Demand growth

AEMO’s 2021 Inputs, Assumptions and Scenarios Report (2021) informs its biennial Integrated System Plan (Australian Energy Market Operator, 2022). The reports use various scenarios (in the 2022 ISP – slow change, progressive change, step change and hydrogen superpower) to forecast potential growth and changes to the NEM’s energy mix. The (then) Queensland Department of Energy and Public Works has also included a “strong electrification” scenario in its demand outlook forecast (Figure 3).

Figure 3.

Demand scenarios for Queensland (after Australian Energy Market Operator, 2021).

AEMO (2021, p. 4) continually refines its scenarios acknowledging the pace of change in

According to AEMO (2021 Figure 2, p. 6), across the NEM, the hydrogen superpower scenario sees growth in energy consumption (demand) to 614 TWh over the slow change scenario (184 TWh) by 2040. Figure 3 shows the Queensland component of these scenarios.

In June 2023, Queensland had ∼17,000 MW or 17 GW (Queensland Government, 2023) of utility-scale generation out of the total NEM’s ∼55 GW (approximate) installed capacity (Australian Energy Regulator, 2024). All scenarios except for “slow change” see a minimum doubling of the consumption experienced across the period 2010 to 2020 by 2050.

AEMO (2022, p. 39) outlines the build task for variable renewable energy (VRE) under its most likely (step change) scenario.

Figure 4 shows the AEMO (Australian Energy Market Operator, 2024) generation contributions required to 2050, under the Step Change scenario. The Step Change scenario has been chosen as it reflects strong action on climate change leading to a step change reduction of greenhouse gas emissions. Given recent commitments at the state and federal level (see section 1) this scenario is currently a plausible outcome. By 2050, utility-scale solar needs to provide around 22% (∼110 terawatt hours of ∼500 TWh) of total generation and will require nearly 300 GW of installed capacity (Australian Energy Market Operator, 2024, Figure 14, p. 45).

Figure 4.

Forecast National Electricity Market generation to 2050; step change scenario (Australian Energy Market Operator, 2024 Figure 9, p. 30).

The estimate for utility-scale solar will require substantial land areas. Estimates on generation from utility-scale solar vary. Ergon Energy, Queensland’s regional retail and network service provider advises 1 ha per 1-1.5 MW; other estimates range to 2-3 ha per MW (Squadron Energy, 2022). AEMO’s projections will require large tracts of land regardless – ∼65,000 to 200,000 ha for the NEM.

The potential for renewable energy in Australia to be converted into a non-polluting export fuel has been widely forecast (e.g. COAG Energy Council, 2019). Scenarios including strong growth in hydrogen production push demand growth exponentially (Australian Energy Market Operator, 2021). Projections for growth in hydrogen production reflect the wider growth in renewable electricity demand. AEMO (2022, p. 39) describes the “Hydrogen Superpower” build task as “monumental.” Any renewable demand growth arising from the conversion of the Queensland aluminium industry to renewable energy, would create additional demand.

In September 2022, the Queensland Government released its Energy and Jobs Plan (Queensland Government, 2022). The implications for the stationary energy mix and mine rehabilitation are discussed in more detail below. Figure 5 shows the change in energy mix and the projected generation growth to 2040.

Figure 5.

Forecast annual mix of NEM-connected large-scale generation in Queensland in the Plan Scenario (after Queensland Department of Energy and Public Works, 2022, p. 5). Y-axis is TWh.

It becomes apparent that more renewables are required to simply meet the existing commitments in Queensland (50% of electricity generation from renewables by 2030, 70% by 2032, 80% by 2035) and the 2022 emissions reduction targets introduced by the federal government. Plausible scenarios should Australia seize the opportunities afforded by the global decarbonisation agenda, such as green metals and hydrogen, see net growth in total energy demand, to be delivered by renewable energy sources.

