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Capability Analysis

The Chinese Navy’s Marine Corps, Part 1: Expansion and Reorganization

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This article originally featured on the Jamestown Foundation’s Chief Brief. Read it in its original form here

By Dennis J. Blasko and Roderick Lee

Editor’s Note: This is the first part of a two-part article discussing organizational reforms and evolving missions for the PLA Navy (PLAN) Marine Corps. The first part focuses on the growing order of battle for the PLAN Marines. The second part, which will appear will focus on the creation of a service headquarters for the PLAN Marines, and their expanding training for expeditionary warfare and other missions. Taken as a whole, this two-part article provides significant new information and analysis to update the December 3, 2010 China Brief article titled “China’s Marines: Less is More.

Introduction

On August 16, 2018, the Department of Defense Annual Report to Congress: Military and Security Developments Involving the People’s Republic of China 2018, reported that “One of the most significant PLAN structural changes in 2017 was the expansion of the PLAN Marine Corps (PLANMC).” The PLA Marine Corps (中国人民解放军海军陆战队) has historically been limited in terms of personnel, geography, and mission—with a primary service focus on amphibious assault, and the defense of outposts in the South China Sea. However, under currently estimated plans for service expansion, “by 2020, the PLANMC will consist of 7 brigades, may have more than 30,000 personnel, and will expand its mission to include expeditionary operations on foreign soil.”1

The expansion of the PLANMC, which commenced in April 2017, is an important element of reforms to the PLA’s operational forces. For the past two decades, the Marine Corps consisted of only two brigades, the 1st and 164th Marine Brigades (each estimated to number from 5,000 – 6,000 personnel) assigned to the South Sea Fleet stationed in Zhanjiang, Guangdong. After recent reforms, the number of brigades now amounts to a total of eight, with four new Marine combined arms brigades, a Special Operations Forces (SOF) brigade, and the core of a shipborne aviation (helicopter) brigade added to the previously existing two brigades. The four new combined arms brigades were formed out of units transferred from the Army, while the SOF and helicopter brigades were created from standing Navy units. A corps-level headquarters for the Marine Corps also has been identified. Though the Chinese government has not officially explained these developments, this new structure probably amounts to a total of up to approximately 40,000 personnel distributed among eight brigades at full strength.

The expanded Marine Corps, supported by Navy long-range sealift, likely will become the core of the PLA’s future expeditionary force. Training that began in 2014 further indicates that the eventual objective for the Marine Corps is to be capable of conducting operations in many types of terrain and climates – ranging beyond the PLANMC’s former, and continuing, focus on islands and reefs in the South China Sea. The manner by which the force has expanded, however, suggests that the PLA leadership was not motivated by an immediate need for a larger amphibious capability; rather, it appears to be consistent with several new missions undertaken by the Chinese military over the past decade that have provided impetus for the addition of new Marine units. It will likely take several years for all of the Marine Corps’ new units to reach full operational readiness as measured by personnel, equipment, and training.

Expanded Order of Battle

After “below the neck” reforms and restructuring implemented throughout PLA in 2017, Marine units are now found along China’s eastern seaboard from Shandong in the north, to Fujian and Guangdong in the east opposite Taiwan, to Hainan in the South China Sea. In northern Shandong, a former Army motorized infantry brigade of the old 26th Group Army has been transformed into a new Marine brigade (Jiefangjun Bao Online, September 30 2017). On Shandong’s southern coast, a second new brigade has been formed from what likely was a former Army coastal defense regiment located near Qingdao (Qingdao Television, February 12 2018). Further south, an Army coastal defense division stationed around Jinjiang, Fujian was the basis for a third new brigade that remains in that same locale; and may also have provided manpower and resources for a fourth new brigade that recently moved to Jieyang in eastern Guangdong province  (Anxi, Fujian Government website, August 1 2017; Jieyang News, August 17 2018). Although the PLA has not widely publicized either the creation of these new brigades or their true unit designators, the emergence of photos and new military unit cover designators associated with the Marine brigades both suggest a 1st through 6th brigade numbering scheme.2

As the new Marine brigades are being organized and equipped for their new missions, the two previously existing brigades also appear to have been reorganized. Most significantly, to streamline their chain of command, the former amphibious armored regiment headquarters appear to have been eliminated: command is now passed directly from brigade level to the newly established combined arms battalions (similar to the Army’s brigade command structure). Marine combined arms battalions are distinguished between amphibious mechanized and light mechanized combined arms battalions. Some, if not all, Marine brigades also have, or will likely have, units trained for air assault operations (Jiefangjun Bao Online, December 10 2017), and will be reinforced by operational support battalions.3

It is likely that in coming years older equipment will be retired and all Marine units will be issued new amphibious vehicles—such as the tracked ZBD05 Infantry Fighting Vehicle (IFV), tracked ZTD05 Assault Vehicle, PLZ07 122mm Self-Propelled Howitzer, the eight-wheeled ZBL09 IFV, the eight-wheeled ZTL11 assault vehicle, and the Mengshi Assault Vehicle. (The latter three vehicles have been observed deployed to the Djibouti Support Base). Some reconnaissance units are also receiving light 8×8 all-terrain-vehicles for terrain that is inaccessible to larger vehicles (Chinaso.com, April 9, 2018).

In total, the Army probably transferred over 20,000 personnel to the Navy’s new Marine units, while retaining its own amphibious capability. The Army’s two former amphibious infantry divisions—one previously stationed in the Nanjing Military Region near Hangzhou and the other in the Guangdong Military Region near Huizhou—were both transformed into two combined arms brigades each, while keeping their amphibious weapons and capabilities. A fifth former amphibious armored brigade also was converted into a new Army combined arms brigade located in Fujian. The decision to maintain these amphibious units in the Army reflects that service’s continued role in building capabilities to deter further steps toward Taiwan independence—one of the missions of foremost importance to the PLA.

Had the senior PLA leadership perceived the need to increase rapidly the Navy’s amphibious capacity, it could have decided to transfer to the Marine Corps those existing Army amphibious units, all of which were equipped and trained for assault from the sea. But by transforming a motorized infantry brigade and multiple coastal defense units—none of which were outfitted with amphibious equipment, nor trained extensively in amphibious operations—the PLA leadership understood that it would take multiple years for these units to be equipped, and even more annual training cycles before they would be fully trained to undertake amphibious operations. So, while the Marine Corps has been expanded in size, its actual amphibious capabilities will increase gradually over the next several years.

The new Marine special operations force (SOF) brigade has been formed out of the Navy’s existing SOF Regiment stationed in Hainan, which includes the Jiaolong (“Dragon”) commando unit (China Central Television, December 12 2017). The former Navy SOF Regiment’s missions and capabilities overlapped with that of the Marine Corps, and therefore their transfer is a logical evolution as the Marine Corps expands. Eventually, the new brigade will likely number approximately one thousand personnel more than the old regiment (estimated to have been about 2,000 strong). Some of those personnel may have been transferred from the 1st and 164th Marine Brigades’ structure, each of which probably included SOF elements in their former reconnaissance battalions. Of all the new Marine units within the expanded force structure, the SOF Brigade currently is the most combat ready.

