Category 4, the second-highest classification on the SaffirâÂÂSimpson scale, is used for tropical cyclones that have winds of . The division of the eastern and central Pacific basins occurs at 140ð W; the eastern Pacific covers area east of 140ð W, while the central Pacific extends between 140ð W to 180ð W. Both basins' division points are at 66ð N as a northern point and the equator as the southern point. , 145 hurricanes have attained Category 4 status in the northeastern Pacific basins. This list does not include storms that also attained Category 5 status on the scale.
Numerous climatological factors influence the formation of hurricanes in the Pacific basins. The North Pacific High and Aleutian Low, usually present between January and April, cause strong wind shear and unfavorable conditions for the development of hurricanes. During its presence, El Niño results in increased numbers of powerful hurricanes through weaker wind shear, while La Niña reduces the number of such hurricanes through the opposite. Global warming may also influence the formation of tropical cyclones in the Pacific basin. During a thirty-year period with two sub-periods, the first between 1975 and 1989 and the second between 1990 and 2004, an increase of thirteen Category 4 or 5 storms was observed from the first sub-period.
On the SaffirâÂÂSimpson Hurricane Scale, "Category 4" is the second-most powerful classification, with winds ranging between . When these hurricanes make landfall, impacts are usually severe but are not as destructive as Category 5 hurricanes that come ashore. The term "maximum sustained wind" refers to the average wind speed measured during the period of one minute at the height of above the ground. The windspeed is measured at that height to prevent disruption from obstructions. Wind gusts in tropical cyclones are usually approximately 30% stronger than the one-minute maximum sustained winds.
The northeastern Pacific hurricane basins are divided into two parts â eastern and central. The eastern Pacific basin extends from all areas of the Pacific north of the equator east of 140ð W, while the central Pacific basin includes areas north of the equator between 140ð W and 180ð W. Both basins extend to the Arctic Circle at 66ð N.
When tropical cyclones cross from the Atlantic into the Pacific, the name of the previous storm is retained if the system continues to exhibit tropical characteristics; however, when hurricanes degenerate into a remnant low-pressure area, the system is designated with the next name on the rotating eastern Pacific hurricane naming list.
Since 1900, 145 Category 4 hurricanes have been recorded in the eastern and central Pacific basins. Of these, fourteen have attained Category 4 status on more than one occasion, by weakening to a status on the SaffirâÂÂSimpson Hurricane Scale lower than Category 4 and later restrengthening into a Category 4. Such storms are demarcated by the dates they first attained and the final time they lost the intensity. Only four storms, Hurricane Fico in 1978, Hurricane Norbert in 1984, Hurricane Hector in 2018, and Hurricane Dora in 2023, reached Category 4 status three times or more.
Between 1970 and 1975, advisories for systems in the eastern Pacific basins were initiated by the Eastern Pacific Hurricane Center (EPHC) as part of the National Weather Service (NWS) office in San Francisco, California. At that time, the advisories released were written in cooperation with the United States Navy Fleet Weather Center in Alameda and the Air Force Hurricane Liaison Officer at the McClellan Air Force Base. Following the move of the hurricane center to Redwood City in 1976, track files were created and altered by Arthur Pike and were later re-modified following the release of a study in 1980. The National Hurricane Center (NHC) extended its authority to the EPHC in 1988, and subsequently began maintaining the tracks.
A total of 145 Category 4 hurricanes have been recorded in the eastern and central Pacific basins since 1900. It is theorized that global warming was responsible for an increase of 13 Category 4 and 5 storms that developed in the eastern Pacific, from 36 in the period of 1975âÂÂ1989 to 49 in the period of 1990âÂÂ2004. It was estimated that if sea-surface temperatures ascended by 2 to 2.5 degrees, the intensity of tropical cyclones would increase by 6âÂÂ10% internationally. During years with the existence of an El Niño, sea-surface temperatures increase in the eastern Pacific, resulting in an increase in activity as vertical wind shear decreases in the Pacific; the opposite happens in the Atlantic basin during El Niño, when wind shear increases creating an unfavourable environment for tropical cyclone formation in the Atlantic. Contrary to El Niño, La Niña increases wind shear over the eastern Pacific and reduces it over the Atlantic.
The presence of a semi-permanent high-pressure area known as the North Pacific High in the eastern Pacific is a dominant factor against formation of tropical cyclones in the winter, as the Pacific High results in wind shear that causes environmental conditions for tropical cyclone formation to be unconducive. Its effects in the central Pacific basin are usually related to keeping cyclones away from the Hawaiian Islands. Due to westward trade winds, hurricanes in the Pacific nearly never head eastward, although several storms have defied the odds and headed eastward. A second factor preventing tropical cyclones from forming during the winter is the occupation of a semi-permanent low-pressure area designated the Aleutian Low between January and April. Its presence over western Canada and the northwestern United States contributes to the area's occurrences of precipitation in that duration. In addition, its effects in the central Pacific near 160ð W causes tropical waves that form in the area to drift northward into the Gulf of Alaska and dissipate. Its retreat in late-April allows the warmth of the Pacific High to meander in, bringing its powerful clockwise wind circulation with it. The Intertropical Convergence Zone departs southward in mid-May permitting the formation of the earliest tropical waves, coinciding with the start of the eastern Pacific hurricane season on May 15.
Cooler waters near the Baja California peninsula are thought to prevent storms in the eastern Pacific from transitioning into an extratropical cyclone; as of 2009, only three storms listed in the database are known to have successfully completed an extratropical transition.
In the years between 1957 and 1974, 8 Category 4 hurricanes formed within the confines of the Pacific Ocean. A denotes that the storm temporarily weakened below Category 4 intensity during the specified period of time. As the Pacific hurricane database only goes back to 1949, the 1943 Mazatlán hurricane is not included, although it attained Category 4-equivalent winds at . It is unknown if the winds observed were sustained. Storms that formed in the eastern or central Pacific but strengthened to reach Category 4 status in the western Pacific basin (west of 180ð W) are not included.
In the years between 1974 and 1999, 70 Category 4 hurricanes formed within the confines of the Pacific Ocean. A denotes that the storm temporarily weakened below Category 4 intensity during the specified period of time.
In the years between 2000 and 2025, 68 Category 4 hurricanes formed within the confines of the Pacific Ocean. A denotes that the storm temporarily weakened below Category 4 intensity during the specified period of time.
Only two Category 4 hurricanes have been recorded in May, in addition to 15 in June, 29 in July, 40 in August, 38 in September, 22 in October, and two in November. No Category 4 storms have developed during the off-season.
Of the 145 Category 4 hurricanes that have formed in the eastern and central Pacific basins, 34 have made landfall. Of them, five made landfall at Category 4 and Category 3 intensity, thirteen at Categories 2 and 1, ten as tropical storms, and eight as tropical depressions. Several of these storms weakened slightly after attaining Category 4 status as they approached land; this is usually a result of dry air, shallower water due to shelving, cooler waters, or interaction with land.