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BrahMos-II

BrahMos-II is a hypersonic under joint development by India's and Russia's defense entities, utilizing air-breathing propulsion to achieve speeds exceeding Mach 5. Designed as a successor to the supersonic missile, it incorporates and niche technologies to enable high impacts, generating forces up to 36 times that of an object at Mach 1. The project, cleared with substantial investment, focuses on scramjet technology for sustained over six times the , minimizing enemy reaction times for strikes on hardened targets like bunkers. Initial development emphasizes "technology bricks" and clusters in collaboration with India's (DRDO), positioning -II as a potential game-changer in aerospace and capabilities. Capable of multi-platform launches from land, sea, and air, the addresses challenges in , with ongoing efforts to overcome technical hurdles such as sustained . As of 2025, the program has seen renewed momentum through Indo-Russian cooperation, building on successful tests and aiming for operational deployment amid global hypersonic advancements. While specific range figures remain undisclosed officially, projections suggest capabilities extending beyond 600 km, enhancing strategic deterrence. Development delays attributable to the inherent complexities of hypersonic underscore the empirical challenges, yet progress in related signals feasibility.

Development and History

Origins and Initial Concept

The BrahMos-II, also known as BrahMos-2, originated as a proposed hypersonic successor to the supersonic BrahMos cruise missile, developed through the Indo-Russian joint venture BrahMos Aerospace. Following the successful induction of the original BrahMos into Indian armed forces, the need for a next-generation variant capable of hypersonic speeds arose to counter evolving air defense systems and reduce target engagement times. The initial push came in June 2007, when then-Indian President A.P.J. Abdul Kalam, during the commencement of BrahMos deliveries to the Indian Army, stated that the time had arrived for BrahMos Aerospace to pursue development of a Mark-II version leveraging advanced propulsion technologies. Formal conceptualization advanced through bilateral agreements. On 29 September 2008, the Indo-Russian intergovernmental commission on military-technical cooperation agreed to initiate development of the hypersonic variant and established a joint working group to oversee the project. This marked the transition from conceptual discussions to structured collaboration between India's (DRDO) and Russia's . The missile was envisioned as retaining the physical dimensions and compatibility of the original for integration with existing ship, submarine, land, and air launch platforms, while incorporating scramjet propulsion for sustained . The core initial design focused on achieving speeds exceeding Mach 6 (approximately 7,400 km/h), with an operational range capped at 290 km to comply with (MTCR) restrictions prevailing at the time. This hypersonic capability was intended to enable rapid strikes against heavily fortified targets, such as deeply buried nuclear bunkers, by minimizing enemy detection and interception windows. In August 2009, the Indian government approved a multi-billion-dollar allocation for the joint effort, emphasizing the missile's versatility across multiple deployment modes and its role as India's most advanced weapon system to date.

Indo-Russian Joint Venture Formation

The Private Limited joint venture, responsible for developing the hypersonic BrahMos-II missile, originated from an Inter-Governmental Agreement signed on February 12, 1998, in between the governments of and . This agreement established the company with an authorized capital of US$250 million, allocating a 50.5% stake to (DRDO) and 49.5% to , headquartered in to oversee joint design, development, production, and marketing of cruise missiles. Although initially focused on the supersonic missile, the venture expanded to encompass hypersonic technologies, with conceptual work on BrahMos-II proposed in 2007 by then-President to leverage propulsion for speeds beyond 5. Formal commitment to the hypersonic variant materialized through announcements by the defence ministers of both nations in 2008 during a Russian ministerial visit to BrahMos facilities, signaling intent for collaborative advancement. A pivotal Memorandum of Understanding (MoU) was signed in September 2009 between DRDO and , finalizing parameters for , including a target speed exceeding 6 (approximately 7,400 km/h), a 290 km range constrained by guidelines, and compatibility with existing launch platforms to minimize infrastructure changes. The MoU outlined joint engine development, with providing airframe and propulsion expertise derived from its program, while contributed guidance and integration capabilities; induction was initially projected for 2015 but has faced delays due to technological complexities.

Key Milestones and Technological Hurdles

The BrahMos-II hypersonic project was conceptualized in 2008 as a between India's (DRDO) and Russia's NPO Mashinostroyenia, aiming to achieve speeds of 7-8 using propulsion. Development progressed slowly due to international restrictions, but India's accession to the (MTCR) in 2016 enabled extensions in range beyond initial limits of 290 km, facilitating renewed focus on hypersonic capabilities. A significant setback occurred in 2019 when the program was effectively shelved amid disagreements over and Russia's adherence to MTCR guidelines, delaying scramjet integration efforts. Momentum revived in 2024-2025 following successful operational use of the baseline in strikes and DRDO's ground tests, including a scramjet combustor demonstration exceeding 1,000 seconds of sustained operation in April 2025. Russian officials projected program completion by 2028, with potential induction into Indian forces targeted for 2030, contingent on resolving bilateral technical alignments. Key technological hurdles include mastering engine stability at hypersonic velocities, where air-breathing propulsion demands precise and amid extreme exceeding 2,000°C, necessitating advanced thermal protection materials unproven at scale. Thermal management persists as a core challenge, with sustained flight requiring innovations in heat-resistant composites to prevent structural failure, compounded by limited real-world testing data from either partner. International collaboration has faced friction over rights and terms, with historically cautious on sharing proprietary scramjet designs, exacerbating delays alongside high development costs estimated in billions. Logistical obstacles, such as integrating hypersonic guidance systems resistant to plasma-induced blackouts during re-entry-like phases, further impede progress, demanding iterative ground and component validations before full flight trials.