The 2018 DOD report on the Chinese military also noted the creation of an independent aviation capability for the PLA Marines, stating that the expanding PLANMC “may also incorporate an aviation brigade, which could provide an organic helicopter transport and attack capability, increasing its amphibious and expeditionary warfare capabilities.”4 The new Marine Shipborne Aviation (helicopter) Brigade apparently has been built out of elements from all three PLAN independent air regiments (Weibo, January 27 2018). These regiments have been busy since 2009, provided the aircraft for 15 of 30 of the Navy’s deployments to the Gulf of Aden escort mission (PLA Daily, July 16 2018).

Currently, the new Marine helicopter unit likely has considerably less than a full contingent of aircraft compared to an Army Aviation Brigade, which when fully equipped probably consists of over 70 helicopters. The Military Balance 2018 estimates the Navy’s entire helicopter fleet at slightly over 100 aircraft, with about half being transport helicopters—while the others are anti-submarine warfare, early warning, and search and rescue aircraft needed to support the rest of the Navy’s operations.5 Heretofore the Navy apparently has experimented with only a few armed Z-9 helicopters (People’s Navy, July 31 2012). Until additional attack helicopters are added to the force, as a stop gap measure it would be possible for the Army to temporarily assign a few of its attack helicopters to the Marines to assist in training and doctrine development for amphibious operations. Thus, it is likely that it will take several more years to add additional transport and attack helicopters and train the pilots and crews before the new Marine helicopter brigade is at full strength and combat ready.

This article will continue in the next issue of China Brief, with “The Chinese Navy’s Marine Corps, Part 2: Chain-of-Command Reforms and Evolving Training.”

Dennis J. Blasko, Lieutenant Colonel, U.S. Army (Retired), was an army attaché in Beijing and in Hong Kong from 1992-1996 and is the author of The Chinese Army Today: Tradition and Transformation for the 21st Century, second edition (Routledge, 2012). 

Roderick Lee is an analyst with the United States Navy. His work focuses on Chinese maritime forces and strategy. He earned his Master of Arts degree from The George Washington University’s Elliott School of International Affairs.

The views and opinions expressed herein by the authors do not represent the policies or position of the U.S. Department of Defense or the U.S. Navy, and are the sole responsibility of the authors.

Notes

[1] U.S. Department of Defense, Annual Report to Congress: Military and Security Developments Involving the People’s Republic of China 2018, p. 28. https://media.defense.gov/2018/Aug/16/2001955282/-1/-1/1/2018-CHINA-MILITARY-POWER-REPORT.PDF#page=11&zoom=auto,-85,733.

[2] Military unit cover designators (MUCDs) are serial numbers (consisting of five digits) employed by the People’s Liberation Army to identify specific military units, and are frequently employed in official communications in the place of the true unit designators. 

[3] People’s Navy, January 23, 2018 and February 9, 2018.

[4] U.S. Department of Defense, Annual Report to Congress: Military and Security Developments Involving the People’s Republic of China 2018, p. 28. https://media.defense.gov/2018/Aug/16/2001955282/-1/-1/1/2018-CHINA-MILITARY-POWER-REPORT.PDF#page=11&zoom=auto,-85,733.

[5] International Institute for Strategic Studies, The Military Balance 2018, p. 254.

Featured Image: PLAN Marine Corps command and staff personnel examine maps in the course of a cold weather training exercise in Inner Mongolia, March 2015. (Source: Xinhua)

Africa, Capability Analysis

The Gulf of Guinea is Ready for Maritime Technology

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By Dr. Ian Ralby, Dr. David Soud, and Rohini Ralby

Few regions of the world have seen more improvement in maritime security institutions over the last five years than the Gulf of Guinea. At the same time, however, maritime security threats across West and Central Africa have continued to evolve and are increasingly difficult to address. Ironically, the region is becoming a victim of its own success: improved maritime law enforcement drove criminals to become both more brazen and more innovative in how they pursue illicit profit. These heightened challenges, however, are no longer as insurmountable as even basic ones were a decade ago. Having built one of the most sophisticated and promising sets of maritime security architecture in the world, the Gulf of Guinea is actually well-placed to take on the new challenges it faces.

To maximize the efficiency and effectiveness of this architecture in confronting these threats, a new element has to enter the conversation: technology. States, zones, regions, and the wider interregional mechanisms must all explore ways of leveraging technology to realize their respective mandates in the most cost effective way. Five years ago, discussing maritime technology would have been of limited value, as the state and cooperative mechanisms across West and Central Africa were too nascent to take advantage of it. Now, however, the Gulf of Guinea is primed to make better use of maritime security technology. 

The Gulf of Guinea Has Momentum

While progress in developing functional maritime security in the Gulf of Guinea may not have been as fast as some would prefer, it is now moving rapidly, and its trajectory is unmistakable. The signing of the 2013 Code of Conduct Concerning the Repression of Piracy, Armed Robbery against Ships, and Illicit Maritime Activity in West and Central Africa – known informally as the Yaoundé Code of Conduct – catalyzed an intensive process of national, zonal, regional, and interregional improvement that continues to gain momentum. As Article 2 of the Code states, “the Signatories intend to co-operate to the fullest possible extent in the repression of transnational organized crime in the maritime domain, maritime terrorism, IUU fishing, and other illegal activities at sea.” This initiative has given rise to a multi-tiered effort.

The Gulf of Guinea (Osservatorio Strategico 2017 – Year XIX issue IV)

At the national level, states are working to establish interagency processes for maritime governance, and to develop and implement national maritime strategies. States will remain the fundamental building blocks of maritime security in the Gulf of Guinea. Only through the national laws of the regional states can maritime crimes be effectively prosecuted. Beyond these national efforts, however, the states are engaging in an increasingly integrated, multilateral architecture that facilitates seamless cooperation.

The states, including the landlocked signatories to the Yaoundé Code of Conduct, are grouped by their respective Regional Economic Communities (REC) into maritime Zones. The Economic Community for Central African States (ECCAS) has Zones A and D (there is neither a B nor a C) and the Economic Community for Western African States (ECOWAS) has Zones E, F, and G. The national groupings are as follows, with an asterisk indicating each country that hosts a Zonal Multinational Coordination Center (MCC):

  • Zone A: Angola, Democratic Republic of Congo, Congo
  • Zone D: Cameroon*, Equatorial Guinea, Gabon, São Tomé and Príncipe
  • Zone E: Nigeria, Benin*, Togo, Niger
  • Zone F: Ghana*, Côte d’Ivoire, Burkina Faso, Sierra Leone, Liberia, Guinea
  • Zone G: Cabo Verde*, Senegal, the Gambia, Guinea Bissau, Mali

Each REC also has a corresponding Regional Coordination Center – CRESMAC for ECCAS based in Pointe Noir, Congo, and CRESMAO for ECOWAS based in Abidjan, Côte d’Ivoire. The two regional centers interact and share information with the MCCs to ensure operational cooperation across their respective areas of responsibility.

