In a new weekly update for pv magazine, Solcast, a DNV company, reports that in January most of East Asia experienced normal to above-average solar irradiance, with southeastern China seeing surges due to reduced clouds and low aerosol levels under lingering La Niña effects. In contrast, the Philippines faced below-average irradiance from early Tropical Storm Nokaen, while other regional cities like Seoul, Tokyo, and Taipei recorded modest gains.

Most of East Asia recorded normal to above‑normal solar irradiance in January, as weak La Niña conditions continued to influence regional weather patterns. The largest gains were observed across southeastern China, where suppressed cloud formation and reduced aerosol-effects delivered a strong start to the year for solar operators, while unusual early tropical storm activity brought significant rainfall and irradiance losses to parts of the Philippines. With two days left in January at time of publishing, this data uses live data from 1-29 January, and forecasts for 30-31 Jan from the Solcast API.

Irradiance in southeastern China surged well above historical averages in January, with Hong Kong exceeding 25% above average. A dominant Siberian high pressure system, with temperatures in parts of Siberia more than 10 C below normal, extended into western China. The resulting northerly flow delivered drier air into southeastern China, reducing both precipitation and cloud formation. This irradiance pattern aligns with typical La Niña effects, even though the La Niña signal was weak and fading toward neutral by late January. Additionally, lower than normal aerosol levels contributed to above average irradiance in coastal parts of China.

In a continuation of the irradiance and aerosol pattern seen in 2025, many parts of China, in particular low-lying industrial areas saw significant drops in aerosol load and a corresponding increase in available irradiance. Both Hong Kong and Shanghai regions saw significantly lower winter average aerosol loads, than the historical average for winter months from 2007-2026. Whilst this supported the exceptionally high irradiance in Hong Kong through January, Shanghai recorded slightly above-average irradiance, despite experiencing a rare snowfall late in the month. By contrast, Beijing has historically lower aerosol loads, however still saw slightly below-average irradiance due to prevailing cloud levels.

Elsewhere in East Asia, irradiance levels were generally normal to above normal for this month. Seoul and Tokyo recorded irradiance 5–10% above January averages and Taipei saw gains exceeding 10%. Across the maritime continent, irradiance and precipitation anomalies were near normal.

The most significant negative irradiance anomaly in the region was associated with Tropical Storm Nokaen (Ada), which marked an unusually early start to the 2026 Pacific typhoon season. Making landfall in January—the first such occurrence since 2019— Nokaen delivered intense rainfall and heavy cloud cover to the central and northern Philippines. Daily rainfall totals reached up to 200 mm, triggering mudslides and widespread disruption. Irradiance across the northern Philippines dropped by as much as 10% below average, while the southern parts of the archipelago, spared from the worst of the storm, saw irradiance climb to 10% above average.

Solcast produces these figures by tracking clouds and aerosols at 1-2km resolution globally, using satellite data and proprietary AI/ML algorithms. This data is used to drive irradiance models, enabling Solcast to calculate irradiance at high resolution, with typical bias of less than 2%, and also cloud-tracking forecasts. This data is used by more than 350 companies managing over 300 GW of solar assets globally.

In a new weekly update for pv magazine, Solcast, a DNV company, reveales that last year extreme Canadian wildfires drove aerosol levels around 30% above normal, sharply reducing solar irradiance across Canada and even impacting Europe, while the Congo Basin also saw worsening aerosol conditions. In contrast, China and South America experienced unusually low aerosol levels, supporting stronger solar irradiance due to cleaner air, reduced fires, and favorable climate and policy conditions.

Aerosol anomalies in 2025 reveal the outsized impact of Canadian wildfires on solar conditions, with smoke and particulates from one of the worst fire seasons in the country’s history driving major reductions in solar irradiance across Canada and beyond. While Canada saw a marked increase in aerosol loading, China and South America experienced anomalously low levels, supporting stronger irradiance conditions. Meanwhile, the Congo Basin registered worsening aerosol conditions, highlighting growing concerns for central Africa's solar outlook, according to analysis using the Solcast API. Aerosols impact solar irradiance by scattering and absorbing solar radiation as it passes through the atmosphere, when calculated this effect is called ‘aerosol extinction’.

Across Canada, 2025 aerosol extinction values were around 30% above climatological norms, indicating significantly higher levels of sunlight absorption and scattering by particulate matter. This spike is directly linked to the extreme wildfire season, with the total burned area in 2025 reaching twice the 10-year average. The timing of the peak fire activity, which aligned with the high-irradiance months of May and June, compounded the impact on solar conditions.

Smoke plumes from Canada were transported across the Atlantic by prevailing westerly winds, impacting solar production as far as Western Europe, where they overlapped with Spain's worst wildfire season in over a decade, further amplifying the regional aerosol burden.

Despite having a higher aerosol load than other solar generation regions, China experienced one of its cleanest atmospheric years in recent history. Aerosol extinction anomalies were approximately 20% below the recent climatology, driven by a combination of favourable meteorological patterns and continued reductions in industrial emissions. These conditions supported a strong irradiance performance throughout the past year when irradiance was already tracking 30% above average.

South America also recorded a notable improvement in aerosol conditions following a turbulent 2024. Anomalies in 2025 were generally 20% to 30% below average, allowing for clearer skies across the region. Solar production in Brazil, benefited from reduced smoke associated with a 45% reduction in burned areas within the Amazon Basin, as detected by the DETER satellite system. This significant decrease is part of a broader post-Bolsonaro shift in environmental management, further supported by La Niña-associated wetter conditions that helped suppress fire activity.

Meanwhile, the Congo Basin experienced worsening aerosol conditions, with extinction anomalies 20% to 30% above climatology. Unlike the declining trends in Saharan dust seen across northern Africa, this spike in aerosols is attributed to increasing fire activity within wet forest regions. The number of active fires in these forests has doubled over the past two decades, largely due to a combination of hotter, drier weather and anthropogenic factors such as conflict or agricultural-driven deforestation

Solcast produces these figures by tracking clouds and aerosols at 1-2km resolution globally, using satellite data and proprietary AI/ML algorithms. This data is used to drive irradiance models, enabling Solcast to calculate irradiance at high resolution, with typical bias of less than 2%, and also cloud-tracking forecasts. This data is used by more than 350 companies managing over 300 GW of solar assets globally.