Rehabilitated mine lands occupy tens of thousands of hectares. While the Queensland REZ locations continue to evolve, there are already areas that coincide with mining areas. The disturbed (and subsequently rehabilitated) areas have been retired from agricultural production for many years, in many cases decades. They lend themselves as highly suitable locations to meet even the most modest of energy demand growth scenarios.

The Decarbonisation agenda

A large proportion of global resources companies, including those active in Queensland, have signed up to carbon emissions reductions, including net zero emissions by 2050 such as BHP Ltd (BHP, 2021), Glencore PLC (2021) and Peabody Energy Inc. (Peabody Energy Inc., 2023). The Queensland Resources Industry Development Plan (Department of Resources, 2022, p. 21) has included a proposal to develop a decarbonisation policy with industry to be prepared for mining operations in the State, aiming to achieve

The Australian Government’s Resources 2030 Taskforce (2018, p. 40) noted

Net zero by 2050 is a bold, ambitious but necessary aspiration for all organisations, especially those energy-intensive operations, or those producing emissions-intensive products, or both. To achieve net zero 2050, companies are looking for the immediate next steps they can take on that path. The mining industry’s direct greenhouse contribution is attributed 4-7% of total global emissions (Delevinge et al., Reference Delevinge, Glazener, Gregoir and Henderson2020). Of these, Scope 1 (emissions generated by the activity itself) and Scope 2 (emissions generated by the goods and services provided to the operation, including energy) emissions account for 1%.

The Scope 3 emissions from the use of mining products including the combustion of coal are attributed 28% of global emissions (Delevinge et al., Reference Delevinge, Glazener, Gregoir and Henderson2020). While addressing Scope 3 emissions may remain elusive in the short-term, real action can be taken in the short to medium term to address Scope 1 and Scope 2 emissions from Queensland mines. They present an opportunity for mining companies to begin their decarbonisation journey with real, practical emissions reductions.

Reducing the carbon intensity of operations is of primary importance to those companies committing to net zero by 2050 and staged interim reductions (such as BHP’s 30% reduction in operational levels by 2030). BHP has identified the introduction of renewable energy sources into its first 40% of reductions. From 1 January 2021, BHP entered into a power purchase agreement with the state’s newest generator, CleanCo Queensland, to provide renewable energy from the Western Downs Clean Power Hub and Karara windfarm. BHP states the deal will reduce their operational emissions in Queensland by 50% by 2025. BHP (n.d.) has also committed to behind-the-meter renewables where grid connectivity is limited.

A survey of mine managers at 162 mine sites globally was conducted in early 2022 (GlobalData, n.d.). On-site renewable energy options were preferred by 38% of respondents and more than 20% citing purchased renewable energy. And it is that global preference for on-site renewable power that presents a win-win opportunity for miners to reduce their emissions-intensity while developing a sustainable post-mining land use.

The $62B Queensland Government Energy and Jobs Plan (2022) seeks to rapidly decarbonise the stationary energy economy and take Queensland beyond its stated 2030 target of 50% renewables in the stationary energy sector. Figure 5 shows the proposed growth in demand and the change in generation sources proposed in the Plan (Queensland Department of Energy and Public Works, 2022). The Plan transitions Queensland from coal-fired generation by 2040.

An initial focus on reducing the carbon intensity of mining operations, using behind-the-meter renewable energy generation on site, would be a proactive, if modest step towards mining companies’ decarbonisation strategies. Growth in renewables on-site can be matched to the rehabilitation task, occur over the operating period of the mine and provide renewable energy as a complement to traditional energy sources.