Technical Design and Features

Propulsion System and Hypersonic Capabilities

The propulsion system of BrahMos-II centers on a (supersonic combustion ramjet) engine, an air-breathing technology designed for sustained . Unlike the engine in the original BrahMos supersonic missile, which relies on subsonic combustion, the scramjet maintains supersonic airflow through the combustor, enabling operation at velocities exceeding without mechanical compressors. This design leverages the missile's forward motion to compress incoming air, mix it with fuel, and ignite it in a high-speed flow, producing via exhaust expansion. The engine's development draws on joint Indo-Russian expertise, with India's (DRDO) contributing scramjet prototypes tested in hypersonic wind tunnels, while provides integration support from its Zircon program experience. Hypersonic capabilities of BrahMos-II are projected to achieve cruise speeds of 7 to 8 (approximately 8,600–9,800 km/h), significantly surpassing the Mach 3 speeds of its predecessor. This velocity regime allows the missile to follow unpredictable quasi-ballistic or low-altitude trajectories, reducing intercept windows for defenses and enhancing penetration against hardened targets. The 's efficiency in the hypersonic domain supports a potential range of up to 1,500 km, enabled by minimized drag and optimized fuel consumption during sustained powered flight. Initial boost to scramjet ignition is provided by a solid or liquid booster, transitioning to air-breathing mode at around Mach 3–4, as demonstrated in DRDO's subscale scramjet trials achieving short-duration hypersonic burns. Key challenges in realizing these capabilities include managing extreme thermal loads from , which can exceed 1,000°C on leading edges, necessitating advanced materials like carbon-carbon composites and systems. Development milestones include ground-based tests by DRDO in 2016–2020, validating combustion stability, though full-system integration remains pending as of 2025. The prioritizes indigenous Indian components for BrahMos-II, reducing reliance on foreign propulsion tech while leveraging Russian hypersonic know-how.

Range, Speed, and Payload Specifications

The BrahMos-II is designed to achieve a maximum range of approximately 1,500 kilometers, enabling strikes deep into enemy territory from launch platforms such as ships, , or . This extended reach represents a significant advancement over the original supersonic missile's 290–800 kilometer variants, facilitated by efficient propulsion that minimizes fuel mass relative to distance. Earlier projections from 2018 cited a more conservative 600 kilometer range, but recent developments, including successful scramjet tests by India's (DRDO), have supported scaling to 1,500 kilometers. In terms of speed, the missile is engineered for hypersonic velocities between 6 and 8, with operational targets emphasizing sustained 7–8 cruise after booster separation. This performance relies on an air-breathing engine, which ignites supersonic airflow in the combustor to generate thrust without traditional rocket fuel dependency during the cruise phase. Official statements confirm velocities exceeding 6 as a baseline, derived from subscale validations conducted by DRDO in 2024–2025. Payload specifications for the BrahMos-II center on a conventional high-explosive , with capacity estimated at 200–300 kilograms, akin to its supersonic predecessor but optimized for hypersonic delivery to penetrate advanced air defenses. The design prioritizes from speed over warhead mass, allowing for modular including anti-ship or land-attack variants, though exact configurations remain classified pending full-scale integration. Development focuses on ensuring payload integrity under extreme thermal and aerodynamic stresses at hypersonic regimes.

Guidance and Stealth Elements

The guidance system of BrahMos-II is designed to ensure precise targeting during regimes, incorporating advanced inertial navigation systems () for mid-course updates, augmented by (GPS) integration for enhanced accuracy over long ranges. Terminal guidance employs (RF) seekers developed indigenously by India's (DRDO), which provide active homing capabilities resistant to jamming. These systems enable the missile to execute maneuvers at speeds exceeding Mach 7, maintaining lock-on against mobile or hardened targets despite plasma sheath effects that can disrupt conventional signals during atmospheric re-entry. Stealth elements in BrahMos-II focus on reducing radar cross-section (RCS) through aerodynamic shaping, low-observable materials, and sea-skimming flight profiles that exploit masking and horizon effects to evade detection. The missile's hypersonic velocity inherently challenges interceptors by compressing reaction times, but dedicated features—such as -absorbent coatings and minimized protrusions—further diminish its and electromagnetic signatures compared to its supersonic predecessor. These attributes are projected to allow penetration of advanced air defense networks, though full efficacy remains unverified pending flight tests scheduled post-2025.

Testing and Validation

Component and Ground Tests

The (DRDO) conducted a groundbreaking ground test of a engine on April 25, 2025, sustaining combustion for over 1,000 seconds at the newly inaugurated test facility, marking a significant advancement in hypersonic propulsion validation for the BrahMos-II. This endurance test demonstrated stable supersonic combustion under simulated flight conditions, essential for the missile's -powered hypersonic phase, and was performed using indigenous technologies to manage extreme thermal loads exceeding 2,000 . Earlier, on January 21, 2025, DRDO's (DRDL) successfully executed a 120-second ground test of an actively cooled combustor, the first such demonstration in , validating , ignition, and flame stabilization mechanisms critical for sustained hypersonic operation. These tests build on prior hypersonic technology demonstrator efforts, including subscale validations that confirmed integration and thermal management components under high-enthalpy flows. Component-level evaluations have focused on the scramjet's isolator, inlet diffuser, and nozzle elements, with ground-based simulations at 6-8 replicating aerodynamic and aero-thermal stresses to refine material compositions like carbon-carbon composites for heat resistance. Over 130 iterative tests on subscale prototypes have iterated designs for the BrahMos-II's propulsion module, ensuring compatibility with the missile's booster stage separation at altitudes above 30 km. These ground validations, conducted at facilities like the High , have de-risked integration challenges prior to full-system assembly.

