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Sukhoi SU-35 Flanker

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WIKI
The Sukhoi Su-35 (Russian: ????? ??-35; NATO reporting name: Flanker-E) is the designation for two improved derivatives of the Su-27 air-defence fighter. They are single-seat, twin-engine, supermaneuverable aircraft, designed by the Sukhoi Design Bureau and built by the Komsomolsk-on-Amur Aircraft Plant.

The type was originally developed by the Soviet Union from the Su-27 and was known as the Su-27M. It incorporated canards and a multi-function radar giving it multi-role capabilities. The first prototype made its maiden flight in June 1988. Following the dissolution of the Soviet Union Sukhoi re-designated it as the Su-35 to attract export orders. Fourteen aircraft were produced and used for tests and demonstrations; one example had thrust-vectoring engines and was in turn redesignated the Su-37. A sole Su-35UB two-seat trainer was also built in the late 1990s that resembled the Su-30MK family.

In 2003, Sukhoi embarked on a second modernization of the Su-27 to serve as an interim aircraft awaiting the development of the Sukhoi PAK FA (Su-57) program. Also known as the Su-35, this version has a redesigned cockpit and weapons-control system and features thrust-vectoring engines in place of the canards. The type made its first flight in February 2008. Although it was designed for export, the Russian Air Force became the launch customer in 2009, with the production version designated Su-35S. China's People's Liberation Army Air Force have also placed orders.

Design and development
Upgraded Su-27
The first aircraft design to receive the Su-35 designation had its origins in the early 1980s, at a time when the Su-27 was being introduced into service with the Soviet Armed Forces. The definitive production version of the Su-27, which had the factory code of T-10S, started mass ("serial") production with the Komsomolsk-on-Amur Aircraft Production Association (KnAAPO) in 1983. The following year, this Su-27 version reached initial operational readiness with the Soviet Air Defence Forces.[6] Having begun work on an upgraded Su-27 variant in 1982,[7] the Sukhoi Design Bureau was instructed in December 1983 by the Soviet Council of Ministers to use the Su-27 as the basis for the development of the Su-27M (T-10M).[8] Nikolay Nikitin would lead the design effort throughout much of the project's existence, under the oversight of General Director Mikhail Simonov, who had been the chief designer of the Su-27[9] along with Mikhail Pogosyan.[citation needed]

Planform view of the Su-27M
While sharing broadly the blended wing-body design of the Su-27, the Su-27M is visibly distinguished from the basic version by the addition of canards, which are small lifting surfaces, ahead of the wings. First tested in 1985 using an experimental aircraft,[6] the canards, in complement with the reshaped wing leading-edge extension, redirected the airflow in such a way so as to eliminate buffeting at high angles of attack and allowed the airframe to sustain 10-g manoeuvres (as opposed to 9 g on the Su-27) without the need for additional structural reinforcement.[10] More importantly, when working with the relaxed-stability design and the accompanying fly-by-wire flight-control system, the aerodynamic layout improved the aircraft's manoeuvrability and enabled it to briefly fly with its nose past the vertical while maintaining forward momentum. Because of this, theoretically, during combat the pilot could pitch the Su-27M up 120 degrees in under two seconds and fire missiles at the target.[11] Other notable visible changes compared to the T-10S design included taller vertical tails, provisions for in-flight refuelling and the use of two-wheel nose undercarriage to support the heavier airframe.[12][13]

Besides the increase in manoeuvrability, another feature that distinguished the Su-27M from the original design was the new weapons-control system. The centrepiece of this system was the multi-function N011 Bars (literally "Leopard") phased-array radar with pulse-Doppler tracking that allowed it to detect targets below the horizon. First installed on the third prototype, the radar transformed the Su-27M from simply being an air-defence fighter into a multi-role aircraft capable of attacking ground targets.[6][14] Compared to the N001 Myech ("Sword") radar of the Su-27, which could track 10 targets and only direct two missiles towards one target at a time, the new radar could track fifteen targets and direct missiles towards six of them simultaneously.[6] The extra weight of the N011 radar at the front of the aircraft necessitated the addition of the canards; engineers would only later discover the aerodynamic advantages of these devices.[1][15] In addition, an N012 self-defence radar was housed in the rearward-projecting tail boom, making the aircraft the first in the world to have such a radar.[14] Other changes to the aircraft included the use of uprated turbofan engines, as well as the increased use of lightweight composites and aluminium-lithium alloys in the aircraft's structure.[12][16]

Testing and demonstration
In 1987, Sukhoi started converting the first prototype (designated T10M-1) from a T-10S airframe at its experimental plant in Moscow. Although it had canards, the first prototype, like several subsequent aircraft, lacked the many physical alterations of the new design.[17] It made its first flight after conversion on 28 June 1988, piloted by Oleg Tsoi, followed by the second prototype in January 1989.[18] Following the conversions of the two Su-27M prototypes, the actual production of the aircraft was transferred to the country's Far East where it was carried out by KnAAPO. The third aircraft (T10M-3), which was the first new-built Su-27M and first to be constructed by KnAAPO, made its first flight in April 1992.[18] By then, the Soviet Union had disintegrated, and the ensuing economic crisis in Russia throughout the 1990s meant that the original plan to mass-produce the aircraft between 1996 and 2005 was abandoned,[6] with the aircraft to serve as experimental test-beds to validate the canards, the flight-control system and thrust-vectoring technology.[12] In total, two prototypes, nine flying pre-production and three production aircraft were constructed by 1995;[1][19] the production aircraft were delivered in 1996 to the Russian Air Force for weapons testing.[20]