At the apex of the architecture is the Inter-regional Coordination Center (CIC) in Yaoundé – the intersection of the operational, strategic, and political aspects of maritime safety and security in the Gulf of Guinea. CIC both coordinates and supports the work of the two regional centers, the five zones, and the 25 member states. At the same time, it has the important role of engaging both with international partners and national governments to build political will and ensure the Gulf of Guinea’s momentum continues.

Importantly, the Yaoundé Architecture for Maritime Safety and Security (YAMSS), as the institutional framework is often called, is not merely a nice idea on paper; it is increasingly producing real results on the water. Furthermore, the community of maritime professionals involved in implementing this architectural design are increasingly connected with each other and working collectively to make maritime safety and security a reality in the Gulf of Guinea. As perhaps the most notable example, Zone D already serves as a leading example of how to conduct systematic combined operations at sea for maritime security, not just in Africa but around the world. CRESMAC and CRESMAO are becoming increasingly operational in sharing information across their regions and with each other. And CIC is beginning to garner the attention needed to be successful. At every level, there are encouraging signs of growing momentum and increased community among the maritime professionals in West and Central Africa.

Most technology for maritime law enforcement is procured at the national level. Given the extent of the integration within the Yaoundé architecture, however, there is also an opportunity for technology to be procured at the zonal, regional or inter-regional levels to ensure harmonization, to streamline access to common, inherently interoperable systems and provide a uniform operating picture. 

Technology, some procured within the Gulf of Guinea and some provided by international partners, has been a part of this process from the start. Most of it has involved enhancing visibility to improve maritime domain awareness (MDA). But with the growing coordination across states and regions, and the problem-solving and advance thinking that expansion has generated, key stakeholders have crossed a threshold: they can now discern with confidence what technologies will actually help maximize the impact of maritime operations. The lessons learned along the way merit careful attention from anyone seeking to leverage technology for improved maritime security. What follows are some of those insights.1

Avoiding Information Overload 

Improving MDA has been a major focus for years in Africa. But there is a balance to strike: being aware of everything is almost as challenging as being aware of nothing. Efficiency and effectiveness therefore begin with how information is selected and packaged for use on and off the water. Operators from across different maritime agencies share a keen interest in technology that highlights useful, actionable information, and not only collects but also filters input, helping them focus on key areas of concern rather than providing blanket visibility of all maritime activity. Given the region’s limited human as well as financial resources, such technology could guide them toward confidently engaging in targeted interdiction. This holds true for maritime criminal activity as well as fisheries protection.

But to be used consistently and effectively, the technology must be user-friendly as well. Simplicity is an important differentiator between technology that would improve general maritime domain awareness and technology that would actually help operations in law enforcement, fisheries protection, or search and rescue. For instance, artificial intelligence has now made it possible to have an MDA platform that not only shows ship positions and makes recent AIS anomalies visible, but also aggregates a wide range of real-time and historic data and filters them according to selected parameters, providing instant alerts to suspected illegal activity. That array of functions would allow for both launching decisive interdictions and detecting patterns of illicit activity.

Technology Can Facilitate Inter-Regional Harmonization 

When any one state or even zone is perceived to be weaker than its neighbors, in terms of either its laws or its capacity for law enforcement, that state or zone becomes a magnet for criminality. Consequently, a major focus of the YAMSS is on harmonization to ensure consistency in deterring and addressing maritime crime throughout the Gulf of Guinea. Depending on how it is chosen, distributed and applied, technology could either exacerbate the problem or help resolve it.

When one state has a significant technological advantage over its neighbors, the neighboring states are likely to suffer. Conversely, when shared technologies are deployed across neighboring zones and regions, new possibilities arise for communication, coordination, interoperability, and even harmonization of legal and regulatory frameworks. Some technologies, for example, could provide insight across the region as to where IUU fishing and illicit transshipment most frequently occur, or call attention to ships on erratic or otherwise suspicious courses. This could in turn inform legislative or regulatory action as well as operational decision-making at the national or zonal levels to help address maritime problems where they are most acute. Such an approach can therefore help CIC with building the political will to harmonize, as well as help the operators in their planning and execution of law enforcement activities. The more seamlessly technology is deployed across a region, the more difficult it becomes for criminals to find venues for illicit activity. As the name suggests, transnational crime is borderless; a common operating picture across the regions is therefore vital to identifying that illicit activity.

Not only have the maritime institutions evolved in recent years, the available maritime technology has developed greatly. Surveillance systems to identify illicit activity on the water – from illegal fishing to illicit transshipment to trafficking and smuggling – have improved dramatically. Employing this technology means that operators are not merely patrolling on the off chance they encounter illicit activity. The confidence of law enforcement agencies that they will not be wasting fuel and other resources is greatly enhanced by engaging in targeted interdiction of vessels reasonably certain to be committing offenses based on real-time information.

If law enforcement agencies can show that their efficiency is such that they have successful interdictions nearly every time they deploy assets, that success can become contagious. It can help energize the maritime agencies, deter criminal actors, and at the same time build the political will to ensure the longer-term safety and security of the maritime domain. Politicians are persuaded by success, and technology can greatly increase the odds of operational success.

Culprits Do Not Have to be Caught Red-Handed

In addition to facilitating targeted interdiction, advanced surveillance technologies can offer a further benefit. Just as a robber could be arrested at home for a heist caught on closed caption television (CCTV), it is now possible for vessels to be arrested in port for illicit actions committed at sea and recorded using sophisticated maritime surveillance platforms. Though CCTV is not a possibility on the water, other technologies including the use of the vessels’ Automated Information System (AIS), Synthetic Aperture Radar (SAR), and Electro Optical Imaging (EO) can produce high degrees of certainty regarding illicit activity. While states must ensure that their rules of evidence allow for such electronic and digital data to be used in court, this leveraging of historic surveillance data is another way the technology available today can greatly amplify the impact of limited maritime law enforcement resources. 

Technology that helps counter smuggling will inherently benefit two states simultaneously – the state that is losing the smuggled good, and the state that is losing the tax on the importation of that smuggled product. If implemented effectively, technology could disincentivize the smuggling of certain goods. One crucial example of this is fuel: the cost of doing business in illicit fuel could, with effective law enforcement, become higher than that of selling it legally, thereby making it an unattractive business proposition. A suite of technologies such as molecular marking, GPS tracking of shipments, digital documentation, and state-of-the-art metering, strategically implemented across the Gulf of Guinea, would alter the risk-reward calculus and help West and Central Africa eradicate most cross-border smuggling of fuel. These and related technologies could also appreciably mitigate other modalities of illicit trade, including counterfeit tobacco and pharmaceuticals.