Scramjet Engine Development Trials

Development of the scramjet engine for BrahMos-II has centered on ground-based testing conducted by India's (DRDO), aiming to achieve sustained hypersonic propulsion at speeds up to Mach 8. On January 21, 2025, DRDO performed a scramjet engine ground test lasting 120 seconds, validating initial combustion stability and airflow dynamics under simulated hypersonic conditions. This was followed by a significant advancement on April 25, 2025, when DRDO successfully tested the scramjet combustor for over 1,000 seconds, demonstrating prolonged fuel-air mixing and heat management critical for BrahMos-II's air-breathing propulsion phase. These trials build on DRDO's indigenous expertise, with the engine design intended to replace the in BrahMos-II, enabling cruise speeds exceeding 7 after an initial booster phase. No integrated flight tests of the -powered BrahMos-II configuration have occurred as of October 2025, with ground validations focusing on resolving thermal and aerodynamic challenges inherent to sustained supersonic combustion.

Planned Full-Scale Flight Tests

Following the successful ground and component tests, including the Defence Research and Development Organisation's (DRDO) combustor validation on April 25, 2025, which demonstrated sustained hypersonic combustion at 6-equivalent conditions, full-scale flight tests of the BrahMos-II are anticipated to commence in 2026 or 2027. These tests will integrate the -powered with a for initial acceleration, aiming to validate end-to-end hypersonic cruise at speeds of 7–8 over ranges potentially exceeding 1,000 km, drawing partially on Zircon missile technology for propulsion and guidance synergies. Historical timelines for these trials have repeatedly shifted due to challenges in thermal management, materials for extreme aerothermal loads, and joint Indo-Russian coordination, with initial targets set for 2015 under the 2008 agreement but postponed amid integration hurdles. Renewed high-level talks between and in May 2025 signal accelerated progress, potentially incorporating indigenous DRDO advancements to mitigate dependencies, though full operational clearance may extend to 2028 or later per Russian industry assessments. The trials are expected to occur from Indian test ranges such as Chandipur or , involving sea-skimming or high-altitude trajectories to assess maneuverability, stealth features, and precision guidance under hypersonic conditions, building on subscale (HSTDV) flights that achieved 22–23 seconds of burn in 2020. Multiple developmental sorties are projected, prioritizing air- and ship-launched variants for compatibility with Su-30MKI fighters and surface combatants, with success hinging on resolving airflow instability and reliability observed in prior isolated engine runs.

Strategic and Operational Role

Integration with Indian Defense Platforms

The BrahMos-II hypersonic cruise missile is designed for multi-platform deployment, enabling launches from land-based mobile systems, sea-based naval vessels, and aircraft to support integrated operations across the Indian Army, Navy, and Air Force. This versatility builds on the modular architecture of the BrahMos family, allowing adaptation to vertical launch systems on warships for anti-ship and land-attack roles, though the scramjet propulsion demands enhanced thermal management and structural reinforcements compared to supersonic variants. Naval integration focuses on surface combatants and potentially submarines, leveraging existing universal launchers while addressing the missile's higher mass and velocity profile, which could limit canister compatibility without redesigns. Air-launched configurations target fighter platforms capable of carrying heavier payloads, with ongoing evaluations to ensure compatibility amid the program's developmental phase. Land systems emphasize mobile transporter-erector-launchers for rapid deployment in forward areas, aligning with India's emphasis on . As of 2025, detailed platform-specific modifications remain prospective, pending successful validation and full-scale tests, with joint India-Russia efforts prioritizing with assets like Project 15B destroyers and derivatives where feasible.

Deterrence Value Against Regional Threats

The hypersonic profile of BrahMos-II, with speeds exceeding Mach 7, equips with a designed to evade and overwhelm regional air defense architectures, thereby strengthening conventional deterrence against potential aggressors. This capability addresses vulnerabilities in slower supersonic missiles by enabling low-altitude, maneuverable trajectories that reduce reaction windows for interceptors, a critical factor in scenarios involving time-sensitive strikes on mobile or hardened targets. In the context of tensions with , BrahMos-II enhances India's posture along the by countering the People's Liberation Army's layered defenses, such as S-400 equivalents, through rapid penetration and precision guidance, potentially targeting command nodes or logistics hubs deep inland. This offsets Beijing's numerical advantages in conventional forces and hypersonic developments, fostering a mutual that discourages escalatory border incursions, as evidenced by India's accelerated testing to match regional arms dynamics. Against , the missile counters emerging asymmetries, including reported acquisitions of DF-17 hypersonics, by providing with standoff range options exceeding 600 km that bypass limited indigenous defenses like the HQ-16, imposing costs on any preemptive or retaliatory strategies. Multi-domain launch compatibility— from , fighters, and ground batteries—amplifies this effect, ensuring survivable delivery in contested environments and signaling resolve without relying on thresholds.

Comparative Advantages Over Supersonic Predecessors

The BrahMos-II, designed as a hypersonic powered by a engine, achieves projected speeds of 7 to 8, substantially exceeding the 2.8 to 3.0 velocities of its supersonic predecessor, the BrahMos-I. This velocity differential shortens flight times dramatically—for instance, over a 600 km range, reducing transit from approximately 10-12 minutes for the BrahMos-I to under 4 minutes—compressing adversary detection, tracking, and windows to levels that overwhelm conventional air defense reaction cycles. Hypersonic flight enables the BrahMos-II to maintain low-altitude, sea-skimming trajectories with enhanced maneuverability, contrasting the more predictable paths of supersonic cruise missiles like the BrahMos-I, which are vulnerable to radar-guided interceptors optimized for Mach 3 speeds. The sustained high-speed regime, above , generates plasma sheaths that degrade returns and complicates for defenses, while the missile's design incorporates potential for evasive maneuvers during , increasing survivability against layered missile shields such as S-400 systems. This penetration edge stems from the causal physics of hypersonic , where speed-induced heating and airflow dynamics render tracking algorithms for slower threats inadequate. Upon impact, the BrahMos-II's hypersonic velocity imparts yielding approximately 36 times the destructive force of a 1 strike for equivalent mass, surpassing the BrahMos-I's supersonic impact effects and reducing reliance on size for target neutralization. Projected ranges of 600 to 1,500 km further extend standoff capabilities beyond the BrahMos-I's 450-800 km envelope, allowing strikes on high-value inland assets without exposing launch platforms to counterfire. These attributes collectively elevate the BrahMos-II's role in saturation attacks, where fewer missiles can achieve effects previously requiring volleys of supersonic variants to saturate defenses.

