% of the amount of old forest expected naturally,
and all but the MHw and MSm (montane spruce moist)
have units with less than 1% of the amount expected
under natural disturbance (Table 2). Some variant groups
are at higher risk than others, including almost all CDF,
IDF and PP variants, dry CWH, very dry and moist ICH,
dry SBPS and wet SBS. Higher productivity stands within
every LU / BEC combination are always at highest risk.

SI > 10

16

40

>15

SI > 5

3

○ Low

>10

SI > 20

3

60

>5

SI > 15

BWBSd

80

0

SI > 10

< 1% OF NATURAL OLD FOREST

% OF NATURAL OLD FOREST
SITE
INDEX

NONE

< 1%

< 10%

TOTAL
UNITS

> 5

9%

11%

24%

4373

> 10

13%

17%

30%

4016

> 15

23%

27%

44%

2981

> 20

36%

43%

69%

1583

How to read the table: For example, 71% of the LU /
BEC combinations in the IDFx (very dry Interior Douglas
Fir) have less than 10% of the natural levels of old forest.

31

 Across BC, old forest makes up less than 10% of the
total area of a BEC variant within a landscape unit in much
of the interior (Figure 9). Coastal ecosystems generally
have more area in old forest, although, as analyses above
show, these are primarily on low productivity sites.

Figure 9. For all forest with SI > 10m, BEC variants within landscape units that have less than 1%, 1 – 5% and 5 – 10% remaining in
old in the LU / BEC combination. Note this is of the total area, not in relation to naturally expected levels.

32

33

 Higher productivity forests
have been reduced sufficiently
far from natural amounts that
risk to biodiversity is high for
most ecosystems and across
most of the province

34

35

 Method 1: Provincial Targets

9  Actual intermediate and low emphasis areas can vary from 35 – 55% with restrictions.
10  For example, if historic disturbance regime is 250 years, 37% of the landscape is expected to be older than 250 years.
Subtracting 12% for parks leaves 25%. High targets are 75% of 25% = 19%; intermediate are 50% of 25% = 13%; low targets are
drawn down to 1/3 of intermediate targets, hence 17% of 25% = 4.3%.
36

80

60

40

20

○ Retained

r
we
tte
r

ie
S

dr

SB
S

SB

SB
PS

PP

S
M

H
M

ID
F

te
r

r

we
t

ie
dr
H

IC

IC
H

r
we
tte
r

rie

SF

Fd

ES

ES
S

C

W
H

0

C
DF

BC has as a set of policies that are intended to ‘protect’
old growth across the province. In this exercise, we
estimate the amount of old forest for each zone that will
remain in the future - based on the current provincial policy that sets targets for old growth retention. Legal objectives for old growth retention apply to forested Crown
land across BC, either as spatially-defined Old Growth
Management Areas, or through aspatial landscape-level
targets implemented within Forest Stewardship Plans.
Targets were derived in the Biodiversity Guidebook
(1995) and modified in the Landscape Unit Planning
Guide (1999) for most of the Province. “Biodiversity
Emphasis Options” define areas where the Province
determined that ‘acceptable risk’ to biodiversity could

100

BW
BS

How much
old forest will
there be in the
future — based on
current BC policy?

be lower and higher. Based on current policy, about 10%
of the province is expected to be managed with a high
biodiversity emphasis, 45% with intermediate and 45%
with low biodiversity emphasis, although in some areas of
the province, much less than 10% of each zone has a high
biodiversity emphasis option.9 Old forest targets start
with the expected amount of old forest under historic
disturbance regimes, subtract a fixed area assumed to
be in parks (12%), and reduce the result by a percentage
based on biodiversity emphasis.10 In addition, the concept
of ‘drawdown’ was introduced — where only 1/3rd of
the target in low BEO has to be met for three rotations
(allowing the remaining forest to be all harvested and
to grow back to old growth over 240 years). This leaves
many units having a target of 3, or 4.7% for 45% of the
landbase of BC.
We assessed future risk in two ways: first by projecting
policies forward and second by assessing the amount of
forest conserved within spatially defined areas including
protected areas, legally defined OGMAs, no-harvest wildlife habitat areas and other similar zones. We considered
two time periods: the short-term future (next few decades
assuming that logging continues); and long-term future
(> 100 years, assuming that natural disturbance continues
within conserved areas).

