The purpose of this and the next two installments in the Fair Targets for ESG
Performance series is to look at how market methods — e.g., service payments
and fees — can be applied in novel ways to reduce carbon emissions in the energy
sector without harming the economy. We begin by looking at global goals in the
face of current emissions, why so few tangible results have been produced from
so much high-level political and media attention (Case in point:
COP27
and its predecessors), and what needs to be done to break through the carbon log
jam.
First, some math: Over 99 percent of climate scientists agree that the climate
is warming, and that the primary driver is GHG emissions (Lynas, Houlton and
Perry, 2021). Global net anthropogenic GHG emissions were higher in the past
decade than any previous (IPCC AR6
WGIII,
2022) and higher this past year than ever before. In an effort to keep climate
change below a level that might trigger significant political chaos, economic
displacement and/or social harm, the Intergovernmental Panel on Climate
Change (IPCC) provides two targets for human society to achieve: staying
below a 1.5°C and a 2°C global area-averaged change in surface air temperature
(IPCC AR6 WGIII, 2022). The targets are based on the difference in mean
temperature compared to pre-industrial temperatures, defined as the 50-year
baseline of 1850-1900. Based on the amount of extreme weather events we are
already experiencing with about a 1°C (estimated to be 1.18°C in 2019), the
1.5°C target is clearly preferable; if increasingly ambitious (Matthews et al,
2021).
While several GHGs contribute to climate change, the largest and most well-known
contributor is carbon dioxide (CO2) — which is, for that reason, a widely used
proxy for overall anthropogenic GHGs. As of the end of 2019, historic cumulative
net CO2 emissions were 2,400 GtCO2 in the atmosphere (IPCC AR6 WGIII, 2022). To
meet the 1.5° target, we need to keep total CO2 to about 2,800 GtCO2. Thus,
we need to limit future emissions to around 400 GtCO2 counting from 2020 onwards
(Matthews et al, 2021; Friedlingstein et al, 2021, 2022; IPCC AR6 WGIII, 2022).
That atmospheric accumulation of carbon and other GHGs leads to mean temperature
rise and increasing numbers of extreme weather events is not new news —
scientists have been talking about climate change for 40 years, and the business
world has rallied somewhat around finding solutions: There are numerous other
carbon-focused NGOs in addition to the IPCC; CDP invites companies to share
their carbon-emissions
data;
the Science-based Targets
initiative
has devised technically feasible schedules for industries to reduce their carbon
emissions per unit of output (i.e., the carbon intensity of production); and
Project Drawdown has researched low-carbon,
energy-producing technologies along with their respective startup and
maintenance costs. And there are plenty of conferences dedicated to carbon
awareness and reductions in one form or another — including COP, which has
produced country-specific climate pledges; and Innovate4Climate and the
Global Carbon Markets Conference that focus on regional and private sector
financing.
And, of course, companies, countries and federations of countries have gotten
increasingly involved over the past 20 years. In the EU, day-ahead spot
markets for electricity favor renewable energy producers. China has pledged
to become carbon neutral by 2050. In the US (notwithstanding the Supreme
Court’s disallowance of the EPA as a carbon
regulator,
the Biden administration target for the country is to reduce net GHG
emissions by 50-52 percent below 2005 levels by 2030. Individual states
including
California
and
Washington
have implemented cap-and-trade carbon markets; and corporations are voluntarily
making carbon-neutrality
pledges
with highly variable degrees of ambition.
Despite all this high-level effort, estimates of current total annual human
emissions of CO2 are still increasing and have reached over 44 Gt of CO2 per
year (IPCC AR6 WGIII, 2022). At our current emissions rate, we will bypass
(i.e., miss) the 1.5°C budget in less than ten years! What meaning is there in
pledging to become carbon neutral by 2050 to keep global warming to 1.5°C
when we will have exceeded that level 15 years before any pledges take effect?
The imbalance between aggregate human demand for carbon sinks and the
atmosphere’s remaining supply (i.e., capacity to serve as a sink) is shown in
Figure 1 below.