The ninth Su-27M in-flight
By the time of the disintegration of the Soviet Union, Sukhoi had been demonstrating the Su-27M to senior defence and government officials. With its debut to a Western audience at the 1992 Farnborough Airshow, the company redesignated the aircraft as Su-35.[21] The aircraft subsequently made flying demonstrations overseas in an effort to attract export orders, starting in November 1993 with Dubai, where Viktor Pugachev flew it in a mock aerial engagement with an Su-30MK in front of spectators.[22][23] The aircraft thereafter flew in Berlin and Paris, and would be a regular feature at Moscow's MAKS Air Show.[23] The Russian government cleared the aircraft for export during Sukhoi's unsuccessful sales campaign in South Korea during the late 1990s and early 2000s;[24] the company also marketed the aircraft to Brazil, China and the United Arab Emirates.[25]

As the flight-test programme of the Su-27M proceeded, engineers discovered that the pilot failed to maintain active control of the aircraft during certain manoeuvres, such as the Pugachev's Cobra. The eleventh Su-27M (T10M-11) was therefore equipped with thrust-vectoring engine nozzles in 1995, and the resultant Su-37 technology demonstrator made its first flight on 2 April 1996.[26][27] It also tested the enhanced N011M radar, as did the twelfth developmental Su-27M.[25] The Su-37's ability to maintain a high angle of attack while flying at close to zero airspeed attracted considerable press attention.[28] It later received different engines and updated fly-by-wire controls and cockpit systems for evaluation.[25]

Apart from the single-seat design, a two-seat aircraft was also constructed. Working in cooperation with Sukhoi, KnAAPO's own engineers designed the Su-35UB so as to combine thrust-vectoring engines with features of the Su-27M. Modified from an Su-30MKK airframe, the aircraft made its first flight on 7 August 2000, and afterwards served as an avionics test-bed.[29] While the original Su-27M never entered mass production due to a lack of funding,[30] Sukhoi refined the Su-27M's use of canards and the Su-37's thrust-vectoring technology and later applied them to the Su-30MKI two-seat fighter for the Indian Air Force.[31] The tenth Su-27M (T10M-10) also served as a test-bed for the Saturn AL-41FS engine that is intended for the Sukhoi Su-57 (previously known under the acronym "PAK FA") jet fighter.[32]

Modernization

Thrust vectoring nozzle on a Sukhoi Su-35S
With the need to update Russia's aging fleet of Su-27 aircraft, Sukhoi and KnAAPO in 2002 started integrating glass cockpits and improved weapons-control systems (to accommodate a greater variety of weapons) to existing air force aircraft. The Su-27SM, as the modified aircraft is called, made its first flight in December 2002.[33] The initial success of this project led Sukhoi in December 2003 to proceed with a follow-up modernization programme. Known internally as T-10BM,[1] the programme was aimed at a more thorough redesign of the airframe to narrow the qualitative gap between Russian aircraft and foreign fourth-generation aircraft. The resultant design, also designated Su-35, would serve as an interim solution pending the introduction of the Sukhoi Su-57 fifth-generation fighter,[34][35] many features of which the aircraft would incorporate.[1] Additionally, the aircraft was to be a single-seat alternative to the two-seat design of the Su-30MK on the export market.[36]

In many respects, the T-10BM design outwardly resembles the Su-27 more than the Su-27M. During tests of the thrust-vectoring engines and the Su-27M's aerodynamic layout, Sukhoi had concluded that the loss of manoeuvrability due to the removal of the canards – the design of which imposed a weight penalty on the airframe – could be compensated for by the addition of thrust-vectoring nozzles.[N 1] Industry progress in the fields of avionics and radars have also reduced the weight and size of such components, which shifted the centre of gravity of an aircraft rearward.[38] Therefore, designers removed the canards (and the dorsal air brake) found on the Su-27M; the size of the vertical tails, aft-cockpit hump and tail boom were also reduced.[38] With such changes, as well as the increased use of aluminium and titanium alloys and composites, designers had reduced the empty weight of the aircraft,[39][40] while maintaining a similar maximum take-off weight to the Su-27M.

Su-35S cockpit layout: a head-up display, two multi-function liquid crystal displays, and a control stick with HOTAS controls
While the Su-27M design had the avionics to give the aircraft the nominal designation as a multi-role fighter, flight tests with the Russian Air Force revealed difficulties in efficiently deploying the aircraft's armament. According to Aviation Week & Space Technology, air force pilots described weapons trials with the aircraft in Akhtubinsk and Lipetsk as a "negative experience", with a particular emphasis on the layout of the cockpit and its adverse impact on the workload of the single pilot.[37] Designers, test pilots and avionics software specialists therefore worked together to redesign the cockpit and its attendant systems and improve the human-machine interface. The information management system of aircraft's avionics suite had been changed so that it now has two digital computers which process information from the flight- and weapons-control systems. The information is then displayed on two 9 in × 12 in (23 cm × 30 cm) multi-function liquid crystal displays,[41] which replaced the smaller multi-function cathode-ray tube displays found on the Su-27M.[37] The pilot can also view critical flight information on the head-up display,[42] and is equipped with Hands On Throttle-And-Stick (HOTAS) controls.[41]