Challenges and Criticisms

Development Delays and Cost Overruns

The BrahMos-II hypersonic program, initiated as a between India's (DRDO) and Russia's in the early , has faced protracted delays in achieving key milestones. Originally targeted for operational deployment around 2017, the project encountered technical hurdles in engine integration and design, compounded by challenges in from . Flight testing, initially slated to commence by 2020, remains pending as of 2025, with projections now shifted to 2026–2027 due to iterative ground trials and validation of hypersonic propulsion systems. These setbacks stem partly from geopolitical factors, including Russia's initial reluctance to share sensitive hypersonic technologies amid and export controls following its 2014 and subsequent events. Coordination issues between the partners, alongside DRDO's broader history of extended timelines in advanced missile programs, have further prolonged development; for instance, demonstrator tests conducted in the mid-2010s required multiple redesigns to address thermal management and challenges. Recent efforts, including bilateral discussions in 2025, aim to revive momentum, but persists regarding adherence to revised schedules given past patterns in Indo-Russian collaborations. On the financial front, while specific overrun figures for BrahMos-II are not publicly detailed, the program's escalating costs—driven by imported components, repeated prototyping, and R&D investments—have prompted temporary halts. A related hypersonic variant, BrahMos-2K, was shelved in late 2024 owing to prohibitive development expenses exceeding initial projections, highlighting fiscal pressures amid India's push for alternatives. Overall, DRDO's hypersonic initiatives, including BrahMos-II, reflect systemic cost escalations typical of high-risk defense R&D, where initial budgets for and materials testing have ballooned due to iterative failures and dependencies. These overruns underscore the trade-offs in pursuing 7–8 capabilities, with total program funding undisclosed but aligned with broader allocations for next-generation missiles estimated in the billions of rupees.

Technical Risks in Hypersonic Technology

Developing engines for BrahMos-II involves overcoming inherent instabilities in supersonic combustion, where airflow velocities preclude traditional subsonic mixing and require systems capable of rapid ignition and flame stabilization within milliseconds. India's HSTDV program demonstrated functionality for 22-23 seconds at 6 during a 2020 ground test, yet scaling to the sustained duration needed for a 600-800 km range flight at 7-8 demands unresolved advancements in injector design and to prevent engine . These hurdles have contributed to program delays, with initial integration targets from 2014 remaining unmet as of 2025. Aerodynamic heating at hypersonic speeds generates surface temperatures exceeding 2000 K on the missile's , risking structural deformation and component failure without effective thermal protection. BrahMos-II relies on composite hulls with specialized alloy coatings developed since 2014, but sustaining integrity under prolonged frictional heating—unlike brief boost-glide profiles—exacerbates and oxidation, as evidenced by limitations in prior HSTDV trials requiring augmentation. Material degradation under these conditions, including ceramic-matrix composites for leading edges, poses a cascading to and viability. Airframe-engine integration amplifies risks, as scramjet inlets must manage shockwave interactions and inlet unstart while minimizing drag, with fuel fractions limited to around 10% by volume constraints that intensify thermal loads over extended ranges. Low-density fuels like hydrogen, potentially viable for cooling, introduce storage and leakage challenges in a compact cruise missile configuration. These factors, compounded by the need for seamless transition from solid rocket booster acceleration to scramjet mode above Mach 4, have delayed full-scale validation, underscoring the empirical gaps between laboratory demonstrations and operational reliability.

Geopolitical Dependencies on Russian Partnership

The development of BrahMos-II, a hypersonic intended to achieve speeds of 6-8, fundamentally depends on the Indo-Russian framework established through , a 50.5:49.5 equity partnership between India's (DRDO) and Russia's . This collaboration extends the original supersonic missile program, initiated in 1998, by incorporating Russian expertise in hypersonic propulsion, particularly engine technology derived from systems like the missile. India formally requested (ToT) for Zircon-related hypersonic components in April 2023 to advance BrahMos-II's air-breathing engine, which remains a critical bottleneck without Russian input. Russia's historical reluctance to fully disclose proprietary designs has stalled progress, as evidenced by delays in finalizing the agreement despite renewed discussions in 2025. Geopolitical tensions, particularly Western sanctions imposed on Russia following its 2022 invasion of Ukraine, introduce supply chain vulnerabilities and payment complications for dual-use technologies essential to BrahMos-II. These measures, intensified in 2022, have disrupted global semiconductor and precision component flows, indirectly affecting defense exports and raising risks of production halts or cost escalations for India-dependent projects. While CEO Atul Rane asserted in February 2023 that sanctions would not impede the partnership for at least 15 years, independent analyses highlight potential long-term erosion if prioritizes domestic needs amid isolation. The program's non-export policy for hypersonic variants, as stated by officials, further ties India's to Moscow's approval, limiting diversification options under constraints. To mitigate these dependencies, has pursued indigenous scramjet advancements through DRDO's (HSTDV) tests, aiming to integrate homegrown engines into BrahMos-II by 2025-2026, though full self-reliance remains years away without complete ToT from . This reliance reinforces bilateral defense ties—evident in 2025 talks to the program during high-level visits—but exposes to leverage dynamics, such as Russia's potential use of tech holdbacks in broader geopolitical negotiations. Critics from Western-aligned think tanks argue this entrenchment hinders India's self-reliance goals, prioritizing relational continuity over diversified sourcing amid evolving global alliances.