For the first method, we applied provincial targets, assuming that 10% of each variant would have retention targets
based on high biodiversity emphasis, 45% on intermediate
and 45% on low biodiversity emphasis. Although regional
targets and implementation strategies vary, only the Great
Bear Rainforest and Clayoquot Sound have significantly
higher targets than those outlined in the Biodiversity
Guidebook / Landscape Unit Planning Guide11 .
Rolling the targets forward in time shows that once
applied, almost all BEC variants will have less than 10%
of their area retained as old forest, with a total average

Proportion of old forest (%)

TAYLOR ROADES

retention target of 9% across BC (Figure 10) — and with
45% of the landbase at very high risk, where individual
targets are down to 3%- 4.7% due to drawdown. This
means that if the forest is harvestable — i.e., if it grows
reasonably sized trees — then it will be harvested down to
this low level of old forest leaving ecosystems at high risk
in all zones, and at very high risk for many of the wetter
ecosystems that naturally would have been dominated by
old forest. This analysis does not apply to the Great Bear
Rainforest, where risk should be lower, at least in some
ecosystems, based on higher targets. However, there
remain implementation issues here that may also fail to
protect productive ecosystems.

Expected

Figure 10. Amount of old forest projected into future based on targets taken from the Biodiversity Guidebook and Landscape
Unit Planning Guide, compared to natural levels for each forest type. Regional targets will vary. Note this does not include
Great Bear Rainforest EBM targets for site series. Note this reflects age of old as > 140, or > 250, so wetter variants (e.g. in the
ICH) have a lower target of older aged forest than drier variants.

11  Note that due to complexity of application, we did not include GBR EBM targets in this analysis. We therefore over-estimate
strategic level risk for the mainland coast GBR region. However, although the EBM targets are intended to be applied at site series
level, in some cases, we are aware that this approach is failing to maintain representative old forest. Actual risk levels for the GBR
ecosystem will depend upon how the targets are implemented and whether the intent of ecosystem representation is met or not.
37

 may be harvested in future. The province assumes that
all forest will be harvested, if it is economic to harvest,
unless it is protected. This assessment of policy targets
makes the same assumption.

Method 2: Spatial Protection Areas
The second lens through which to assess the future of
old forest protection is to examine spatially protected
areas of forest, to understand its productivity and age.
We mapped spatially-defined protection zones. The distribution of large protected areas is biased towards higher
elevation and lower productivity ecosystems (Figure 11).

The combination of protected areas and old growth
management areas include over 15% of most BEC zones,
however, less than 5% is old forest except in the CWH
and MH (Figure 12). This lack of protected old forest
means that projected risk in the short-term future is high
for most BEC variants (Figure 13). It is also important to
understand that typically, this forest in protected areas
(whether it is old or not) is used towards meeting old
growth targets, so this area is very often double-counted12
and not incremental to the base targets.

Proportion of BEC zone conserved (%)

In every biogeoclimatic zone, these policy targets
represent considerably less than 30% of historic amounts
of old forest and hence on their own, will pose high risk to
biodiversity. Additionally, over time, natural disturbance
will further reduce the amount of old forest, so that
long-term projected old forest amount across BC may be
as low as about 3%.
The province often suggests that the amount of old
forest in the non-contributing landbase is a ‘buffer’ or a
potential ‘safe area’ for old forest even if it is not protected
by policy targets, noting that only a small proportion will
ever be harvested. However, experience tells us that as
we run out of large trees, then we will develop markets for
smaller trees, and similarly as the economics of biofuels
shifts, the areas traditionally considered unharvestable

30
25
20
15
10
5
0

BWBS CDF CWH ESSF ICH

IDF

MH

MS

PP

SBPS

SBS

○ All ages ○ Old forest
Figure 12. Proportion of each BEC zone in conservation zoning (including protected areas, no-harvest wildlife habitat areas and
legally-defined spatial old growth management areas) of all ages and old forest. Note this analysis includes only crown land,
and does not reflect high levels of conversion / private land in some ecosystems (e.g. CDF, PP, IDF).