The Su-35 employs the powerful N035 Irbis-E ("Snow Leopard") passive electronically scanned array (PESA) radar, which is a further development of the N011M radar that had been evaluated on Su-27M test-beds and constitutes the core of the Su-35's weapons-control system. It is capable of detecting an aerial target up to 400 km (250 mi; 220 nmi) away, and can track thirty airborne targets and engage eight of them simultaneously; in addition, the multi-function radar is capable of providing high-resolution images of the ground using synthetic aperture mode.[43] The aircraft is equipped with an OLS-35 optoelectronic targeting system ahead of the cockpit to provide other forms of tracking including infra-red search and track.[43] For defences against enemy tracking, the Su-35 is equipped with the L175M Khibiny-M electronic countermeasure system,[44] while engineers have applied radar-absorbent materials to the engine inlets and front stages of the engine compressor to halve the Su-35's frontal radar cross-section and minimise the detection range of enemy radars.[45] The multi-role Su-35 can deploy air-to-air missiles of up to 300-kilometre (190 mi) range, and can carry the heavy Oniks anti-ship cruise missile, as well as the multitude of air-to-ground weaponry.[46][47]

"The classical air combat starts at high speed, but if you miss on the first shot—and the probability is there because there are maneuvers to avoid missiles—the combat will be more prolonged. After maneuvering, the aircraft will be at a lower speed, but both aircraft may be in a position where they cannot shoot. But supermaneuverability allows an aircraft to turn within three seconds and take another shot."[48]
— Sergey Bogdan, Sukhoi chief test pilot
The Su-35 is powered by a pair of Saturn AL-41F1S turbofan engines, formerly known as izdeliye (Product) 117S. A highly upgraded variant of the AL-31F, the AL-41F1S is related to the Su-57's Saturn AL-41F1 (izdeliye 117), differing primarily in the engine control system.[49][50] The engines are equipped with thrust-vectoring nozzles, which have their rotational axes canted at an angle; the nozzles operate in one plane for pitch, but the canting allows the aircraft to produce both roll and yaw by vectoring each engine nozzle differently; this configuration was first implemented on the Su-30MKI and is also used on the Su-57.[51] The Su-35's thrust-vectoring system and integrated flight- and propulsion-control systems allow the aircraft to attain "supermaneuverability", enabling it to perform post-stall manoeuvres at low speeds. This differs from Western air combat doctrine, which emphasises the maintenance of a fighter aircraft's kinetic energy.[48]

The engine gives the Su-35 the limited ability to sustain supersonic speed without the use of afterburners.[39] According to Carlo Kopp of the think tank Air Power Australia, such a "supercruise" feature allows the Su-35 to engage an opponent at a greater speed and altitude and increases the range of its long-range missiles by 30–40 percent.[40] He cites the aircraft's mature airframe and carefully balanced combination of advanced technology as allowing the Su-35 to achieve a favourable exchange rate against the F-35 stealth fighter.[52] The US Department of Defense and Lockheed Martin had refuted criticisms of the F-35, saying that it is 400 percent more effective in air-to-air combat than any aircraft other than the F-22.[53]

Detection radius of a large ship =400 km, boats =120 km[54]

Testing and production

A Russian Air Force Su-35S during a standard takeoff procedure.
Following the completion of design work, KnAAPO constructed the first prototype, which was finished in mid-2007. The prototype, Su-35-1, was then transferred to the Gromov Flight Research Institute at Zhukovsky Airfield, in preparation for its maiden flight.[55][56] On 19 February 2008, Sergey Bogdan took the aircraft aloft for its 55-minute first flight from Zhukovsky.[55][57] Bogdan later piloted the second prototype on its maiden flight on 2 October from KnAAPO's Dzyomgi Airport.[58] The flight-test programme was expected to involve three flying prototypes, but on 26 April 2009, a day before its scheduled maiden flight, the fourth Su-35 (there's a static test aircraft) crashed during a taxi run at Dzyomgi Airport. The aircraft struck a barrier at the end of the runway and was destroyed by fire; the pilot ejected and sustained burn injuries.[59][60] The cause of the accident was the failure of the engine management system, as a result of which the afterburner was not turned off.[61][62][63]

The Su-35 project was aimed primarily at the export market.[64][65] During the early stages of the flight-test programme, Sukhoi estimated that there was such a market for 160 aircraft, with a particular emphasis on Latin America, Southeast Asia and the Middle East. Some of the candidate countries, such as Algeria, Malaysia, and India, were already operators of the Su-30MK family.[66] As the aircraft was to be available for export starting in 2010,[67][68] the actual launch order for 48 Su-35S aircraft was placed by the Russian Defence Ministry at the 2009 MAKS Air Show (as part of a larger deal worth US$2.5 billion for 64 fighter aircraft).[69] During the type's international debut at the 2013 Paris Air Show, Mikhail Pogosyan, General Director of Sukhoi's parent company United Aircraft Corporation, stated that there was an estimated demand for 200 aircraft, split evenly between the domestic and export markets.[70] It was not until the end of 2015 when the first export contract was signed with China; by then, the Russian government had placed a follow-up order for 50 aircraft.[71]