Technology that Pays for Itself Sells Itself

For states and multinational bodies working to secure and govern vast maritime spaces that seldom command the political attention they deserve, investments in technology have to bring returns that justify initial and ongoing expenditure. Technologies that enable more streamlined and cost-effective operations, that combat activities that lead to substantial economic losses, or that actively generate revenue in the form of taxes, fees or various kinds of penalties are preferable to those that run at ongoing cost.

Countering IUU fishing, prosecuting environmental crimes, and combating fuel smuggling are three efforts that could hold precisely this kind of appeal. Acquiring new technology that can stem economic losses from depleted fisheries and degraded marine spaces, elicit substantial financial penalties for illegal fishing or environmental, dumping, recover revenues previously lost to fuel smuggling or prevent subsidies fraud may well find more support among decision-makers than procuring more patrol vessels that need to be crewed, fueled, and maintained. And when the technology begins to pay for itself and lead to more success on the water, investing in new patrol vessels that can amplify that success also begins to look more attractive.

If the political classes can see financial return on investment as well as improved maritime safety, security, and sustainability, wider adoption of the technology becomes more likely. Furthermore, if the procurement approach does not put all the economic burden on the purchaser, but rather balances investment and return, the Gulf of Guinea states are more likely to proceed.

Maritime Safety, Security and Resource Protection Can Share Technology 

The Gulf of Guinea Code of Conduct not only laid the groundwork for an inter-regional security architecture, it also established IUU fishing as a crime coequal with piracy, trafficking, oil theft, and other illicit activities. This move made it possible to establish far more effective legal deterrents than the administrative penalties that often accompany fisheries-related crimes. It also allows for more sharing of technology and information across agencies that combat the full range of illicit maritime activities. In light of how such criminal enterprises as IUU fishing, trafficking, and oil theft often overlap, sharing technology in this fashion can close gaps in law enforcement that criminals have all too often exploited.

Given that limited resources become even more limited when they are divided among multiple agencies trying to accomplish similar tasks, this sort of integration could have an immediate impact on maritime safety, fisheries protection and maritime security. Such sharing of resources, however, necessitates a functional interagency mechanism for maritime governance. Thus the state-level work on both whole-of-government approaches to maritime security and integrated maritime strategy development and implementation go hand-in-hand with the prospects for effective use of such technology. 

Technology Can Both Help and Complicate Legal Finish 

One of the most difficult challenges for the Gulf of Guinea, and indeed for any region, is translating operational successes into legal finish. If no prosecutorial or regulatory action is taken to penalize illicit activity, maritime law enforcement becomes a matter of catch and release. Technology can play an important role in assisting with maritime interdiction, but it also has an essential role to play in effectuating legal finish.

That said, a challenge must first be overcome. Not all legal systems have provisions for technological, digital, or electronic evidence. In order to be able to use the evidence provided by the MDA and monitoring, control, and surveillance (MCS) technologies now emerging, the state’s evidentiary rules must be amended to ensure that technology can be used in court. If those evidentiary rules are more permissive, however, there is another possibility for assisting law enforcement.

Traditionally, in the maritime space, perpetrators have to be caught in the act. But, as noted above, technology that provides evidence of illicit activity at sea could potentially be used to arrest vessels at the pier and on their return from a voyage that involved a breach of the law. In other words, limited vessels or a lack of fuel would not be a barrier to arrest and prosecution. Furthermore, regardless of where a vessel was caught, historical data could be used to increase the charges and penalties for prior offenses as indicated by the technology.

Conclusion 

The Gulf of Guinea is ready to more effectively use technology to enhance the work done to develop and operationalize the cooperative maritime security architecture in West and Central Africa. Cost-neutral or even revenue generating technology is most likely to garner the necessary political will, but from an operator’s standpoint, simplicity is also key. In addition to aiding targeted interdiction, technology can help provide the evidence for pier-side arrests and even enhance charges and penalties based on prior illicit activity. That said, legal systems must account for such technological evidence in court. Harmonized legal finish across the Gulf of Guinea must be a central focus, as that is the only way to change the risk-reward calculus and ensure that no state or zone becomes a magnet for crime.

In a larger, more strategic sense, the individual states and regional bodies pursuing greater maritime security and development in the Gulf of Guinea must also work together to harmonize their more foundational approaches to the challenges facing the region. Too often stakeholders presented with the chance to cooperate or collaborate in confronting such issues fall into the trap of viewing that effort in terms of false dichotomies. They may rightly be keen to exercise autonomy in light of a history in which their sovereignty has been compromised. But they may also unhelpfully misinterpret the cooperative and collaborative harmonization of approaches as being a threat to sovereignty. In an effort to maintain their autonomy, they may therefore isolate themselves, and consequently become more of a magnet to the highly cooperative, transnational criminals they face.

Exercising autonomy Losing sovereignty
Isolating Cooperating and collaborating

This diagram reveals how the terms of a dichotomy are never simply binary, but actually part of a cluster of related terms that are often conflated, or defined in varying ways.2 Failing to get outside the “box” formed by these choices can narrow vision and obstruct communication, and thus frustrate efforts at progress. The stakeholders in the Gulf of Guinea must clarify for themselves and each other the difference between exercising autonomy and isolating themselves, and between cooperating or collaborating and losing sovereignty. If everyone can achieve this “outside-the-box” clarity, progress can happen quickly and effectively. While many of the maritime operators recognize these nuanced dynamics, they have a challenge to overcome in convincing their political leadership to move past a limiting dichotomy centered on autonomy, and instead embrace cooperation and recognize the value in sharing resources and technology to secure, govern, and develop the maritime space in the Gulf of Guinea.

The work of maritime professionals in West and Central Africa to pursue safety, security, and sustainability in the maritime domain has already led to some notable successes. Now it is in a position to begin realizing the ambitious vision of successfully securing, governing, and developing the region’s maritime domain. This is where new, better, and more effectively used technology can play a pivotal role by enabling individual states and regional bodies to make far more effective use of their resources to control the maritime space. Stakeholders must now select the right tools for the job – those that provide the necessary precision, simplicity of use, cost-effectiveness, and ability to link efforts across both agencies and maritime boundaries.

Ian Ralby is a recognized expert in maritime law and security, serving as Adjunct Professor of Maritime Law and Security at the US Department of Defense’s Africa Center for Strategic Studies; a Maritime Crime Expert for UNODC; and as CEO of I.R. Consilium, a family business that works matters of security, governance and development.

David Soud is Head of Research and Analysis at I.R. Consilium and works on issues at the intersection of fisheries governance and transnational organized crime.

Rohini Ralby is Managing Director of I.R. Consilium and works on strategy development and implementation.

References

1. A recent public-private conference organized by the US firm I.R. Consilium, LLC in Freetown, Sierra Leone explored this topic and served as the basis for the key points of this article.

