Timo Zeyer scite author profile

Wind and solar PV generation data for the entire contiguous US are calculated, on the basis of 32 years of weather data with temporal resolution of one hour and spatial resolution of 40×40 km 2 , assuming site-suitability-based as well as stochastic wind and solar PV capacity distributions throughout the country. These data are used to investigate a fully renewable electricity system, resting primarily upon wind and solar PV power. We find that the seasonal optimal mix of wind and solar PV comes at around 80% solar PV share, owing to the US summer load peak. By picking this mix, long-term storage requirements can be more than halved compared to a wind only mix. The daily optimal mix lies at about 80% wind share due to the nightly gap in solar PV production. Picking this mix instead of solar only reduces backup energy needs by about 50%. Furthermore, we calculate shifts in FERC (Federal Energy Regulatory Commission)-level LCOE (Levelized Costs Of Electricity) for wind and solar PV due to their differing resource quality and fluctuation patterns. LCOE vary by up to 35% due to regional conditions, and LCOE-optimal mixes turn out to largely follow resource quality. A transmission network enhancement among FERC regions is constructed to transfer high penetrations of solar and wind across FERC boundaries, based on a novel least-cost optimization approach.

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Principal Mismatch Patterns Across a Simplified Highly Renewable European Electricity Network

Raunbak

Zeyer

Zhu

et al. 2017

Energies

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Due to its spatio-temporal variability, the mismatch between the weather and demand patterns challenges the design of highly renewable energy systems. A principal component analysis is applied to a simplified networked European electricity system with a high share of wind and solar power generation. It reveals a small number of important mismatch patterns, which explain most of the system's required backup and transmission infrastructure. Whereas the first principal component is already able to reproduce most of the temporal mismatch variability for a solar dominated system, a few more principal components are needed for a wind dominated system. Due to its monopole structure the first principal component causes most of the system's backup infrastructure. The next few principal components have a dipole structure and dominate the transmission infrastructure of the renewable electricity network.

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Infrastructure Estimates for a Highly Renewable Global Electricity Grid

Dahl

Rodriguez

Søndergaard

et al. 2016

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Principal Mismatch Patterns across a Simplified Highly Renewable European Electricity Network

Raunbak¹,

Zeyer²,

Zhu³

et al. 2017

Preprint

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Timo Zeyer

Features of a fully renewable US electricity system: Optimized mixes of wind and solar PV and transmission grid extensions

Principal Mismatch Patterns Across a Simplified Highly Renewable European Electricity Network

Infrastructure Estimates for a Highly Renewable Global Electricity Grid

Principal Mismatch Patterns across a Simplified Highly Renewable European Electricity Network

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