A critical review of global decarbonization scenarios: what do they tell us about feasibility?

Loftus, P. J.; Cohen, Armond; Long, Jane C.; Jenkins, Jesse D.

doi:10.1002/wcc.324

Cited by 151 publications

(123 citation statements)

References 35 publications

(60 reference statements)

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“…A similar analysis has been done by Loftus et al (2014), who normalized electricity capacity deployment rates in various global decarbonization scenarios using global GDP. In their study they found that the rates of change are broadly consistent with historical experience.…”

Section: Average Annual Capacity Additionmentioning

confidence: 91%

“…In their study they found that the rates of change are broadly consistent with historical experience. Only specific decarbonization scenarios with imposed restrictions on the implementation of clean and carbon sequestration technologies would lead to unprecedented rates of change for the remaining eligable low-carbon energy technologies (Loftus et al, 2014).…”

Section: Average Annual Capacity Additionmentioning

confidence: 99%

“…Historically observed rates of change can be important reference points for assessing the difficulty associated with future rates of change -providing possibly also insights in real world factors not covered in the models. In fact, several studies have already tried to compare model results and historical data using different indicators (Kramer and Haigh, 2009;Loftus et al, 2014;Riahi et al, 2015;Tavoni and van der Zwaan, 2009;van der Zwaan et al, 2013;Van Vuuren and Stehfest, 2013;Wilson et al, 2012). In these studies different methods and data sets have been used to confront existing scenarios with historical evidence, meaning that their results and conclusions cannot be easily compared.…”

Section: Introductionmentioning

confidence: 99%

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Comparing future patterns of energy system change in 2 °C scenarios with historically observed rates of change

Sluisveld

Harmsen

Bauer

et al. 2015

Global Environmental Change

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A B S T R A C TThis paper systematically compares modeled rates of change provided by global integrated assessment models aiming for the 2 C objective to historically observed rates of change. Such a comparison can provide insights into the difficulty of achieving such stringent climate stabilization scenarios. The analysis focuses specifically on the rates of change for technology expansion and diffusion, emissions and energy supply investments. The associated indicators vary in terms of system focus (technology-specific or energy system wide), temporal scale (timescale or lifetime), spatial scale (regional or global) and normalization (accounting for entire system growth or not). Although none of the indicators provide conclusive insights as to the achievability of scenarios, this study finds that indicators that look into absolute change remain within the range of historical growth frontiers for the next decade, but increase to unprecedented levels before mid-century. Indicators that take into account or normalize for overall system growth find future change to be broadly within historical ranges. This is particularly the case for monetary-based normalization metrics like GDP compared to energy-based normalization metrics like primary energy. By applying a diverse set of indicators alternative, complementary insights into how scenarios compare with historical observations are acquired but they do not provide further insights on the possibility of achieving rates of change that are beyond current day practice.

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Section: Average Annual Capacity Additionmentioning

confidence: 91%

Section: Average Annual Capacity Additionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Comparing future patterns of energy system change in 2 °C scenarios with historically observed rates of change

Sluisveld

Harmsen

Bauer

et al. 2015

Global Environmental Change

View full text Add to dashboard Cite

show abstract

“…Thus, even a complete decarbonization of the nation's electricity production would not be enough to meet a 2050 target of 80 per cent reduction. Most of the transport industry would have to be decarbonized as well (Loftus et al 2015), fuelled by a mix of synthetic products from a nuclear-derived surplus of heat and electricity and battery electric 'plug-in' vehicles (Brook 2012b), and current domestic gas use would have to be electrified (Heard 2013). Massive gains in efficiency might also be needed, depending on deployment rates.…”

Section: Discussionmentioning

confidence: 99%

Implications of Australia's Population Policy for Future Greenhouse Gas Emissions Targets

Bradshaw

Brook

2016

Asia & Pacific Policy Stud

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Australia's high per capita emissions rates makes it is a major emitter of anthropogenic greenhouse gases, but its low intrinsic growth rate means that future increases in population size will be dictated by net overseas immigration. We constructed matrix models and projected the population to 2100 under six different immigration scenarios. A constant 1 per cent proportional immigration scenario would result in 53 million people by 2100, producing 30.7 Gt CO 2 -e over that interval. Zero net immigration would achieve approximate population stability by mid-century and produce 24.1 Gt CO 2 -e. Achieving a 27 per cent reduction in annual emissions by 2030 would require a 1.5-to 2.0-fold reduction in per-capita emissions; an 80 per cent reduction by 2050 would require a 5.8-to 10.2-fold reduction. Australia's capacity to limit its future emissions will therefore depend primarily on a massive technological transformation of its energy sector, but business-as-usual immigration rates will make achieving meaningful mid-century targets more difficult.

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“…A recent review by Reference [44] categorize decarbonization scenario studies into four types of methodologies (the low-carbon technology options considered in some of these studies include carbon capture and storage and nuclear), namely (i) top-down, scenario based back-casting; (ii) top-down integrated assessment modeling; (iii) bottom-up energy system modeling; and (iv) bottom-up technical or techno-economic assessments. These methodologies typically apply cost as a cut-off criteria, otherwise the models stop with technology deployment once its desired objective (e.g., emission reduction) is reached.…”

Section: Strength and Limitations Of The Remap Methodologymentioning

confidence: 99%

The Implications for Renewable Energy Innovation of Doubling the Share of Renewables in the Global Energy Mix between 2010 and 2030

Saygin¹,

Kempener²,

Wagner³

et al. 2015

Energies

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Benefits of increasing the renewable energy (RE) share in the total energy mix include better energy security, carbon dioxide emission reductions and improved human health. This paper identifies the potential of RE technologies and role of innovation to double the global RE share from 18% to 36% between 2010 and 2030. As a first step, a Reference Case is developed based on national energy plans of 26 countries which increases the RE share to 21% by 2030. Next, the realizable potential of RE technologies is estimated beyond the Reference Case at country and sector levels. By aggregating country potentials, this paper reveals that the global RE share can double to 36% by 2030. Despite differences in starting points and resource potentials, there is a role for each country in achieving a doubling. For many countries their Reference Cases result in low RE shares and many countries are just beginning to explore ways to increase RE use. The paper identifies action areas where innovation can increase technology development and improve cost-effectiveness, thereby accelerating global RE deployment. More research is required to specify these action areas for individual countries and specific technologies, as well as to identify policy needs to address them.

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A critical review of global decarbonization scenarios: what do they tell us about feasibility?

Cited by 151 publications

References 35 publications

Comparing future patterns of energy system change in 2 °C scenarios with historically observed rates of change

Comparing future patterns of energy system change in 2 °C scenarios with historically observed rates of change

Implications of Australia's Population Policy for Future Greenhouse Gas Emissions Targets

The Implications for Renewable Energy Innovation of Doubling the Share of Renewables in the Global Energy Mix between 2010 and 2030

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