2. The diagram is an example of the “fourchotomy,” a strategic tool devised by Rohini Ralby.

Featured Image:  GULF OF GUINEA (April 2, 2014) A U.S. Coast Guard law enforcement detachment member and a Ghanaian navy sailor inspect a fishing vessel suspected of illegal fishing during the Africa Maritime Law Enforcement Partnership. The partnership is the operational phase of Africa Partnership Station and brings together U.S. Navy, U.S. Coast Guard, and respective Africa partner maritime forces to actively patrol that partner’s territorial waters and economic exclusion zone with the goal of intercepting vessels that may have been involved in illicit activity. (U.S. Navy photo by Kwabena Akuamoah-Boateng/Released)

Capability Analysis

Breaking the Mold: How to Build a 355-Ship Navy Today, Pt. 1

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“It shall be the policy of the United States to have available, as soon as practicable, not fewer than 355 battle force ships.”

-Section 1025, Para (A) of the National Defense Authorization Act for FY2018 (FY18 NDAA)

“Battle force ships are commissioned United States Ship (USS) warships capable of contributing to combat operations, or a United States Naval Ship that contributes directly to Navy warfighting or support missions, and shall be maintained in the Naval Vessel Register” –SECNAVINST 5030.8C

By Keith Patton

During the Reagan administration, it was the policy goal of the United States to build a 600-ship Navy. That goal came very close to being realized, but the end of the Cold War and the “peace dividend” resulted in a rapid contraction of U.S. battle force ship count. This is not to say the U.S. Navy became less powerful since current U.S. multi-mission destroyers are far more capable than their 80s predecessors, but the fleet can be in far fewer places at once and is less casualty tolerant.

In 2015, the Navy’s force level goal was 308 ships. In 2016, this was raised to 355. This policy goal was codified by Congress in the FY18 NDAA. Currently, the Navy has 286 battle force ships, or only 80 percent of its own and now the Congressionally stated requirement. Pursuant to FY18 NDAA, the Navy produced a report to Congress with a plan for achieving a 355-ship force level after 2050, but included options to achieve this level by 2030.

What if world circumstances or political decisions forced the U.S. to look at achieving a 355-ship Navy far sooner than in 11 to 30 years? Possibilities range from how to stretch or improve what already exists, to more radical notions of foreign warship procurement, armed merchantmen, and development of a U.S. Navy foreign legion type force.

Assumptions

Some of the current and proposed policies for fleet building are built on numerous assumptions. One, that a 355-ship Navy is necessary. This is codified in the FY18 NDAA, but some the forthcoming ideas will stretch the definition or purpose of a 355-ship Navy. Second, that the Navy is in a technological competition and simply adding hulls to the battle force count is insufficient. These hulls must be capable of adapting to emerging technology rather than simply using what is available today. However, some of the offered ideas focus on using current or less capable designs to reach 355 ships. Third, that it is feasible for the Navy to fund a commensurate increase in personnel and weapons procurement. This is also impacted by the type of ships procured. This assumption is not directly challenged, but is fundamental to manning and arming the fleet constructed. Finally, that the political will exists to champion these changes, which could threaten established programs, industrial bases, or voting blocks.

Stretching What We Have

The Department of Transportation’s Maritime Administration has already been told by the Navy that, in the event of a major conflict, there will be insufficient ships to escort a sealift effort to Asia or Europe. Recalling Operation Drumbeat, or the “happy times” of the German U-boat force off the U.S. Atlantic coast in 1942, this is very concerning. 23 merchants were sunk off the U.S. coast by just five Type IX U-boats. For perspective, that is equivalent to 40 percent of the current ship inventory of the Maritime Administration’s Ready Reserve Fleet, which is tasked with transporting U.S. forces in wartime. During U-boat operations, 22 percent of the tanker fleet was sunk, and 232 ships total in seven months. This is more than the entire U.S. merchant marine fleet today. Raising the U.S. battle force ship strength to provide escorts for vital transport and logistics vessels would seem a logical first step.

A quick way to preserve and grow battle force ships is to stop decommissioning vessels and to execute service life extensions on them instead. These would include younger Los Angeles-class SSNs and DDGs. The FY18 NDAA already prohibits the Navy from retiring Avenger-class MCM (Sec 1046). By extending the life of Arleigh Burke-class destroyers to 45 or 50 years, the Navy can reach its desired large surface combatant end strength by 2029. However, this is still 10 years away. Even with extending the lives of Los Angeles-class SSNs, the Navy does not reach its desired attack submarine count until after 2048. Stopping the bleeding is not sufficient to reach 355 in less than a few decades,if the Navy needs to find more hulls in the next few years.

The Navy also could draw upon a limited quantity of warships in Naval Inactive Ship Maintenance Facilities (NISMF) including two aircraft carriers, two cruisers, two destroyers, a score of frigates, amphibious assault ships, and auxiliaries. Appendix 6 of the Navy report to Congress on shipbuilding notes 66 battle force ships being retired, dismantled, or sunk in the next five years. Reactivating those ships would almost instantly reach the 355 vessel goal. A 355-ship fleet, therefore, might be quickly met by delaying decommissioning and returning old warships to active duty

There is a significant downside to both extending the life of existing ships and returning old ships to service. First, there is the upfront cost of nuclear refueling and updating combat systems. Some cost savings could be made, for instance not using the catapults or arresting gear of the old carriers, making them STOVL carriers for helicopters, Ospreys, and F-35Bs (and saving significant manning and maintenance costs) or not updating the combat systems of the Oliver Hazard Perry-class frigates and only using them for low-end counter-piracy or counter-narcotics missions. However, this would severely limit the combat capabilities of the ships to the battle force. They may be able to handle a low end mission and free more expensive assets for higher-threat theaters, but they would not be suitable for great power conflict. Upgrading them with modern combat systems would further increase their cost. Additionally, these old vessels were decommissioned for a reason. Taking old vessels back into service introduces assets that are less capable in modern warfare due to limited growth margins and worn out hulls, and adds significant maintenance costs to stretch their service for a few more years. Long term, this seems far less bang for the buck than procuring new, modern combatants with growth margins for emerging technology. It also violates the planning assumption that the Navy’s new hulls will need growth room for emerging technology to field new weapons and systems.

Building Smarter, Better and Faster

The Navy currently receives new warships from five large and two smaller private shipyards. The shipbuilding industry is not at capacity in the U.S. To achieve a 355-ship in a decade would require almost doubling new ship production.1 Additionally, buying more warships in a smaller interval of time drives down unit cost. The Congressional Research Service (CRS) estimated 10 percent savings by doubling the production rate of combatants.2 The same report also estimated 5-10 percent savings by using multiyear procurement. By energizing the U.S. shipbuilding industry, the 355 battle force ship count can be achieved sooner.

However, U.S. shipbuilding can only achieve a 355-ship Navy slowly. Upon funding, it takes two years for long lead time components for a SSN to be produced, and five to six years for construction. Additional workers and production space would be needed before the five to six year construction phase began. Even with immediate funding, therefore, a decade might elapse before additional warships and specifically SSNs could join the fleet.

The Government Accountability Office 2018 report on Navy Shipbuilding does not give much room for optimism on meeting shipbuilding time or costs. It notes “construction during the last 10 years have often not achieved their cost, schedule, quality, and performance goals” and that the Navy has spent more on shipbuilding but has fifty fewer ships in the inventory than was planned in its 2007 shipbuilding plan.