Future Developments

Projected Timelines for Operationalization

As of mid-2025, full-scale of the BrahMos-II hypersonic remains projected to begin in 2026 or 2027, following successful ground tests of its that exceeded 1,000 seconds of sustained operation in April 2025. These tests validate key elements derived from DRDO's hypersonic and Russian collaborations, including influences from the missile. However, historical delays—originally targeting tests in the early 2010s—stem from persistent challenges in achieving stable ignition and thermal management at 6-8 speeds, pushing timelines repeatedly. Operational induction into Indian Navy, Army, and Air Force platforms is forecasted for the early 2030s, contingent on completing developmental phases that include integration with existing BrahMos launchers and verification of a 1,000-1,500 km range. This aligns with India's broader hypersonic cruise missile (HCM) program, which DRDO aims to finalize by 2030 amid regional threats from China and Pakistan. BrahMos Aerospace officials have indicated that once joint India-Russia development accelerates, the missile could achieve readiness within six years of project formalization, though geopolitical factors like sanctions on Russian components introduce risks of further postponement. Skepticism persists among analysts regarding these projections, given past overoptimism in hypersonic programs; for instance, similar Russian efforts like faced iterative delays despite earlier claims. Full operationalization will require not only successful trials but also production scaling, with initial focus on naval variants for anti-ship roles before land and air adaptations.

Enhancements and Self-Reliance Efforts

The BrahMos-II hypersonic cruise missile program emphasizes indigenous propulsion advancements led by India's (DRDO), with the missile slated to integrate a engine fully developed domestically. This technology stems from DRDO's (HSTDV) efforts, which have validated air-breathing through repeated tests, including successful scramjet-powered demonstrations achieving 6 speeds. BrahMos Aerospace, the joint venture entity, has progressively elevated indigenous content across the BrahMos lineage to align with national self-reliance goals, reaching 65–85% localization of components by 2025 through in-house manufacturing of critical subsystems like boosters, ramjet engines, and airframes. Key milestones include the January 2023 flight test of a BrahMos variant with an entirely indigenous booster stage, paving the way for scalable production and technology maturation applicable to hypersonic successors such as BrahMos-II. These enhancements reduce reliance on imported and seeker technologies, formerly sourced from partners, while fostering domestic supply chains for composites, fuels, and guidance systems. DRDO's parallel hypersonic initiatives, including 12 distinct prototypes under , further bolster the , enabling BrahMos-II to achieve projected ranges exceeding 1,000 km at 7–8 without compromising on maneuverability or precision.

Potential Exports and International Collaborations

The development of BrahMos-II, a hypersonic scramjet-powered missile, has been pursued exclusively through the India-Russia joint venture under BrahMos Aerospace Private Limited, established via an inter-governmental agreement on February 12, 1998, between India's DRDO and Russia's . This bilateral collaboration integrates Russian propulsion expertise with Indian advancements in electronics, seekers, and guidance systems, aiming for speeds exceeding Mach 6 and ranges potentially over 1,000 km, though export controls have influenced design choices like speed limitations to Mach 6 for compliance purposes. Export potential for BrahMos-II remains limited due to its classification as advanced hypersonic technology, subject to stringent (MTCR) guidelines, to which adheres as a plenary member since 2016. Sudhir Kumar Mishra, CEO and Managing Director of , explicitly stated in that BrahMos-II would not be exported and would be manufactured only for domestic use by and , prioritizing operationalization for their armed forces over commercialization. No agreements or offers to third countries have been publicly confirmed as of October 2025, contrasting with the supersonic variant's successful exports, such as the $375 million deal with the in for shore-based systems. Speculation on future export variants persists in defense analyses, suggesting adaptations with 60-70% to facilities in and for local production, potentially blending with precision components to appeal to strategic partners. However, geopolitical factors, including sanctions and MTCR sensitivities around hypersonic , constrain such prospects; no specific countries like those in or —interested in standard —have been linked to BrahMos-II inquiries. Enhanced self-reliance efforts under India's initiative may eventually enable co-production collaborations with export clients for integration onto their platforms, but these would likely exclude core hypersonic elements.