Supporting regional mining economies in transition

The Cooperative Research Centre for Transformations in Mining Economies (CRC TiME) is a collaboration of over 70 institutions committed to responsible mine rehabilitation, closure and sustainable post-mining economies. The formation of the CRC TiME reflects the importance of planned transformations, particularly for fossil fuel-based commodities. The challenges outlined previously suggest that, over time, these commodities face diminishing market demand, especially for energy production. CRC TiME has commenced a project Identifying future economic development pathways for mining regions and increasing transition capacity (Poruschi et al., Reference Poruschi, Fleming-Munoz and Haslam-Mackenzien.d.). Bainton and Holcombe (Reference Bainton and Holcombe2018) identified potential economic linkages to mine closure. Ensuring a sustainable post-mining land use and opportunities for resources communities is an important aspect of mine closure planning.

Integrating renewables into the mine rehabilitation landscape will bring new, “green” energy opportunities. In turn, industries attracted to REZs will contribute to the long-term sustainability of regional economies hosting renewables.

In the Queensland context, the thermal and metallurgical coal open cut mines located close to announced REZs are prime candidates. Metalliferous mines will also “transform” regional economies. Demand for new economy minerals will lead to lower grades becoming commercial, more waste being removed to access these resources, tailings and other “wastes” being remined, and new mines opening, all with demands for energy.

Many mines in southern and central Queensland are located on freehold land, often owned by the companies themselves. These types of tenure arrangements make introduction of renewable energy during the operational life of the mines smoother as the subsequent landholder post-mining is the company itself (or often a subsidiary pastoral entity, ultimately owned by the mine operator).

The resources industry is and will continue to be a major contributor to the Queensland economy. Planned, orderly integration of new technological and economic development opportunities can provide transformation over time that supports regional economic development and sustainability.

Progressive rehabilitation and sustainable post-mining land use

Many jurisdictions around the world require progressive rehabilitation of mined lands, integration of rehabilitation into operations and mine planning, consideration of social aspects of rehabilitation and requirements that land be rehabilitated such that the land can sustain a post-mining land use (e.g. Kabir et al., Reference Kabir, Rabbi and Chowdhury2015; Kung et al., Reference Kung, Everingham and Vivoda2020; Manero et al., Reference Manero, Standish and Young2021). Progressive rehabilitation is particularly applicable to strip mining operations, such as open cut coal, shallow bauxite, phosphate and other bulk commodities, and mineral sands operations. As the working face of the mine progresses across the landscape, disturbed lands trailing that open face can be progressively rehabilitated during mine life.

The surface area of disturbed mined land in Queensland presents a considerable opportunity for the development of renewables. The mined land disturbance footprint in Queensland is dominated by the coal sector (80%), and therefore data from this sector was selected to evaluate this opportunity. To do so, disturbance and rehabilitation data for 88 mines (around 50 operating mines and a variety of proposed mines, mines in care and maintenance and related infrastructure authorities) with environmental authorities (i.e. environmental licences) for extracting metallurgical and thermal coal in Queensland is presented here (Queensland Mine Rehabilitation Commissioner, 2023). Figure 6 shows the cumulative disturbance and rehabilitation data provided by companies in their annual returns to the end of calendar year 2022. Both open cut and underground operations are included, as some mines have a combination of methods operating simultaneously.

Figure 6.

Progressive rehabilitation, including disturbance (Dist.) remaining after rehabilitation (Rehab.) for metallurgical and thermal coal mines in Queensland (Queensland Mine Rehabilitation Commissioner, 2023, p. 19).

Figure 6 shows that net disturbance (Dist.) remaining after rehabilitation (Rehab.) between 2019Footnote ¹ and 2022 has increased by 8,122 ha to 170,747 ha. “Rehabilitation” is measured as the sum of certified rehabilitation and rehabilitation identified by companies as “completed” but not certified in the annual returns to the regulator. Total rehabilitation (historically to end of 2022) is 52,175 ha and total disturbance for the same period is 222,922 ha.

With over 50,000 ha already rehabilitated to some extent and more to come, the opportunity for these lands to play an important role in hosting renewable energy generation becomes apparent. In strip mines, as land is rehabilitated to a safe, geotechnically stable landform, renewable energy infrastructure can be incrementally introduced. In Queensland, the most prevalent nominated post-mining land use is “grazing.” The rehabilitation to a stable, grassed landform lends itself to installation of utility-scale solar. With forward planning, the landform shaping programme can also maximise the solar budget by aligning aspect and slope to optimise future solar energy generation.