Another consideration is that building more of existing designs does not allow margins for growth. The DDG-51 Flight III design does not have the growth margin or electrical generation to support projected future weapons, nor crew reductions. Procuring more DDG-51s at an accelerated rate provides a short-term advantage, but leaves the Navy with a large number of hulls that consume manpower and can’t adapt efficiently as new systems are developed. Designing a new combatant takes years, and this will delay the date when the Navy can achieve a 355-ship force. Simply building existing or projected future designs faster does not offer much hope of meeting a 355-ship battle force quickly.

Another consideration is the boom and bust effect of sudden surges in shipbuilding. Even if a 355-ship Navy could be built in three to five years, what would befall the warship industry in the following years? Once the goal was reached, unless there was a new, higher goal set, shipyards would have to massively trim the workforces they hired to support a surge in construction. A stable growth plan is more economical and sustainable than one based on sudden surges and decelerations. It would also be more politically palatable to the Congress that authorized it.

Increasing the Firepower of What We Have

If ships cannot be built or brought back into service in a timely or economical way, could there be a way to increase the fleets combat ability until a 355 ship force is achieved? This is “breaking the mold” of the first assumption – that a 355-ship navy is necessary. Can a more powerful force of what we have suffice in the interim until a true 355-ship fleet can be achieved? 

The SSGN conversion of four SSBNs gave the Navy four stealthy, high-capacity, long-range, strike platforms. Each can be equipped with up to 154 cruise missiles and other payloads, more than a  cruiser, and offers far more offensive capability when one considers that many of the cruiser’s tubes are filled with defensive weaponry. What if the Navy converted the remaining 14 Ohios? This would provide an 18 percent increase in missile tubes (or firepower) available to the  battle force, when the 355 battle force count goal is a 20 percent increase in hulls. This seems to close the capability gap, for strike anyway, with what is available. The question is, would 18 Ohio SSGNs roaming the oceans provide a greater conventional deterrent, and an effective platform in worst case A2AD environments than more of other ships? For high-end warfare and strike, likely yes. But there are many missions a submarine does not do well, like air and ballistic missile defense, presence, and maritime interdiction. The SSGNs would also be a stop gap since they are aging out. To replace the Ohio SSGNs as they age out, the new Columbia-class SSBN could be repurposed as SSGN as well.

This would dramatically alter U.S. nuclear posture by removing the SSBN leg of the triad. However, this could be mitigated to an extent by the already announced plan to put nuclear-tipped Tomahawks back on U.S. submarines. As hypersonic or smaller intermediate range ballistic missiles became available, nuclear armed versions of these weapons on all the SSGN would provide a survivable nuclear response to underpin US deterrence. The Navy could also consider spreading nuclear Tomahawks or successor systems across more than just the submarine fleet. Instead of a few, high capacity SSBNs, the naval leg of the triad would become a dispersed force of ships and subs with a few weapons each, much as it was during the Cold War.

While far less survivable than a submarine, missile tubes could also be added to existing combat logistics force ships or even amphibious assault ships. The San Antonio-class LPD was originally designed with a 16-cell Mk 41 VLS forward. The Navy has considered back fitting it. However useful, the entire fleet of LPDs outfitted with VLS would yield fewer missiles than two SSGNs, and be less survivable. Another concept would be to take the San Antonio follow on and build them as missile ships with large radars and extensive VLS capability. Huntington Ingalls has produced a model of this concept, with twice the missile firepower of a U.S. cruiser. This would allow the Navy to close the firepower gap between a 355-ship Navy and now with fewer than 355 ships.

While these ideas do not produce a 355-battle force ship fleet any sooner, they do produce a fleet that is more survivable, with more firepower, sooner, than the official ship building plans call for. The cost is shifting and ceding some capability in nuclear deterrence and amphibious lift. Each of these would be controversial alone. Even together, they may be insufficient should the U.S. feel it needs a 355 battle force ship equivalent sooner rather than later.

Change in Deployment Methodology/Theater Specific Ships

While not directly increasing the battle force ship count, changing Navy deployment methodology could allow the force to be more capable as the size grows. This methodology is similar to the report published by the Center for Strategic and Budgetary Assessments as part of the Navy’s fleet architecture study. This report suggested the Navy be divided into two forces. First was a deterrence force, sub-divided among COCOMs, with the capacity to provide prompt, high capacity fires to punish an adversary should their existence fail to deter them. These ships would be tasked to support a particular COCOM rather than CONUS-based forces rotating between them. In low-threat SOUTHCOM, LCS and reactivated Oliver Hazard Perry-class frigates, Coast Guard, or newly designed ships could focus on low-end missions and free up high end warships for other theaters. In CENTCOM, the ships assigned would focus on FAC/FIAC threats and air and missile defense. Ships assigned to PACOM or EUCOM would focus on high end missions. Ships could be built, manned, and trained around these priorities, in contrast to current operations where ships focus on all warfare areas and multiple AORs, risking becoming jacks of all trades but masters of none. While this may have been adequate during a low naval threat period, with the return of great power competition, specialization may be needed again. The SSGN conversions in particular might be outstanding vessels for the deterrence force in EUCOM and PACOM. Difficult to detect and counter, and with two or three perhaps on station at any time able to bring high capacity fires against an adversary’s aggression, the could depart the theater to reload and join the maneuver force.

Theater-specific ships could also be homeported in their AOR, reducing transit time and acting as a force multiplier. CRS estimated it takes 42 additional warships to keep eight additional ones on station in the Mediterranean if home ported in CONUS.3 If homeported in the Mediterranean, only 14 warships would be required. This could reduce the need for a 355-ship force, or allow those 28 warships to be tasked to other missions.

The second part of the fleet would be a maneuver force consisting of a multiple carrier strike groups and larger amphibious vessels that would relieve and replace the deterrence force and provide sustained combat power. By keeping the multi-carrier maneuver force together and away from the immediate area of crisis, it could conduct more high-end training and not be at risk in the initial stage of conflict. This would also mesh with the enduring Mahanian desire to keep a large portion of the fleet concentrated and surge capable. This contrasts with the current deployment methodology where ships frequently shift COCOM and tasking, and carriers don’t consistently operate together as they may have to in wartime to provide 24/7 effects and protection.

All of these ideas, deterrence/maneuver force, theater-specific ships, or greatly increasing overseas homeporting, breaks the mold of U.S. deployments and acquisition. However, they fail to increase the battle force ship count. They simply hold the dream of making the existing ships more efficient, available, or capable for specific missions.

Change in Battle Force Ship Definition

Another idea would be to change SECNAVINST 5030.8C, specifically enclosures (1) and (2) to assign more vessels from the category of Auxiliary to Combatant. The combatant category, which counts toward the 355-ship goal, already includes afloat forward staging bases, cargo and ammunition vessels, expeditionary sea bases, fast transports, fleet tugs, surveillance ships, and towing and salvage vessels. Adding in oceanographic research vessels and survey ships (both similar to surveillance ships), transport oilers and aviation logistics support (both similar to combat logistics ships) and high speed transports (very similar to expeditionary fast transports) could immediately add vessels to the battle force ship count with the stroke of a pen.

