Getting real: real options analysis of land use change in a world of price, yield and climate uncertainty
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Date
2016
Authors
Regan, Courtney Michael
Editors
Advisors
Meyer, Wayne Stewart
Bryan, Brett Anthony
Ostendorf, Bertram Franz
Connor, Jeffrey D.
Zhu, Zili
Bryan, Brett Anthony
Ostendorf, Bertram Franz
Connor, Jeffrey D.
Zhu, Zili
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Abstract
The de‐carbonisation of electricity generation systems will be vital in mitigating the worst effects of
global climate change. This will involve the substitution of fossil fuel based generation with
renewable and carbon neutral energy sources such a photovoltaics, wind and biomass.
Internationally, the use of biomass to produce electricity has maintained a market share of
approximately 2% of total global generation over the past 20 years (Evans et al., 2010). However, for
the biomass share of electricity generation to increase, dedicated biomass crops will likely be
necessary on land currently used for traditional agricultural production. Understanding the returns
required by landholders from alternative land uses such as biomass is an important first step in
determining a) the viability of such an industry in any particular region and; b) how policy setting can
facilitate new industries and land use change.
The economics of land use change from agriculture to agro‐forestry based biomass production has
been broadly examined in Australia. However, these studies have largely employed discounted cash
flow analysis (DCF) to determine the profitability of biomass enterprises. Discounted cash flow
analysis is an established way to value land use and management investments which accounts for
the time value of money. However, it provides a static view and assumes passive commitment to an
investment strategy when real world land use and management investment decisions are
characterised by uncertainty, irreversibility, change, and adaptation. Real options analysis (ROA) has
been proposed as a better valuation method under uncertainty and where the opportunity exists to
delay investment decisions, pending more information. When uncertainty and flexibility are
considered, the rates of return required for investing in a new land use can be substantially higher
than suggested by DCF calculations. This has obvious implications for investors and policy makers
alike. However, while investments in biomass agro‐forestry are characterised by uncertainties, risk
and large upfront (mostly sunk) costs, the application of ROA to this land use change question in
Australia has been scarce.
A previous limitation to the uptake of ROA has been model complexity and dimensionality.
Established analytical methods demand advanced mathematical skills of the practitioner and can
only be applied to limited range of problems, as solutions only exist for rather simple situations
considering limited sources of uncertainty. However, investments in alternative land uses, unlike
investment questions in financial markets (to which established analytical methods were designed to
be applied), will involve multiple sources of uncertainty such as commodity prices, spatially varying
risks like crop yields and emerging risks such as climate change. This poses challenges to the
application of ROA to these types of investment questions. Newer Monte Carlo simulation methods provide opportunity to investigate land use change problems where investment decisions are likely
to involve multiple sources of uncertainty, spatially variable risks such as crop yields and long
investment horizons.
This research aimed to adapt a Monte Carlo based ROA simulation model to investigate [1] the
effect of multiple uncertainties on the investment decision to switch land use from agriculture to
biomass agro‐forestry in a climatically diverse region of southern Australia, [2] Understand the effect
of spatially varying yield uncertainty across the study area, [3] explore the role potential climate
change may have on the returns required to encourage land use change to biomass agro‐forestry
and [4] provide mapped estimates of viable areas for biomass agroforestry at a range of price points
across the study area.
The results show that the consideration of price and yield uncertainty adds substantially to the
returns required to trigger land use change from wheat to biomass when compared to results from
the DCF analysis. Results indicate that uncertainty over returns to agroforestry, high upfront (largely
sunk) costs, and loss of flexibility associated with agroforestry provide the landholder with a valuable
option to delay reforestation and wait for uncertainties to resolve. Our results showed that for the
lower Murray study area, the value of this option can be substantial, ranging from 1.45 – 2.32 times
the present value of expenditures (DCF break‐even point).
Landholders often cite the lack of certainty of government policies, and the longevity of incentive
schemes as barriers to investment in reforestation. This research investigated the effect of incentive
payments and incentive payment uncertainty on returns required to trigger land use change. This
research found that a $25/t CO₂‐e carbon payment reduced the trigger price substantially but that
this impact varied spatially. While the effect of an uncertain carbon payment policy was to increase
the conversion trigger returns when compared to a fixed carbon payment, the effect of added
uncertainty was found to be small. The small effect of payment uncertainty reflects that the
additional payment acted more as an additional top up payment, not a main source of revenue from
conversion to biomass. This highlights a need to understand the role of incentive payments in the
overall revenue stream created from any land use change. For example, when a large proportion of
revenue from land use change is reliant on government policy, not market demand, policy risks are
higher.
Future climate change is anticipated to be the principal source of risk affecting long term economic
viability of rain‐fed agricultural systems. This research specifically modelled land use change from
agriculture to biomass production in a spatially explicit framework across a broad region accounting for impacts of climate change on yield variability. The effect of climate change on trigger returns
shows substantial spatial heterogeneity not only between high and low rainfall areas as one would
intuitively expect, but within similarly classified areas. In broad terms climate change reduced
returns required for land use change to biomass in low and medium rainfall zones (‐76%) and
increased them in the higher rainfall areas (25%). The results of this research show that even under
severe climate change comparatively small areas are economically viable for conversion to biomass
under $200/ DM t (930,986 ha), and it is not until prices exceed $200/DM t that significant areas
become profitable for conversion to biomass (up to 2,738,463 ha).
On an energy equivalence basis, to be competitive with an oil price of AU$41/barrel (current at the
time of writing) biomass would have to be priced at less than AU$130/DM t. Similarly, to be
competitive with coal at AU$68/t, the energy equivalent price of biomass would have to be less than
AU$52/DM t. Whether or not these prices are ultimately achievable is speculative, however, for
substantial biomass industry development to occur in the study area, the synchronisation of
products and services derived from mallee (oil, biomass, charcoal and carbon) and the development
of markets will be paramount.
School/Discipline
School of Biological Sciences
Dissertation Note
Thesis (Ph.D.) (Research by Publication) -- University of Adelaide, School of Biological Sciences, 2016
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