Figure 11. Conservation zoning applicable to old forest in BC. Includes parks and protected areas, conservancies, no-harvest
wildlife habitat areas and legally-defined old growth management areas (the latter are difficult to see at this scale). Map shows
all forest above site index 10m as green if protected and yellow if not. Pink areas are non-forested or have a site index of less
than 10m. LU/BEC units smaller than 500 ha are not coloured by amount.
38

12  12% is removed from old growth target calculation to account for area assumed to be protected elsewhere; then protected areas
are often assumed to meet the target in implementation, whether or not they are old, effectively double-counting that land area.
39

 •  Inaccurate natural disturbance estimates.
Underestimated time between disturbance could
partly explain the high amounts of lowest productivity forest. We have used improved estimates for
coastal ecosystems where disturbance intervals are
much longer than previously estimated. However, for
some mixed severity ecosystems (in particular MS
and IDF) our analysis of risk likely under-estimates
actual risk in these ecosystems.
•  Missing data. We had access to some, but not all
Tree Farm License data. We suspect that patterns
would not change as we analysed data before
and after obtaining some TFL data and found little
change.
•  Exclusion of Great Bear Rainforest objectives.
Analyses included updated return intervals estimated for the Great Bear Rainforest, but future
projections did not include GBR objectives.
Figure 13. Current risk (duplicated from Figure 7) and projected future risk across BC for BEC variant for forest with a site index
> 10m, reflecting areas that are spatially set aside and protect old forest (including old forest in protected areas, no-harvest
zones and legal old growth management areas. This map does not include Great Bear Rainforest objectives where some areas
are intended to remain at low risk.

Analysis and
interpretation
limitations
These analyses use provincial data and approaches.
The general trends observed have been identified within
many local regions and there is no evidence to suggest
that these broad trends are not a reflection of the current
state of old forest in BC. However, there remain data and
interpretation limitations, including:
•  Ancient forests ignored. Age class (and age
within the BC government data) does not allow
old and ancient to be separately identified. On the
coast and inland rainforests, where some forests are
many thousands of years old and have completely
different biodiversity values, these extremely rare
40

•  Forest condition ignored. Our analyses did not
consider the condition of remaining old forest,
either within or outside Old Growth Management
Areas. Regional analyses in various parts of BC
have demonstrated that much of the remaining old
forest is in small (many less than 2 ha) and fragmented patches, or impacted by a diverse industrial

footprint (e.g., northeast BC) leaving old forest
with very variable functional value. Considering the
condition of remaining forest will generally result in
an increased risk level over our analysis — because
in most places in BC stand condition, interior forest
and functionality are not key parts of deciding
which old forest is used to meet provincial targets.
•  Poor policy implementation. Understanding
future risk based on current targets assumes that the
targets will be met using actual old forest. However,
local analyses have shown that in some regions less
than 20% of the area within OGMAs is actually old
forest, even when old forest exists in the landscape
unit. In many areas, the targets themselves outlined in
policy lead to high risk; poor implementation of this
policy further exacerbates risk.
•  Uncertainty about aspatial implementation. In
about half of the province, ‘aspatial targets’ are used
to meet old forest targets. In these areas, future risk
is impossible to assess (outside protected areas),
because the areas being used to meet the target are
not even known, and cannot be evaluated (either in
this analysis, nor in reality).

forests are a further subset that are likely at considerably higher risk than old forests as defined by
provincial age thresholds.
•  Mis-classified age. Age class can be mis-classified,
especially in low productivity and high elevation
ecosystems where old trees may appear small.
This presents a challenge to understand risk in
these ecosystems; in particular, the amount of
ESSF over 250 years old is likely underestimated in
provincial data, leading to higher risk classification
than warranted in some situations. An alternative
approach to avoid this issue would be to use 140
years to assess ESSF risk. Note however, that the
‘target’ against which risk is assessed must then also
be calculated based on using the same age criteria
(i.e., it is simply wrong to use one age for a target
and another for the amount of old). In general, this
issue affects only a limited subset of ecosystems
(ESSF and MH).
41