Doing this, while breaking the mold in the definition of a battle force ship, seems to be going against the spirit and intent of Congressional policy and U.S. Navy desire to increase force strength. While it could be argued some of the ships listed as auxiliaries provide very similar support to ships listed as “Fleet Support” or “Expeditionary Support,” reclassifying is simply smoke and mirrors while not increasing capability. Even if weapon systems were added to these platforms to make them more plausible as “battle force ships” the increase in Navy power and capability would be far less than battle force ships as listed under current definitions.

CDR Patton is deputy chairman for the U.S. Naval War College’s Strategic and Operational Research (SORD) Department. SORD produces innovative strategic research and analysis for the U.S. Navy, the Department of Defense, and the broader national security community.  CDR Patton was commissioned in 1995 from Tufts University NROTC, with degrees in history and political science and has served four tours conducting airborne nuclear command and control missions aboard the US Navy E-6B Mercury aircraft, and two tours as Tactical Action Officer (TAO) and Combat Direction Center Officer (CDCO) aboard the carriers USS KITTY HAWK and USS NIMITZ. 

The opinions and ideas above do not necessarily represent those of the Department of Defense, U.S. Navy, or the Naval War College. The ideas expressed here do not necessarily reflect those of the principal author either. They were drawn from the Breaking the Mold II workshop held at the U.S. Naval War College with invited participants from military, industry, government and academic institutions. The workshop was held under the Chatham House Rule, so these ideas will not be attributed to their originator. Some ideas were specific enough that they are not included here because the idea itself might identify the originator and violate the Chatham House rule.

References

1. Congressional Budget Office “Costs of Building a 355-Ship Navy”, April 2017 pg.9

2. Ronald O’Rourke, “Options and Considerations for Achieving a 355-Ship Navy” July 25, 2017. Pg. 3

3. Ronald O’Rourke, “Options and Considerations for Achieving a 355-Ship Navy” July 25, 2017. Pg. 11

Featured Image: DARDANELLES STRAIT (Jan. 19, 2019) The Arleigh Burke-class guided-missile destroyer USS Donald Cook (DDG 75) transits the Dardanelles Strait, en route to the Black Sea, Jan. 19, 2019. (U.S. Navy photo by Mass Communication Specialist 2nd Class Ford Williams/Released) 190119-N-JI086-050

Capability Analysis

Regaining the High Ground at Sea: Transforming the U.S. Navy’s Carrier Air Wing

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By Bryan Clark

Regaining the Maritime “High Ground”

Aircraft carriers have been the centerpiece of the U.S. Navy since they came to prominence during the Second World War. Their mobility and firepower were essential to winning the Pacific Campaign during that conflict, and carriers’ adaptability enabled them to remain the fleet’s primary means of power projection through the Cold War and in multiple smaller conflicts thereafter. Unless the Navy dramatically transforms its carrier air wings (CVW), however, the carrier’s preeminence will soon come to an end.

America’s carriers, often the target of adversaries, are once again under threat. China and Russia are investing in networks of sensors and weapons designed to deter U.S. and allied forces from intervening in their regions. As part of their efforts, these great power competitors, in addition to regional powers like Iran and North Korea, are fielding anti-ship cruise and ballistic missiles, warships, and submarines to threaten U.S. carriers.

The Navy is developing ways to counter enemy kill chains from initial detection through engagement. Carrier strike groups (CSG) will need to maneuver, minimize their radiofrequency emissions, and limit flight operations to reduce the vulnerability of carriers to detection and targeting and maximize the capacity of their air defenses. But employing these capabilities and tactics could significantly constrain carriers’ sortie generation capacity.

To retain their ability to defeat aggression, CSGs will need to conduct wartime operations from areas where they can generate high-volume sorties and fires and their defenses can realistically defeat enemy attacks. This will likely place them about 1000 miles from concentrations of Russian or Chinese forces, or up to 500 miles from the missile batteries of regional powers. At these ranges, the Navy’ current and planned air defense capabilities will be sufficient for CSGs to protect themselves without having to rely extensively on countering enemy sensors.

Unfortunately, the Navy’s current and planned carrier air wings (CVW) lack the reach, survivability, and specialized capabilities to effectively protect U.S. forces at sea and ashore or attack the enemy from 1000 miles away. Carriers are an important, and in some scenarios essential, element of the National Defense Strategy’s “contact” and “blunt” forces that will counter enemy aggression because they are more heavily defended and less vulnerable than forward land bases. If CSGs cannot substantially contribute to degrading, delaying, or defeating aggression, the Navy should reconsider continuing its investment in carriers and their aircraft and shift those resources toward more effective approaches.

As arguably the ultimate modular military platform, carriers can address emerging threats and opportunities by changing the size and mix of aircraft they carry. Without the ability to evolve and support new missions, carriers and their CVWs would likely have gone the way of the battleship and left the fleet decades ago. Our new Center for Strategic and Budgetary Assessments study describes how the Navy could transform its CVWs during the next 20 years to address the challenges posed by great power militaries.

Changing Carrier Strategy and Tactics

Some analysts recommend that rather than invest in new aircraft and improved carrier defenses, the Navy should use missiles from surface combatants and submarines to defend naval forces and attack enemy targets. This approach, however, would be unsustainable and may not deter a committed aggressor.

Long-range surface-launched missiles are more expensive and less numerous than the glide, gravity, and powered weapons carried by aircraft. Moreover, once a ship or submarine expends its missiles, it will need to withdraw from the fight to safely reload, even if that reloading could be done at sea. Using large numbers of missile-carrying merchant vessels to sustain fires would not solve these problems, because large numbers of expensive standoff weapons would still be needed, as well as defenses for the vessels carrying them.

Instead of replacing carriers with missiles, the Navy should use them as complementary capabilities. Missile-centric platforms such as submarines and surface combatants are well-suited for the NDS’ contact forces, which will be the first to engage the enemy and need to generate large volumes of offensive and defensive fires on short notice. Carriers should be used mostly in the NDS’ blunt force, which will reinforce and support the contact force. Carriers take time to generate sorties, but can sustain fires as long as the carrier is resupplied, allowing contact force ships and submarines to withdraw and reload. Without the threat of sustained resistance from the blunt force, an aggressor like China could choose to fight through ship-launched missiles until ships and submarines need to reload.

Under this construct, CSGs will be employed in four main categories of operations, which are similar to how carriers were used in previous great power competitions and conflicts:

  • Day-to-day training, port calls, and exercises inside contested regions during peacetime to build alliances and demonstrate U.S resolve not to cede waters to adversary intimidation or coercion.
  • Smaller-scale operations at long range against highly defended targets of great power adversaries, such as strike and surface warfare (SUW) attacks of 200 weapons or less, electromagnetic warfare (EMW) or escort missions, and anti-submarine warfare (ASW);
  • Sustained operations at the periphery of great power confrontations, such as in the Philippine or South China Seas against China or in the Norwegian Sea against Russia; and
  • The full range of operations against regional powers such as Iran or North Korea that lack integrated, long-range surveillance, anti-air, and anti-ship capabilities.