References

  1. [1]
    BRAHMOS-II
    BrahMos Aerospace has embarked on a path-breaking journey to design and develop a highly advanced, futuristic weapon system – 'BRAHMOS-II'.
  2. [2]
    India to develop BrahMos-II missile
    The BrahMos-II will quite simply be India's most technologically advanced weapon, and will be built for delivery from land, sea as well as from aircraft. View ...
  3. [3]
    BrahMos–II and Indigenous Star Missile - SP's Aviation
    May 27, 2025 · On April 25, 2025, ISRO scientists successfully conducted the ground test for a scramjet engine combustor for an unprecedented duration of over ...<|separator|>
  4. [4]
    India's BrahMos-2 Hypersonic cruise missile - Battle Tech Insider
    Hypersonic speed of BrahMos-2: The BrahMos-II is designed to fly with the speeds of Mach 7 to Mach 8 (approximately 8,600 to 9,800 km/h or 5,300 to 6,100 mph).
  5. [5]
    Hypersonic Hiccups: Challenges in BRAHMOS II Development
    Feb 27, 2024 · The missile is designed to hit its target with unparalleled accuracy, making it a formidable weapon for both strategic and tactical scenarios.
  6. [6]
    PJ-10 BrahMos - GlobalSecurity.org
    Mar 2, 2019 · President A P J Abdul Kalam said on 21 June 2007 that the time had come for BrahMos Aerospace to work on Mark-II version of BrahMos so that ...Missing: initial proposal
  7. [7]
    India, Russia to start work on BrahMos 'hypersonic' missile
    "India and Russia have today agreed to set up a joint working group (JWG) for the development of a hypersonic version of the Brahmos missile," ...Missing: II | Show results with:II
  8. [8]
    BrahMos-2 - Deagel
    The Russian-Indian intergovernmental commission on military-technical cooperation agreed on its development on September 29, 2008.Missing: announcement | Show results with:announcement
  9. [9]
    India, Russia to develop new hypersonic cruise missile
    NEW DELHI: India and Russia have agreed to develop and induct a new hypersonic version of their joint venture 290-kilometre-range BRAHMOS cruise missile by ...
  10. [10]
    India to develop BrahMos-II missile
    To be called BrahMos-II, the cruise missile will fly at screaming velocities well over six times the speed of sound on hypersonic scramjet technology. It is ...
  11. [11]
    About JV - BrahMos Aerospace
    The journey of BrahMos Joint Venture (JV) started on 12th February 1998 after the landmark signing of an Inter-Governmental Agreement (IGA) at Moscow ...
  12. [12]
    [PDF] BrahMos: 25 Years of the Joint Venture - IDSA
    May 29, 2023 · The BrahMos JV was formed in 1998 and the first successful launch of the missile took place in 2001. The missile has since been inducted ...
  13. [13]
    Hypersonic Hiccups: Challenges in BRAHMOS II Development
    ### Summary of 2009 MoU and Joint Venture History for BrahMos-II
  14. [14]
    BRAHMOS: The most sophisticated cruise missile in the world
    BRAHMOS is designed, developed, and produced jointly with Indian and Russian scientists and industries as a consortium under BrahMos Aerospace. BrahMos ...
  15. [15]
    India, Russia to develop new hypersonic cruise missile - The Hindu
    Oct 9, 2009 · India and Russia have agreed to develop and induct a new hypersonic version of their joint venture 290-kilometre-range BrahMos cruise ...
  16. [16]
    https://nationalinterest.org/blog/buzz/meet-brahmos-ii-super-hypersonic-missile-russia-and-india-may-never-build-46007
  17. [17]
    After BrahMos's Op Sindoor success, India ramps up hypersonic ...
    Jun 4, 2025 · BrahMos-II: Projected Capabilities · Speed: Estimated between Mach 6 to Mach 8 · Range: Up to 1,500 km · Engine: Scramjet propulsion · Design ...
  18. [18]
    BrahMos-II on Horizon: Russia Poised to Greenlight Hypersonic Joint Venture with India, Bolstering Edge Post-Op Sindoor Triumph - Indian Defence Research Wing
    ### Summary of BrahMos-II Hypersonic Missile: Exports, Collaborations, and Sales
  19. [19]
    Project Vishnu, BrahMos-II to power next-gen scramjet strike
    Jul 3, 2025 · Production for induction into the armed forces is expected to begin by 2030. The Hypersonic Glide Vehicle (HGV) is another major development.
  20. [20]
    India's Hypersonic Cruise Missile: A Leap Toward Global Defense ...
    Jul 18, 2025 · Despite its progress, India faces challenges in scaling hypersonic technology. Thermal management remains a hurdle, as sustained hypersonic ...
  21. [21]
    After DRDO's Scramjet Success, India to Fast Track BrahMos-II ...
    Jun 2, 2025 · The BrahMos-II project, first conceptualised by BrahMos Aerospace nearly ten years ago, encountered obstacles previously, including Russia's ...India-Russia May Finally Greenlight Long-Delayed Brahmos-II ...India-Russia BrahMos-2 Missile Project Stalls Over ToT and ...More results from defence.in
  22. [22]
    BrahMos-2: Hypersonic Dreams on Hold as India, Russia Face ...
    Jun 28, 2024 · The hypersonic future of the BrahMos cruise missile system faces a hurdle as India's BrahMos Corporation and Russia grapple with technical and financial ...
  23. [23]
    BrahMos | Missile Threat - CSIS
    The BrahMos PJ-10 is distinguished by its reported supersonic speed of between Mach 2.0-2.8, depending on the cruising altitude used. In addition to making it ...
  24. [24]
    BrahMos–II and Indigenous Star Missile - SP's Land Forces
    May 27, 2025 · The forthcoming BrahMos-II is anticipated to significantly surpass these capabilities, with expected speeds of Mach 7-8 and a range of 1,500 km.
  25. [25]
    BrahMos-II Set to Feature DRDO's Hypersonic Scramjet Engine ...
    May 17, 2025 · With over 130 tests conducted, the BrahMos system—jointly developed by DRDO and Russia's NPO Mashinostroyenia—has seen consistent improvements, ...
  26. [26]
    Hypersonic Hiccups: Challenges in BRAHMOS II Development