In modelled pathways that successfully limit temperature rise to either target
(1.5°C or 2°C), global emissions need to peak between 2020-2025. But under
currently implemented policies, global emissions are projected to rise well
beyond 2025 — leading to over a 3°C increase by 2100, according to the IPCC. So,
why have the collective efforts of national governments, NGOs, forward-looking
companies, and citizens had so little impact on curbing carbon emissions? Why is
there such a carbon action log jam?
There are three main reasons why high-level pledges are not translating into
concrete actions (e.g., investments taken by companies):
-
Carbon-neutrality pledges for 2050, made by companies or countries,
are not analytically useful even if we knew and could treat them as if
they were true. This is because what matters for climate change (and what
needs to be aggregated, allocated, projected and targeted) is the cumulative
amount of emitted greenhouse gases. The specifics of a company’s or
country’s carbon-reduction path matter; not just the final
goal.
Therefore, an analytically meaningful pledge that could easily be reported
would be the total tons of carbon emitted annually by the entity between
2020 and 2050: pledged, measured and/or projected.
-
Carbon pledges and self-selected targets do not need to — and in practice,
do not — align with sector, regional or global
targets. To break the logjam, company targets need to align with sector and
regional targets so that, in the same way that the aggregate of state
populations equals the population of the country, the aggregate of company
targets in the energy-producing sector for next year are equal to the
aggregate sector target. This is why there needs to exist an objective
method for converting global, regional and sector targets into fair company
targets.
-
Even if company targets were expressed as cumulative emissions and were
aligned with sector targets, there are no market mechanisms active today
that would push companies to meet their specific targets. The closest are
taxes and cap and trade — but neither mechanism, as currently implemented,
incorporates company-specific targets (that align with aggregate targets)
and the difference between those company-specific targets and actual
performance. As policy tools for behavior change, they are too broad.
If only we could translate global, regional and sector knowledge into fair
targets for individual companies (like personalized workout or diet programs)
that were expressed as annual emissions, and compare actual company performance
with their fair targets, behavior-changing market mechanisms could apply in a
customized way to individual companies based on their performance relative to
their fair targets. This could steer aggregate energy-producing behavior towards
meeting aggregate carbon goals without harming the economy.
For example, one market mechanism could be a broad-spectrum service approach
that imposes fees on those producers whose performance is below their fair
target; is neutral for those producers whose carbon efficiency matches their
fair target; and provides a payment to those producers whose carbon efficiency
exceeds their target. Based on aggregate performance and total energy output,
fair targets could be adjusted on a yearly basis as needed to ensure that
carbon-emissions behavior changes as needed to meet our real aggregate target.
Clearly, this approach assumes that it is possible to compute fair,
company-specific targets.
This is why in our next installment, we describe what it means to be a fair
target; we show how to compute fair targets for companies in the
energy-producing sector based on key attributes of their facilities (e.g., fuel
type, production technology, location, even financial accounting); and we
explain why fair targets provide a much better handle than self-proclaimed
company targets and add needed precision to sector targets for steering energy
production towards carbon neutrality and our aggregate climate goals without
harming our global economy.
Previous articles in this series:
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Erik is a world authority in the field of multidimensional information systems, an internationally recognized expert in the application of logic to information systems, and a well-known innovator in ontologically grounded approaches to AI and socio-economic-environmental (or ESG) applications.
As CTO of Blender Logic, he designed a semantic controller that improves the performance of machine learning applications that was selected as an exemplar of advanced AI algorithms by the DoD's Joint Center for AI (JAIC). Recently, Blender Logic teamed with sciGaia, a Montana-based provider of sustainability services, in order to produce a new generation of wellbeing-based planning systems.
He is the author of "OLAP Solutions: Building Multidimensional Information Systems," which is used around the world in both graduate computer science and MBA programs, and of publications for both scholarly and IT journals.
Rob Lindner is Director at sciGaia and The Movement Collective, based in Montana.
Published Nov 22, 2022 7am EST / 4am PST / 12pm GMT / 1pm CET