Apart from the launch order at the 2009 MAKS Air Show, the Russian government and the state-owned VEB development bank agreed to provide Sukhoi with capital for the aircraft's production.[69] In November 2009, KnAAPO (which was renamed KnAAZ in 2013 after it became part of the Sukhoi Company) started manufacturing the first production aircraft,[72] the general assembly of which was completed in October 2010;[73] by then, pilots and engineers had successfully completed preliminary tests of the aircraft's systems.[74] The first Su-35S took its maiden flight in May 2011,[75] and would be delivered (along with other aircraft) to Akhtubinsk to start state joint tests with the Defence Ministry to prepare the aircraft for service. Because production of the Su-35S occurred alongside trials, some early-production aircraft were later modified as a result of such tests.[76] In December 2018, United Aircraft Corporation has reported 100th serial Su-35S was produced at the Komsomolsk-on-Amur Aircraft Plant.[77]

Operational history
Russia
In 1996, three production Su-27Ms were delivered to the air force's 929th State Flight-Test Centre (GLITs) at Vladimirovka air base [ru], Akhtubinsk, to perform weapons trials.[20] In 2001, the air force decided to transfer several Su-27Ms to re-equip the Russian Knights aerobatics team, and so the team's pilots took familiarisation flights with the aircraft.[78] The three production and two other pre-production Su-27Ms arrived at the team's Kubinka air base near Moscow in 2003. However, they were used as a source of spare parts for other aircraft in the demonstration fleet.[79]

A Russian Air Force Sukhoi Su-35 performing at MAKS 2009 air show in Moscow
Initially, one static and three flyable prototypes (bort no. 901, 902, 904) were built between 2007 and 2009.[58] The third one (bort no. 904) was later destroyed when it crashed into a barrier during its taxi runs.[59]

The first contract for 48 production aircraft was signed at the 2009 MAKS Air show in Moscow.[69] In May 2011, Sukhoi delivered the first Su-35S to Akhtubinsk to conduct state joint tests with the Defence Ministry to prepare for operational service.[80] The first of two stages of the trials commenced in August 2011. By March 2012, the two prototypes and four production aircraft were conducting flights to test the type's technical characteristics,[80] which were assessed by the end of that year to have generally complied with requirements.[81] A batch of six production aircraft was handed over in December 2012.[82] In February 2013, five of these at the Gromov Flight Research Institute in Zhukovsky started the second stage of the trials, focusing on the Su-35's weapons and combat maneuverability.[83]

Twelve production Su-35Ss were delivered in December 2013,[84] followed by another twelve production aircraft in February 2014, ten of which were handed over to the 23rd Fighter Aviation Regiment stationed in the Far East with the remaining two tasked with carrying out the final phase of state joint tests.[76] The handover marked its official entry into operational service.[85] Several Su-35Ss were later transferred to Lipetsk to further develop combat tactics and to train service personnel.[86] The Russia's Su-35Ss are also permanently based at Besovets air base near the Finnish border,[87] and at Centralnaya Uglovaya air base near Vladivostok.[88]

Sukhoi Su-35S taxiing with drogue parachute after landing during Aviadarts contest, 2019
The introduction of the Su-35S into the service with the Russian Air Force is a part of the Russia's state armament programme for 2011–2020 that was formulated following the war with Georgia in 2008 with an aim to significantly increase the number of modern military equipment in the Russian Armed Forces.[89] The aircraft is delivered alongside the Su-30M2 and Su-30SM and the heavier Su-34 strike aircraft.[90] The first two are domestic variants of KnAAPO's Su-30MK2 and Irkut's Su-30MKI two-seat export aircraft. According to reports, the simultaneous acquisition of three fighter derivatives of the original Su-27 was to support the two aircraft manufacturers amidst a slump in export orders.[85] The Su-30M2 serves as a trainer aircraft for the Su-35.[90]

The Su-35S attained full operational capability (FOC) in late 2018.[91][92][93]

In July 2020, the Russian Knights aerobatic team received eight new Su-35Ss as an addition to its previously acquired Su-30SM aircraft.[94]

2015 Russian military intervention in Syria
Main article: Russian military intervention in the Syrian Civil War
A Russian Defence Ministry video of the Su-35S
In January 2016, Russia made the first combat deployment of the Su-35S when it sent four aircraft to Syria. This occurred following the increased tensions between Russia and Turkey as result of reported incursions by Russian aircraft into the Turkish airspace and the shooting down of a Russian Su-24 bomber by a Turkish F-16 fighter in November 2015.[95][96] The Su-35Ss deployed to Syria are to provide air cover for Su-30SMs flying combat air patrols as well as for other Russian aircraft when on bombing missions.[97] Its combat deployment to Syria helped to find and subsequently resolve number of problems, for example with the aircraft avionics.[98] Su-35s in Syria have been seen carrying unguided bombs, with Russian sources claiming that the Su-35 has carried out strikes against ground targets using guided weapons.[95]

On 20 August 2019, two Russian Air Force Su-35Ss, operating from the Khmeimim Air Base, intercepted two Turkish Air Force F-16s over the southern Idlib and forced them to leave the Syrian airspace.[99] Russian Su-35Ss again intercepted several Israeli aircraft over southern Syria on 10 September 2019 and prevented them from carrying out airstrikes.[100] Another interception allegedly occurred on 19 September 2019, when two Russian Su-35Ss intercepted Israeli aircraft preparing to attack suburbs of Damascus.[101] On 15 October 2019, a Turkish F-16 fighter was intercepted by Russian Su-35Ss and forced to retreat as it was attempting to bomb the Syrian Democratic Forces's headquarters in Manbij.[102] On 12 November 2019, Russian Su-35Ss intercepted an Israeli fighter during airstrikes on Damascus.[103] On 7 December 2019, several Israeli aircraft were intercepted by Russian Su-35Ss and forced to retreat during an attempt to bomb the T-4 Airbase.[104]