    Feb 27, 2024 · BRAHMOS II will be based on a hypersonic scramjet technology. · The prime purpose of such a weapon is to target deeply buried enemy nuclear ...
  27. [27]
    BrahMos II - Missile Defense Advocacy Alliance
    Sep 18, 2018 · BrahMos II is a Russian-Indian hypersonic cruise missile, designed for anti-ship and land-attack, with a 600km range and Mach 7 speed.
  28. [28]
    India and Russia Rekindle BrahMos-II Hypersonic Missile Program
    May 26, 2025 · The BrahMos-II, also known as BrahMos-2 or BrahMos Mark II, represents a quantum leap forward. Envisioned to achieve speeds of Mach 6–8 and a ...
  29. [29]
    Hypersonic Hiccups: Challenges in BRAHMOS II Development
    Feb 27, 2024 · Known as Kinzhal – meaning dagger in Russian – these missiles boast an impressive speed of Mach 10 and carry a substantial payload of 480 kg.
  30. [30]
    Features of brahmos
    Designed with a low radar signature for stealth operations. Lethal Accuracy. Delivers pinpoint accuracy and formidable destructive power.
  31. [31]
    BrahMos-II: India's Hypersonic Dagger ready to pierce the future
    May 20, 2025 · ... BrahMos Aerospace, revealed a major milestone: a 1,000-second ground test of a scramjet engine combustor, conducted on April 25, 2025. This ...
  32. [32]
    BrahMos-II Poised for Mach 7-8 Hypersonic Speed with DRDO's ...
    May 20, 2025 · On April 25, 2025, scientists successfully conducted a ground test of a scramjet engine combustor for an unprecedented duration of over 1,000 ...India-Russia May Finally Greenlight Long-Delayed Brahmos-II ...After DRDO's Scramjet Success, India to Fast Track BrahMos-II ...More results from defence.in
  33. [33]
    DRDO conducts ground test of scramjet engine for hypersonic missiles
    Jan 21, 2025 · The DRDO has successfully tested a scramjet combustor, advancing India's hypersonic missile capabilities. The test conducted by DRDL marked ...Missing: II | Show results with:II<|separator|>
  34. [34]
    The Hypersonic Challenge - SP's Naval Forces
    Feb 14, 2025 · BrahMos-II hypersonic cruise missile. India's hypersonic inventory includes the BrahMos-II, HGV-202F, the Hypersonic Technology Demonstrator ...<|separator|>
  35. [35]
    India Set To Outpace US & China In Air-Breathing Hypersonic Tech ...
    Apr 28, 2025 · The ground test is a continuation of the earlier test reported in January 2025, which lasted 120 seconds. With the successful test, the system ...
  36. [36]
    Hypersonic Weapons: Background and Issues for Congress
    Aug 27, 2025 · India has similarly collaborated with Russia on the development of BrahMos II, a Mach 7 hypersonic cruise missile. Although BrahMos II was ...
  37. [37]
    India's BrahMos Missile Enters New Era: Fleet Saturation ...
    Sep 1, 2025 · BrahMos-II: A full hypersonic (scramjet-propelled) variant ... Flight tests delayed earlier are now anticipated by 2026–27, with ...
  38. [38]
    Hypersonic BrahMos-II missile may include tech from Tsirkon missile
    Aug 2, 2022 · The hypersonic version of the BrahMos cruise missile, the BrahMos-II, will probably have the same performance characteristics as Russia's Tsirkon missile.Missing: planned full-
  39. [39]
    Thinking Hypersonic and the Future of Deterrence
    Dec 2, 2022 · The military value of hypersonic weapons is determined by their ability to strike quickly with precision from stand-off ranges while evading ...
  40. [40]
    Complex Air Defense: Countering the Hypersonic Missile Threat
    Feb 9, 2022 · Hypersonic weapons also fly at a lower altitude than ballistic missiles and, as Tom was sort of showing us in his opening remarks, that means ...
  41. [41]
    India's Hypersonic Missile: Game Changer in Asia?
    Challenges: · Technological Maturity: Further development and refinement of the technology are necessary for a deployable system. · Cost Factor: Hypersonic ...
  42. [42]
    India and Russia Poised to Revive BrahMos-2K Hypersonic Missile ...
    Jul 26, 2025 · The BrahMos-2K is likely to be developed in two stages: a near-hypersonic variant by 2026, using an advanced ramjet engine to achieve speeds ...
  43. [43]
    China Set to Arm Pakistan With DF-17 Hypersonic Missiles in ...
    Jun 13, 2025 · Pakistan is reported to be in early-stage negotiations with China to acquire advanced hypersonic missile technology, specifically the DF-17 system.
  44. [44]
    Hypersonic Arms in South Asia: Racing Toward Instability?
    Jul 23, 2025 · Even with potential acquisitions like the Chinese HQ-19 missile defense system, Pakistan's capacity to neutralize fast, low-flying missiles ...
  45. [45]
    Defence Uncut | Pakistan Has a Serious BrahMos Problem - Quwa
    Jun 7, 2025 · Overall, the BrahMos grants India significant operational flexibility, allowing for stand-off strikes against critical infrastructure, including ...
  46. [46]
    What is BrahMos Missile? Check Speed, Range, and Origin Country
    May 11, 2025 · Hypersonic BrahMos-II variant with speeds in excess of Mach 8 and ranges up to 1,500 km. BrahMos-NG, reduced-sized and weight missile with ...<|separator|>
  47. [47]
    BrahMos Missile, Range, Speed, Significance, Versions
    Oct 15, 2025 · BrahMos-II, also known as BrahMos Mark II, is a hypersonic cruise missile (HCM). It will be used as a ship-based HCM to increase the offensive ...
  48. [48]
    Hypersonic Weapons - Joint Air Power Competence Centre
    'Hypersonic systems provide advantages in terms of speed to target, manoeuvrability and survivability to reach hardened and well-defended targets.'26 The ...
  49. [49]
    U.S. Hypersonic Weapons and Alternatives
    Jan 31, 2023 · Hypersonic weapons could be better than ballistic missiles at penetrating long-range missile defenses that operate outside the ...
  50. [50]
    Hypersonic Capabilities: A Journey from Almighty Threat to ...
    Hypersonic weapons promise to combine benefits of fast effect delivery and high survivability against modern air and missile defense (AMD) systems. In the past ...