Many Queensland coal mines use electric draglines for removal of overburden. As such, significant investment in electricity transmission infrastructure is in place, serviced by grid-connected supply. With modification, intermittent renewable supply “behind-the-meter” can be introduced incrementally. At the conclusion of mining operations, those “green” electrons can then be directed into the wider grid.

A more common practice at present is for mining companies to simply enter into a power purchase agreement with a generator and purchase renewable energy. This reduces the burden of coordinating a new activity onto operational sites and allows miners to stick to their core business. However, the generator in turn must source and locate renewable projects, often into agricultural lands, or lands requiring the clearing of remnant vegetation. If barriers to on-site renewables as part of progressive rehabilitation can be reduced, renewables as part of progressive rehabilitation can greatly assist in decarbonisation of operations and provide an ongoing economic life after mining ceases.

Reducing land use conflict

As at 31 December 2022, the Queensland coal industry reported a total area of disturbed land of over 170,000 hectares (see Figure 6), and the entire mining industry (exclusive of petroleum tenements) around 213,000 ha (Queensland Mine Rehabilitation Commissioner, 2023). The total area of mining leases is larger again, as not all land on any lease is necessarily disturbed by mining. Although relatively small in footprint compared to agriculture, the use of mine sites for renewables during progressive rehabilitation and at end of mine life, potentially avoids a raft of land use conflicts that have already arisen with the current growth in the renewable energy sector and agricultural interests globally (e.g Akita et al., Reference Akita, Ohe, Araki, Yokohari, Terada and Bolthouse2020; Ketzer, Reference Ketzer2020; McBain et al., Reference McBain, Lenzen, Albrecht and Wackernagel2021). Using rehabilitated mine lands also avoids further clearing of remnant vegetation, another source of community conflict historically (England, Reference England2018). This is especially attractive where mining companies own the underlying freehold title.

Queensland’s resources industry presents strategic opportunities to host renewable energy infrastructure. At least two of the four mine mouth power stations are well suited to renewables being a large part of the post-mining land use, where progressive rehabilitation of the adjacent thermal coal mines could leverage the substantial transmission infrastructure at the power stations and skills base of the local workforce. Energy generators are already committed to installing network-scale batteries at a number of these sites to provide not only energy to the grid but also system stability services, reinforcing their utility as enduring “energy precincts” long after coal ceases to be the primary fuel source.

In a study commissioned by the Queensland Resources Council (Worden et al., Reference Worden, Côte, Svobodova, Arratia-Solar, Everingham, Asmussen, Edraki and Erskine2021), both the Bowen and Surat/Moreton basins were identified as suitable for solar projects. The study identified 9,000 ha of mine lands within 1 kilometre of high-voltage transmission lines and 50,000 ha within 2 kms (pp. 66, 71).

If the projected demand for renewable energy forecast from industrial load growth and the onset of the hydrogen industry are to come to fruition, available land and its optimal use will become limiting factors. An integrated approach from all levels of government that facilitates the use of land impacted by mining can be a significant contributor to the overall growth of the sector while sustaining its licence to operate in regional communities.

Queensland legislation, similar to many jurisdictions in OECD and other countries, requires mined land to be rehabilitated to a stable level, suitable to sustain a post-mining land use. In Queensland, “stable” means safe, structurally stable and non-polluting. These are the necessary pre-conditions to then consider the land’s post-mining use. Grazing land outcomes that meet all regulatory requirements for relinquishment, are then suitable for hosting renewables, either as standalone facilities or under co-production models with small livestock. Integrated mine planning can maximise aspect and rehabilitate lands to be amenable to renewables. Of course, there are mined areas that through their remote location and topography, will not be suitable.