2022 Russian invasion of Ukraine
Main article: 2022 Russian invasion of Ukraine
On 3 April 2022, a Russian Su-35S crashed in eastern Ukraine. Ukrainian forces claimed to have shot it down. The pilot ejected and was captured.[105] On 18 April 2022, British newspaper Daily Express claimed the Ukrainian Air Force were able to recover parts from the wreckage and notify British intelligence. The systems were reportedly then taken to the Defence Science and Technology Laboratory (DSTL) in Porton Down, Wiltshire, where UK scientists and two US Air Force specialists spent 10 days analyzing them. After the preliminary evaluation the systems were reportedly transported to Nevada, USA, for further forensic analysis.[106][107] On 9 May, Ukraine Defence Ministry confirmed that Colonel Ihor Bedzay, the deputy head of the Ukrainian Navy, was killed in action. His Mi-14PS was shot down by a Russian Su-35.[108][109] On 19 July, an unidentified aircraft was shot down near Kakhovka. The Ukrainian Air Force command said that the plane was a Russian Su-35 shot down by Ukrainian air defences, but provided no evidence.[110][111]

China
During the early 1990s, sales arrangements for the Su-27M was discussed with China. In 1995, Sukhoi officials announced a co-production proposal contingent on Beijing's agreement to purchase 120 aircraft.[112] However, the Russian Foreign Ministry allegedly blocked the sale of the Su-27M and Tupolev Tu-22M bomber over concerns about the arrangements for Chinese production of the Su-27.[113]

In November 2015, China became the Su-35's first export customer when the Russian and Chinese governments signed a contract worth $2 billion to buy 24 aircraft for the People's Liberation Army Air Force.[114][115] Chinese officials had reportedly first shown interest in the Su-35 in 2006,[116] it was not until 2010 that Rosoboronexport, the Russian state agency responsible for the export and import of defence products, was ready to start talks with China over the Su-35.[117] Russian officials publicly confirmed that talks had been going on in 2012, when a protocol agreement on the purchase was signed.[118] There were subsequent reports of the two countries signing a contract and of imminent deliveries,[119][120] but negotiations would not actually conclude until 2015.

Sales discussions were protracted due to intellectual property rights concerns. China had reverse engineered the Su-27SK and Su-33 to create the J-11B and J-15, respectively,[121] there were fears of China copying the airframe and offer the copied design on the export market. At one stage, Rosoboronexport demanded that China issue a legally binding guarantee against copying.[121] Chinese industry was reportedly interested in the AL-41FS1 engine and Irbis-E radar.[118][122] According to The Diplomat, China held a specific interest in the Su-35's engine, and was already test flying the J-11D, which reportedly has less range, payload and manoeuvrability than the Su-35 but has an active electronically scanned array radar instead of the less advanced PESA radar of the Su-35.[123] Rosoboronexport insisted on China purchasing a minimum of 48 aircraft to offset risks of copying; after the Kremlin intervened in 2012, the minimum quantity was lowered to 24.[124] Another problem was China's insistence that the Su-35 include Chinese-made components and avionics. The Kremlin again intervened and conceded to this demand, allowed the deal to proceed; it was viewed as a major concession since the sales of such components are reportedly lucrative.[118] The contract did not include any technology transfer.[116]

The Chinese military received the first four aircraft in December 2016.[125][126] Followed by the first delivery, the People's Liberation Army's website opined that with the J-20's commissioning, Russia understood that the Su-35 would "lose its value on the Chinese market in the near future...we hope very much that Su-35 will be the last (combat) aircraft China imports."[127] China has received a second batch of ten aircraft in 2017,[128] and another ten in 2018.[3] The Su-35S entered service with PLAAF in April 2018,[129] and are based in Guangdong province in southeast China.[126] In June 2019, Russia offered China a second batch of Su-35s.[130]

On 20 September 2018, the U.S. imposed sanctions on China's Equipment Development Department and its director, Li Shangfu, for engaging in ?significant transactions? with Rosoboronexport, specifically naming China's purchase of ten Su-35s in 2017 as well as S-400 surface-to-air missile system-related equipment in 2018.[131]

Egypt
In March 2019, it was reported that Egypt would procure "over two dozen" Su-35s from Russia in a deal valued about $US2 billion, finalized in late 2018. Deliveries were expected to begin as early as 2020 or 2021.[132][133] Deputy head of the Rosoboronexport Sergei Kornev denied the signing of any contract to supply Su-35s to Egypt.[134] U.S. Secretary of State Mike Pompeo warned Egypt against buying Su-35s, saying "if those systems were to be purchased, the CAATSA statute would require sanctions on the regime."[135]

On 19 May 2020, Russia began Su-35 production for Egypt,[136] and first five production aircraft took off from the KnAAZ plant on 28 July 2020.[137] By June 2021, in total 17 aircraft were produced for Egypt.[4][138] In May 2022, two more Egyptian Su-35s, 9221 and 9237, were seen at their final phase of construction at the Komsomolsk-on-Amur Aircraft Plant, indicating the deal is still valid.[139]