  51. [51]
    BrahMos Missile System: The World's Fastest Supersonic Cruise ...
    Technical Specifications ; Speed, Mach 2.8 to 3.0 (approx. 3700 km/h) ; Range, 290 km (original), now up to 450–800 km ; Weight, ~3,000 kg (land/ship version).<|separator|>
  52. [52]
    A vision for US hypersonic weapons - Atlantic Council
    Aug 19, 2025 · Hypersonic weapons are more likely to penetrate enemy defenses optimized for slower munitions, meaning missile salvos can comprise fewer ...
  53. [53]
    What's next after BrahMos? India may be developing world's fastest ...
    May 16, 2025 · While testing was initially planned for 2020, development delays have pushed the timeline forward. According to media reports, the BrahMos-II ...<|control11|><|separator|>
  54. [54]
    India-Russia May Finally Greenlight Long-Delayed Brahmos-II ...
    Aug 9, 2025 · This will be followed by a true hypersonic variant equipped with a scramjet engine, with a target completion date of 2027. Once operational, the ...After DRDO's Scramjet Success, India to Fast Track BrahMos-II ...India-Russia BrahMos-2 Missile Project Stalls Over ToT and ...More results from defence.in
  55. [55]
    India's Hypersonic Missile Program and Ballistic Missile Defense
    Jul 29, 2025 · The BrahMos-II, with its projected Mach 8 capability, will significantly enhance India's anti-ship and land-attack capabilities, as reported ...
  56. [56]
    India Puts Hypersonic BrahMos-2K Program on Hold, Focuses on ...
    Nov 19, 2024 · The ambitious BrahMos-2K hypersonic missile program has been shelved for the time being due to high costs associated with its development.
  57. [57]
    Hypersonic BrahMos-II To Stealth Fighters: What To Expect From ...
    Jul 15, 2025 · The aircraft will feature supercruise capabilities, internal weapons bays, and stealth geometry. Serial production could begin around 2032 ...
  58. [58]
    https://www.jhuapl.edu/Content/techdigest/pdf/V35-N04/35-04-Van%20Wie.pdf
  59. [59]
    [PDF] Exploring the Challenges Faced in Developing Hypersonic Flight
    This paper explores the primary challenges hindering the development of hypersonic technology, focusing on thermal management, propulsion systems, and ...
  60. [60]
    India's new hypersonic relies on Russian tech - Asia Times
    Aug 4, 2022 · BrahMos II is jointly developed by India's Defense and Research Development Organization (DRDO) and Russia's NPO Mashinostroyeniya, and is the ...
  61. [61]
    Guns and Oil: Continuity and Change in Russia-India Relations - CSIS
    Aug 22, 2025 · Financial sanctions imposed on Russia in 2014, and heightened in 2022, made paying for Russian arms more difficult. At the same time, the ...
  62. [62]
    300 BrahMos Missiles to Arm Entire Fleet by 2030, Redefining Indo ...
    Aug 29, 2025 · India is arming its entire naval fleet with BrahMos supersonic cruise missiles by 2030 in a game-changing move to dominate the Indo-Pacific.
  63. [63]
    brahmos: Western sanctions will not disrupt India-Russia defence ...
    Feb 8, 2023 · The India-Russia defence partnership will "never" be disrupted by the Western sanctions on Moscow, BrahMos Aerospace chief said on Wednesday.
  64. [64]
    BrahMos CEO says Western sanctions did not affect missile production
    Atul Rane emphasized that he didn't see any problems with the production of BrahMos missiles in the next 15 years.<|separator|>
  65. [65]
    The Hypersonic Potential of India-Russia Military-Technical ...
    Aug 31, 2022 · The CEO stated that the BrahMos-II shall not be exported, but will be manufactured only for Russia and India. This is because being a signatory ...Missing: geopolitical | Show results with:geopolitical
  66. [66]
    Russia intends to share Zircon technologies to create BrahMos-2K ...
    Jul 28, 2025 · The BrahMos-2K, conceived as a hypersonic successor to the BrahMos supersonic missile, is expected to be based on the Russian 3M22 Zircon cruise ...
  67. [67]
    BrahMos-II Is Expected To Incorporate Design Cues And ...
    Jun 2, 2025 · The BrahMos-II is expected to incorporate design cues and possibly technology from Russia's 3M22 Zircon hypersonic missile.
  68. [68]
    BrahMos-2 Revival Marks Strategic Shift - Major Kalshi Classes
    May 26, 2025 · India and Russia are igniting plans to co-develop the BrahMos-2,a hypersonic missile set to redefine next-gen warfare.<|separator|>
  69. [69]
    India and Russia Jointly Developing Hypersonic BrahMos Variant
    Jul 19, 2025 · This new version, informally called BrahMos-II, will combine high-end technologies from both India and Russia. He added that once all the ...
  70. [70]
    BrahMos to launch new plant in late 2025 - early 2026
    Dec 18, 2024 · "The prospect for a hypersonic BrahMos variant is there. However, it maybe some years away as we are currently focused on the next-generation ...
  71. [71]
    BrahMos Missile Featuring Indigenous Booster Successfully Flight ...
    Today's successful launch has paved the way for the serial production of the indigenous booster and other indigenous components of the powerful BRAHMOS Weapon ...
  72. [72]
    https://www.eurasiantimes.com/indias-800-km-brahmos-high-supersonic-cruise-missile/
  73. [73]
    Hypersonic missiles, next-gen BrahMos, new air defence: DRDO ...
    Jun 20, 2025 · To increase deployment flexibility, DRDO is working on BrahMos-NG, a next-generation variant designed to fit into more fighter platforms.
  74. [74]
    BrahMos Aerospace
    ... Update 2025, along with Hon'ble UP CM · Defence Minister virtually inaugurated BrahMos Integration & Testing Facility. UP CM attended the in... BrahMos CEO ...
  75. [75]
    BrahMos signs contract with Philippines for export of Shore Based ...
    BrahMos signs contract with Philippines for export of Shore Based Anti-Ship Missile System ... BRAHMOS-II. BRAHMOS. Browse. Home · About Us · Annual Return ...