The duck curve is a graphical representation of power production throughout a day, illustrating the imbalance between peak electricity demand and solar power generation. The curve's shape resembles the silhouette of a duck, which inspired the name. The term was first introduced in 2012 by the California Independent System Operator (CAISO) to describe the challenges faced by utility-scale electricity grids, particularly as solar energy contributes more significantly to the energy mix. This imbalance highlights the difficulty in aligning peak solar production with periods of highest electricity demand, leading to operational challenges for grid management.
In some energy markets, daily peak demand occurs after sunset, when solar power is no longer available. In locations where a substantial amount of solar electric capacity has been installed, the amount of power that must be generated from sources other than solar or wind displays a rapid increase around sunset and peaks in the mid-evening hours, producing a graph that resembles the silhouette of a duck.[2][3] In Hawaii, significant adoption of solar generation has led to the more pronounced curve known as the Nessie curve.[4][5]
Without any form of energy storage, after times of high solar generation, power companies must rapidly increase other forms of power generation around the time of sunset to compensate for the loss of solar generation, a major concern for grid operators where there is rapid growth of photovoltaics.[6] Storage such as dammed hydropower can fix these issues if it can be implemented.[7] Short term use batteries, at a large enough scale of use, can help to flatten the duck curve and prevent generator use fluctuation and can help to maintain voltage profile.[8]
Methods for coping with the rapid increase in demand at sunset reflected in the duck curve, which becomes more serious as the penetration of solar generation grows, include:[8]
A major challenge is deploying mitigating capacity at a rate that keeps up with the growth of solar energy production. The effects of the duck curve have happened faster than anticipated.[12]
The California Independent System Operator (CAISO) has been monitoring and analyzing the Duck Curve and its future expectations for about a half a century now and their biggest finding is the growing gap between morning and evening hours prices relative to midday hours prices.[1] According to their 2016 study, the U.S. Energy Information Administration, found that the wholesale energy market prices over the past six months during the 5 pm to 8 pm period (the "neck" of the duck) have increased to $60 per megawatt-hour, compared to about $35 per megawatt-hour in the same time frame in 2016.[2] However, on the other side they have measured a drastic decrease in the midday prices, nearing $15 per megawatt-hour.[2][needs update] These high peaks and deep valleys are only showing continued trends of going further apart making this Duck Curve even more prevalent as renewable energy production continues to grow.[3][13][14]
A crucial part of this curve comes from the net load ("the difference between expected load and anticipated electricity production from the range of renewable energy sources").[2] In certain times of the year (namely spring and summer), the curves create a "belly" appearance in the midday that then drastically increases portraying an "arch" similar to the neck of a duck, consequently the name "The Duck Chart.[15]" This "neck" represents a ramp speed of between 10 and 17 GW in 3 hours (afternoon) in 2020 which has to be supplied by flexible generation.[16] During the midday, large amounts of solar energy are created, which partially contributes to lower demand for additional electricity.[17] Curtailment impacts the curve.[16] Increasing battery storage can mitigate the issues of solar abundance during the day. When excess solar energy is stored during the day and used in the evening, the price disparity between inexpensive midday and expensive evening energy can be reduced. Enough total solar technology exists to power the world, but there is a current lack of infrastructure to store solar energy for later use.[6] An oversupply of energy during low demand coupled with a lack of supply during high demand explains the large disparity between midday and evening energy prices. As of 2022[update], up to 6 GWh is shifted per day from low price to high price periods.[18]
even out the "solar duck curve". . install batteries and west-facing panels, which helps stretch solar generation into the afternoon-evening peak.
By charging up in the middle of the day, LDV fleets on EVgo's network also help to address the duck curve — where midday net load drops, driven by lots of solar flooding onto the grid
The growing amount of photovoltaic solar generation that is interconnected to the ISO grid continues to change the ISO's net load profile and creates more challenges and uncertainty for ISO operations. The result is a constantly increasing ramping requirement, significantly more than what has been required from the generat ion fleet in the past, both upward and downward. Furthermore, solar generation does not provide significant power at the hours ending 19:00 to 21:00, which leads to reliance on gas and other non-solar generation after sunset. The continuing decline in dispatchable generation in the ISO as dispatchable units retire is beginning to challenge the ISO system's ability to meet net peak demand after sunset and flexible capacity requirements.