Potential operators
United Arab Emirates
In the mid-1990s, the United Arab Emirates evaluated the Su-27M,[140] but later acquired the Mirage 2000 due to the country's close relationship with France.[25] In February 2017, the country was to sign a preliminary agreement for the Su-35 purchase and also signed an agreement with Rostec, Russia's state-owned corporation responsible for the development of advanced industrial products, to develop a fifth-generation aircraft based on the MiG-29.[141]

India
India has been reluctant to order the Sukhoi/HAL FGFA due to high cost, and it has been reported that India and Russia are studying an upgrade to the Su-35 with stealth technology (similar to the F-15 Silent Eagle) as a more affordable alternative to the FGFA (Su-57).[142] The aircraft is competing with 7 other aircraft in a fresh tender which is referred as MMRCA 2.0 in the Indian media, for the procurement of 114 multi-role combat aircraft.[143]

Algeria
According to Kommersant, the Algerian military had requested a Su-35 for testing in February 2016; it was reported the country was satisfied with the fighter's flight characteristics and so Moscow is waiting for a formal application.[144] On 27 December 2019, Algeria has reportedly signed a contract for 14 aircraft as part of large military deal that also includes purchase of Su-34 and Su-57 fighters.[145] However, neither Russian nor Algerian governments ever confirmed that such deal exists.

Turkey
In July 2019, Russia offered the Su-35 to Turkey after it was removed from the F-35 programme by United States due to the purchase of S-400 missile system.[146] CEO of Rostec Sergey Chemezov, said, "If our Turkish colleagues express a desire, we are ready to work out the deliveries of Su-35 fighter jets".[147] Previously in May 2019, Sergey Chemezov had said that Russia was ready to cooperate with Turkey on the export and local production of the Su-57.[148]

Others
Following the deployment to Syria of several new Russian military systems, various countries had reportedly expressed interest in the Su-35. These countries included Algeria, Egypt, and Vietnam.[144][149][150] Other countries that had also expressed interest in the aircraft include Kazakhstan,[151] North Korea,[152] and Pakistan although a Russian official denied that the country was in talks with the latter about the Su-35.[citation needed] Sudan has reportedly also expressed an interest in acquiring of the Su-35 fighters during the Sudanese president Omar Hassan al-Bashir's visitation of Moscow in November 2017.[153]

Failed bids
Brazil
In the mid-1990s, Brazilian and Russian authorities conducted talks on the possible acquisition of the Su-27M.[154] In 2001, the Brazilian government launched the F-X tender, the objective of which was to procure at least 12 aircraft to replace the Brazilian Air Force's ageing aircraft, primarily the Mirage IIIs.[155][156] Since the Brazilian government was also looking to develop the country's aerospace and defence industries, Sukhoi partnered with the Brazilian defence contractor Avibras during the tender. The two companies submitted the Su-27M to the US$700-million tender, and included an offset agreement wherein the Brazilian industry would have participated in the manufacturing of certain aircraft equipment.[157] The tender was suspended in 2003 because of domestic political issues and then scrapped in 2005, pending the availability of new fighters.[155] The Su-27M was preferred over the next favourite, the Mirage 2000BR;[156] had the aircraft been purchased, it would have been the first heavy fighter delivered to Latin America.[154]

With the tender relaunched in 2007 as the F-X2 competition, the Brazilian Defence Ministry looked to purchase at least 36 aircraft – with a potential for 84 additional aircraft – to replace the country's A-1Ms, F-5BRs, and Mirage IIIs. Among the participants were the F/A-18E/F Super Hornet, F-16BR, JAS Gripen NG, Dassault Rafale, Eurofighter Typhoon and the modernized Su-35.[citation needed] Although the Brazilian government eliminated the Su-35 in 2008,[158] Rosoboronexport subsequently offered to sell the country 120 aircraft with full technology transfer,[159] as well as participation in the PAK FA programme.[160] In December 2013, the Gripen NG light fighter was selected because of its low cost and the transfer of technology to the Brazilian industry.[161]

Indonesia
In 2014, Russia offered the Su-35 to Indonesia to replace its ageing F-5E Tiger II fleet.[162] The following year, the Indonesian Ministry of Defense selected the Su-35 ahead of the Eurofighter Typhoon, Dassault Rafale, F-16, and Saab JAS 39 Gripen; the Defense Ministry cited the Indonesian Air Force's familiarity with the Su-27SK and Su-30MK2 as the reason for its selection.[163][164] By 2017, negotiations between the two parties over the Su-35 had reached an advanced stage,[165] with the Indonesian government later agreed in principle to conduct a barter trade of agricultural products for a reported eleven aircraft.[166] In February 2018, Russia and Indonesia finalised an contract for 11 aircraft, worth $1.14 billion.[167] The first delivery was expected in October 2018,[168][169] but was delayed to 2019.[170]