 Recommended
priority actions
The current condition of old forest for many forested
ecosystems in BC is low, or very low today, leading to
high or very high risk to ecological function, biodiversity
and ecosystem services. It is expected to further deteriorate given current policy for protection of old forest and
increased disturbance due to climate change.
The historic management approach has allowed the
old growth situation to become a significant problem, and
the situation will only get worse under current provincial
policy. The entire management regime therefore requires
a significant shift in order to fix the problem. Individual
regions around the province are struggling with this
issue — but a higher-level solution is needed.

Immediate Priorities
•  Apply an immediate moratorium on harvest of old
(and mature) forest in any biogeoclimatic variant
with less than 10% old forest remaining today.
These areas are at overall high risk — and in all of
these areas, old forest is being harvested today.
Opportunities are being lost daily for effective
conservation in these zones.
›  CDFmm (all CDF)
›  CWHxm1,2, dm
›  ICHxw, mk3,4, mw1,2,3,4
›  IDFxc, xh1,2,4, xk, xm, xs, xx2, dc, dk1,2,3,4,5,
dm1,2, mw1,2
›  PPxh1,2,3 (all PP)
›  SBPSmk
›  SBSwk1,2,3a
›  And possibly: ESSFxv2, dc1, mh, mv1,2,3,4, wc3,4,
wh3, wk1, wm1,2,3,4 (note potential mis-classification of age in some of these units).
•  Apply an immediate moratorium on harvest of any
old and mature forest in any BEC / Landscape
Unit combination that has less than 10% old
remaining today, including existing cutblock permits.
›  Altogether, 478 LU x BEC units have less than 10%
old forest remaining today, representing 12% of
the total number of LU / BEC combinations.
›  Most of these areas lie within the BEC variants
listed above; a number of others are on Vancouver
Island and on the mainland coast.
•  Focus retention on higher productivity sites due
to their rarity, for their value for carbon storage,
and to counter the loss of these ecosystems due to
biased harvest.

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•  Apply an immediate moratorium to remaining intact
areas with the potential for resilience (e.g., Walbran
on Vancouver Island).
•  Apply an immediate moratorium on harvest of all
irreplaceable old forest including ancient or
very old forest;
›  Appropriate age of very old/ancient forest should
reflect natural disturbance regime and age of
remaining stands, e.g. forests > 500 years on the
coast and wet ICH; forests > 300 years in ecosystems with higher disturbance intervals.
›  Retain all trees and pockets of trees > 300 years
old in ecosystems with no old forest remaining
e.g., dry CWH / dry CDF / dry ICH as wildlife
tree patches with buffers to protect functionality;
recruit the oldest available mature forest where no
old forest remains.
•  Ensure that implementation of old forest
conservation meets intent in lower-risk areas like
the Great Bear Rainforest and Clayoquot Sound.
•  Immediately remove the low Biodiversity
Emphasis Option target “drawdown” that
reduces targets in low biodiversity emphasis option
areas by two-thirds in all zones.
•  Fix arithmetic errors.
›  Stop double-counting protected areas in old
forest targets (either increase targets so that they
are not reduced by the 12% assumed to be in
parks or ensure that sufficient OGMAs to reach
target are located outside parks).
›  Ensure that targets and inventoried old forest use
the same age (i.e., if a target is for forest > 140
years, then measure the amount of forest > 140
years; if the amount of forest > 120 years is measured, then redo the target for 120 years).

›  Apply an immediate moratorium on harvest of any
very high productivity (SI > 20m, perhaps SI > 25m
in the Great Bear Rainforest) old and mature forest.

•  Maintain all moratoria by region or forest district,
until effective spatial planning is in place to ensure
irreplaceable values are not lost.