On 12 March 2020, Bloomberg reported that Indonesia canceled the deal due to the US pressure and is instead looking to negotiate an order for F-35s.[171] On 18 March 2020, Indonesia's Deputy Defense Minister Sakti Wahyu Trenggono confirmed that the government had not revoked the procurement despite facing unnamed "obstacles".[172] On 8 July 2020, Russian Ambassador to Indonesia, Lyudmila Vorobieva stated that Indonesia's plan to buy 11 Su-35s from Russia is still continuing.[173] In February 2021, the Chief of Staff of the Indonesian Air Force Air Chief Marshal Fadjar Prasetyo unveiled plans to purchase new aircraft such as F-15EX and Dassault Rafale while not mentioning the current status of the Su-35 order.[174] However In 22 December 2021 during a Press Tour and Media Gathering, Fadjar Prasetyo has confirmed that the Su-35 purchase will not go ahead. Regarding the planned purchase of the Sukhoi Su-35, Fadjar said it would be abandoned.[175]

Others
In 1996, Russia submitted the Su-27M and Su-37 for South Korea's F-X programme, which sought a 40-aircraft replacement for the Republic of Korea Air Force's F-4D/Es, RF-4Cs and F-5E/Fs. The two Russian designs competed against the Dassault Rafale, Eurofighter Typhoon, and F-15K Slam Eagle.[176] Sukhoi proposed a design which featured a phased-grid radar and thrust-vectoring engines, and offered full technology transfer as well as final assembly in South Korea. The US$5 billion contract would have been partially financed through a debt-reduction deal on money Russia owed to South Korea.[177][178] However, the Su-27M was eliminated early in the competition, which was won by the F-15K.[179]

A country that had been reported to be a likely early export customer for the modernized Su-35 was Venezuela. The Venezuelan government of Hugo Chávez in July 2006 placed an order for 24 Su-30MK2s to replace its fleet of F-16s that were subjected to a US arms embargo.[180] The aircraft were delivered to the Venezuelan Air Force from 2006 to 2008.[citation needed] The country was expected to follow up with a second order for the same type, or make a purchase of the Su-35.[181] Despite subsequent reports that the Venezuelan government were interested in the aircraft and had placed an order for the Su-35,[182][183]

Libya was also expected to be an early export customer for 12 to 15 Su-35s along with other Russian weapons; however, the civil war in Libya and the resulting military intervention cancelled such plans.[184] Russia has also offered the modernized Su-35 to India, Malaysia, and Greece;[66][185] no firm contracts have materialised, with the first two countries having been occupied with other fighter projects and unlikely to procure the modernized Su-35.[36]

Variants
Su-27M/Su-35
Single-seat fighter design with a factory code of T-10M (Modernizerovany, "Upgraded"). The first two prototypes had a new forward fuselage, canards and updated fly-by-wire flight-control systems. Like three of KNAAPO's nine flying pre-production aircraft (T10M-5, T10M-6 and T10M-7), they were converted from Su-27 airframes.[186][187] The third aircraft (T10M-3) was the first of seven pre-production aircraft to have the taller vertical tails, two-wheel nose undercarriage and in-flight refuel capability.[18] The Su-27M was powered by AL-31FM turbofan engines.[16] Two prototypes, nine pre-production and three production aircraft were constructed by 1995;[1] two static-test aircraft was also constructed (T10M-0 and T10M-4).[188] The aircraft did not enter mass production.

Sukhoi Su-37 at Farnborough 1996 airshow
Su-37
Technology demonstrator, converted from the eleventh developmental Su-27M (T10M-11). The Su-37 featured a digital fly-by-wire flight-control system, a glass cockpit, the N011M radar, and AL-31FP engines with thrust-vectoring nozzles.[189] The aircraft was later fitted with standard-production AL-31F engines, and had its flight-control system and cockpit systems revised.[190]

The sole two-seat Su-35UB in 2001
Su-35UB
Two-seat trainer designed and built by KnAAPO. The single aircraft (T-10UBM-1) featured the canards and taller vertical tails of the Su-27M and a forward fuselage similar to the Su-30MKK. The Su-35UB also shared the avionics suite of the Su-30MKK, although it had a different fly-by-wire flight-control system to accommodate the canards.[191] The aircraft was powered by AL-31FP engines with thrust-vectoring nozzles.[192] Although a training aircraft, the Su-35UB was designed to be fully combat-capable.[191]
Su-35BM
Single-seat fighter that is a major redesign of the original Su-27. The type features significant modifications to the airframe, including the removal of canards and dorsal air brake as found on the Su-27M. It features the updated N035 Irbis-E radar and a redesigned cockpit. The aircraft is powered by thrust-vectoring AL-41F1S turbofan engines that are capable of supercruise. Also known as T-10BM (Bolshaya Modernizatsiya, "Major Modernization"), Su-35BM is not the actual designation used by Sukhoi, who markets the aircraft as "Su-35".[69][193]
Su-35S
Designation of production T-10BM design for the Russian Air Force. According to Aviation Week & Space Technology, "S" stands for Stroyevoy ("Combatant").[122]
Operators
China
People's Liberation Army Air Force – 24 aircraft in inventory.[3]
6th Aviation Brigade – Suixi air base, Guangdong[126]
Egypt
Egyptian Air Force – 24 on order.[194]
Russia
Russian Air Force – 103 aircraft in inventory as of December 2021.[195][2][196] The third order for 30 aircraft finalised in August 2020 is to increase the total number to 128.[71][197][198]
23rd Fighter Aviation Regiment – Dzyomgi Airport, Khabarovsk Krai[76]
22nd Guards Fighter Aviation Regiment – Centralnaya Uglovaya Air Base, Primorsky Krai[88]
159th Fighter Aviation Regiment – Besovets Air Base, Republic of Karelia[citation needed]
790th Fighter Aviation Regiment – Borisovsky Khotilovo Air Base, Tver Oblast[199][200]
4th Centre for Combat Employment and Retraining of Personnel – Lipetsk Air Base, Lipetsk Oblast
929th State Flight-Test Centre – Vladimirovka Air Base, Astrakhan Oblast
Khmeimim Air Base, Latakia, Syria[201]
Notable accidents
The fourth Su-35BM prototype was destroyed in a high-speed taxi run on 26 April 2009 due to brake failure. The aircraft crashed into the barrier at the end of the runway and was destroyed. The pilot ejected and sustained burn injuries.[59]

On 31 July 2021, a Su-35S fighter crashed after suffering an engine failure during a routine training mission in the Khabarovsk Territory in Russia according to statement from the Russian Defence Ministry.[202] According to a preliminary investigation reported by the Russian newspaper Top War, the Su-35 suffered technical malfunctions in the environment control systems that indicate heating and cooling functions.[citation needed]

Specifications (Su-35S)

Irbis-E radar for the modernized Su-35 at MAKS Airshow 2009

GSh-30-1 cannon in starboard wing root, Su-35, Paris Air Show 2013
Data from KnAAPO,[42][203] Jane's All The World's Aircraft 2013[204]

General characteristics

Crew: 1
Length: 21.9 m (71 ft 10 in)
Wingspan: 15.3 m (50 ft 2 in)
Height: 5.9 m (19 ft 4 in)
Wing area: 62 m2 (670 sq ft)
Airfoil: 5%
Empty weight: 19,000 kg (41,888 lb) [205]
Gross weight: 25,300 kg (55,777 lb) with 50% internal fuel
Max takeoff weight: 34,500 kg (76,059 lb)
Fuel capacity: 11,500 kg (25,400 lb) internal
Powerplant: 2 × Saturn AL-41F1S afterburning turbofan engines, 86.3 kN (19,400 lbf) thrust each dry, 137.3 kN (30,900 lbf) with afterburner, 142.2 kN (32,000 lbf) in emergency power
Performance

Maximum speed: 2,400 km/h (1,500 mph, 1,300 kn) / M2.25 at altitude
1,400 km/h (870 mph; 760 kn) / M1.13 at sea level
Cruise speed: 1,170 km/h (730 mph, 630 kn) / M1.1+ supercruise at medium altitude[206]
Range: 3,600 km (2,200 mi, 1,900 nmi) at altitude
1,580 km (982 mi) at sea level
Combat range: 1,600 km (990 mi, 860 nmi) approx[207]
Ferry range: 4,500 km (2,800 mi, 2,400 nmi) with 2 external fuel tanks
Service ceiling: 18,000 m (59,000 ft)
g limits: +9
Rate of climb: 280 m/s (55,000 ft/min) +
Wing loading: 408 kg/m2 (84 lb/sq ft) With 50% fuel
500.8 kg/m2 (102.6 lb/sq ft) with full internal fuel
Thrust/weight: 1.13 with 50% fuel
0.92 with full internal fuel
Armament
Guns: 1 × internal 30 mm Gryazev-Shipunov GSh-30-1 autocannon with 150 rounds
Hardpoints: 12 hardpoints, consisting of 2 wingtip rails, and 10 wing and fuselage stations with a capacity of 8,000 kg (17,630 lb) of ordnance, with provisions to carry combinations of:
Rockets:
S-25 air-ground rocket
Air-to-air missiles:
8 × R-27ER/ET
6 × R-73E/M
12 × R-77M/P/T
6 × R-74
2 x R-37[208]
Air-to-surface missiles:
6 × Kh-29L/TE
3 × 3M-14AE
Anti-ship missiles:
3 × 3M-54AE1
6 × Kh-31A/AD
Kh-35U
5 × Kh-59MK
1 × Yakhont
Anti-radiation missiles:
6 × Kh-31P/PD
5 × Kh-58UShE
Bombs:
8 × KAB-500KR TV-guided bombs
8 × KAB-500L laser-guided bombs
8 × KAB-500OD guided bombs
8 × KAB-500S-E satellite-guided bombs
3 × KAB-1500KR TV-guided bombs
3 × KAB-1500L laser-guided bombs
GBU-500 laser-guided bomb
GBU-500T TV-guided bomb
GBU-1000 laser-guided bomb
GBU-1000T TV-guided bomb
Avionics
Irbis-E passive electronically scanned array radar
OLS-35 infra-red search and track system
L175M Khibiny-M electronic countermeasures system[44]
Notable appearances in media

Spotlights

General Characteristics

  • Created On Windows
  • Wingspan 53.9ft (16.4m)
  • Length 84.3ft (25.7m)
  • Height 21.6ft (6.6m)
  • Empty Weight 23,511lbs (10,664kg)
  • Loaded Weight 37,605lbs (17,057kg)

Performance

  • Power/Weight Ratio 8.127
  • Wing Loading 36.1lbs/ft2 (176.2kg/m2)
  • Wing Area 1,042.1ft2 (96.8m2)
  • Drag Points 18918

Parts

  • Number of Parts 532
  • Control Surfaces 8
  • Performance Cost 2,089