›  Where little to no old remains today, apply
moratorium to ensure adequate productive mature
stands are maintained, particularly in places with
long harvest history.

•  Place all existing cutblocks on hold in these areas
and ensure they were granted legally.

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 The historic management approach
has allowed the old growth
situation to become a significant
problem, and the situation will
only get worse under current
provincial policy

Mid-term Priorities (within 5 years)
•  Update FRPA objectives and associated regulations
and policy to ensure that biodiversity targets are
based on best available science that considers
resilience and carbon storage.
•  Legally implement minimum targets of 30%
protection by forest type throughout the province.
›  Recognise that to maintain 30% of natural old
forest amounts requires maintaining 30% of the
total forested landscape because natural disturbance will continue.
›  Prioritise protection strategies at the two ends of
the risk spectrum of risk:
»  in areas where irreplaceable old forest exists
today in good condition
»  in areas where very little old forest remains
today to ensure very last old is not lost
›  Identify effective recruitment strategy that meets
old forest targets in the shortest time possible.

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•  Identify remaining ancient forest and include in
OGMAs. Include as larger patches where needed
to ensure future viability. Where single trees or small
patches exist, retain as wildlife tree patches with
buffers.
•  Identify remaining high productivity forest and
include in OGMAs. Include as larger patches
to ensure future viability (e.g., add buffers of
lower productivity forest or high productivity
second growth to ensure interior conditions and
connectivity).
•  Ensure that OGMA target is met with old forest at
all times where it is available. A very minimal level
of younger forest (up to 5%?) could be ‘filler’ to
improve patch size.
•  Map all areas used to meet old forest targets
(OGMAs) spatially.
›  Do not allow OGMAs to be moved; if OGMA
is disturbed naturally (e.g., wildfire), retain as
“natural young area” and add additional area of
old forest as new OGMA.

•  Ensure that forest retained in OGMAs represents
the best old forest available for each zone.
›  Ensure that, at a minimum, OGMAs represent the
full range of natural old forest types/productivity
classes at all scales rather than forest with low
timber value.
•  Ensure OGMAs are functional.

•  Ensure planning in lower productivity ecosystems
is adequate to prevent the same high risk strategy
being applied there, as forest harvesting pressure
switches — as it inevitably will — to these lower
productivity ecosystems.
•  Prioritise provincial scale LiDAR to help identify
patches of higher productivity trees to set aside.

›  Ensure OGMAs are of sufficient size. For example,
OGMAs should be > 10ha minimum, with interior
forest condition, and larger minimal areas in areas
with high natural disturbance. Where old forest is
currently in smaller patches, use these as cores
and buffer with recruitment to meet the minimum.
›  Do not allow harvest in OGMAs.
•  Ensure recruitment of old forest uses the best
available mature forest, to meet old forest targets in
an effective way in a short timeframe.

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 Conclusions
Productive old forest has
almost vanished across BC.
Low productivity
inaccessible old forest
remains in some forest types.
Forest policy in BC does not
maintain the natural range
of ecosystem diversity,
thus posing high risk to
biodiversity and long-term
carbon storage.

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Current old forest targets
provide an ecologically
risky low bar, and
implementation succeeds
in going below this bar
due to loopholes, gaming,
arithmetic errors and simple
lack of monitoring.
Many existing OGMAs do
not contain old forest.
Priority actions to increase
effective retention of
representative old forest
must be taken immediately
to reduce risk.

In many areas, mature
forest must be recruited to
bolster the dwindling ranks
of old forest and to allow
for ecological recovery
over time.
Funding, commitment and
management authority is
required from the provincial
government to ensure
that staff are available to
implement effective old
forest conservation.

The transition from logging
old forest to logging second
growth is imminent. Without
immediate action we will
lose these globally priceless
old forests — and still have
to deal with a volume-based
industry that has not
planned for the transition.
If the provincial government
continues to knowingly put
the ecological integrity
and values of old forest
at risk, they should at the
very least be clear about
their intentions and stop
pretending to protect the
province’s natural heritage.

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