Within these broad categories, CVWs will need perform the same missions they do today, but using new operational concepts that address ongoing and future enhancements to adversary threats and the geographic advantages enjoyed by great power and some regional adversaries.

The predominant challenge facing U.S. forces against China and Russia is the threat of long-range precision weapons, making air and missile defense an important enabling concept for CVWs. To survive against Chinese or Russian surface-, air-, and submarine-launched missiles, U.S. forces will need to complement air defenses on ships and air bases with actions to thin out missile salvos in flight and attack enemy missile-launching “archers” before they can launch their “arrows.”

This updated version of the Navy’s “Outer Air Battle” doctrine would place defensive counterair (DCA) combat air patrols (CAP) along the most likely threat axes at the ranges of future anti-ship and land-attack missiles, or about 800 to 1,000 miles. Outside the most likely threat sectors, distributed fires from surface combatants, ground-based air defenses, and DCA aircraft would engage enemy aircraft using targeting from intelligence, surveillance, reconnaissance, and targeting (ISR&T) CAPs. Shorter-range CAPs operating 100-200 miles from carriers and other defended targets would thin out cruise missile salvos, effectively adding capacity to ship and shore-based air defenses.

21st Century Outer Air Battle (CSBA graphic)

Because of their operating areas and the challenge of air- and sea-launched missiles, future CVW strike and SUW operations will need to occur 500–1,000 miles away from the CSG, depending on the adversary. Using standoff weapons such as the Joint Air-to-Surface Standoff Missile (JASSM) could allow carrier aircraft to launch strike and SUW attacks from closer to the carrier, but these weapons are expensive and in short supply. Instead, strike and SUW operations will need to occur from shorter standoff ranges, employing a combination of survivable aircraft, and offensive counterair (OCA) and EMW operations.

With the growing number and sophistication of Russian and Chinese submarines, the Navy has reinvigorated its efforts at anti-submarine warfare (ASW). Today’s ASW platforms such as the P-8A Poseidon are potentially too vulnerable to conduct ASW operations near a great power adversary’s territory. Others, like the MH-60R Seahawk helicopter, lack the range or endurance to conduct ASW operations beyond the 1,000-mile reach of enemy submarine-launched cruise missiles. To conduct ASW in contested areas, U.S. naval forces will need to rely increasingly on unmanned sensors to find and target submarines. CVW aircraft operating in ASW CAPs would then promptly engage possible submarines at ranges of up to 1,000 miles from the carrier or defended areas ashore.

U.S. adversaries are likely to protect valuable ports, airfields, and sensor and C2 facilities with their own DCA CAPs and air defense systems. To enable CVW or land-based attack aircraft to closely approach targets and use smaller short-range weapons, carrier-based escort aircraft could attack air defenses, help protect strike aircraft from CAPs, and launch expendable jammers and decoys to confuse aircraft and air defense radars and weapons.

Escort missions will require a combination of long-range fighters able to engage enemy DCA CAPs and attack aircraft with the payload capacity to carry missile- or unmanned aerial vehicle (UAV)-borne jammers, sensors, or decoys. An attack aircraft could also carry high-power standoff jammers such as the Next Generation Jammer (NGJ) that will be carried by the E/A-18G Growler until it retires in the 2030s.

A Needed Transformation

The operational concepts needed to implement current and likely future defense strategies will require new aircraft and a different CVW configuration than in today’s fleet. CSBA’s proposed CVW would include:

Long-range Multi-mission Survivable Unmanned Combat Air Vehicle (UCAV)

Air and missile defense, ISR&T, strike, SUW, ASW, and EMW missions are all evolving in a way that makes them best conducted by aircraft with longer range or endurance, higher survivability, and a payload on par with today’s Navy strike-fighters. An attack aircraft such as an unmanned combat air vehicle (UCAV) could achieve an unrefueled range of up to 3,000 miles through a fuel-efficient airframe optimized for subsonic speeds. A UCAV could also achieve high levels of survivability by combining a radar-scattering shape with electronic warfare systems and self-defense weapons. And although being unmanned would not necessarily increase its range, a UCAV would be capable of longer endurance than manned strike-fighters provided aerial refueling is available.

UCAV-based Airborne Electronic Attack (AEA) Aircraft

The Navy plans to continue using the E/A-18G as its AEA platform into the 2030s and beyond, but its reliance on standoff effects from outside the range of enemy air defenses is likely unsustainable in the face of improving passive sensors and the increasing range of surface-to-air missiles (SAM) and AAMs. A low-observable platform such as the proposed UCAV could be made into an stand-in AEA platform by incorporating subsystems of the E/A-18G into its mission bay and installing multiple active electronically scanned arrays (AESA) along its wings and fuselage. A UCAV-based AEA aircraft could also carry and deploy expendable EMW UAVs and missiles that would conduct ISR&T, jamming, decoy, and deception operations over target areas.

Unmanned Aerial Refueling Aircraft (MQ-25)

A dedicated carrier-based aerial refueling tanker could enable CVW aircraft to reach CAP stations 1,000 miles from the carrier and conduct long-range attacks against enemy ships and shore targets. The U.S. Navy is already pursuing the MQ-25 carrier-based tanker UAV for this reason and recently awarded design and construction contracts for the first MQ-25 demonstrators.

To fully exploit the potential of the MQ-25, the Navy should re-designate it as a multi-mission UAV. The initial version of the MQ-25 would remain focused on the aerial refueling mission to avoid delays in program development. The Navy could then develop modifications that would enable it also to conduct ISR, attack, and EMW missions in appropriate operational environments. Alternatively, the Navy could explore ways for the UCAV to also conduct the refueling mission once it is fielded.

Long-range Fighter (FA-XX)

Escort and OCA operations will require a long-range fighter to counter enemy DCA CAPs and enable land-based or CVW strike aircraft to closely approach targets and use smaller, short-range strike weapons. The range, sensor capability, and weapons capacity needed in a future long-range fighter could be provided with a modified version of an existing fighter or strike-fighter by shifting weapons payload to fuel capacity and incorporating additional fuel efficiency measures.

Planned Aircraft Retained in Proposed 2040 CVW

Between FY 2019 and FY 2023, the Navy plans to complete the procurement of MH-60R ASW and MH-60S logistics helicopters, E-2D AEW&C aircraft, and E/A-18G EW strike-fighters. The proposed 2040 CVW includes MH-60s and E-2Ds, which may require some life extension; both aircraft will, however, have reduced roles in 2040 compared to today due to their constrained range and survivability.

The proposed 2040 CVW would buy the first half of the F-35C program to supply one squadron per CVW, but the second squadron would be replaced with the FA-XX. Although not formally part of the CVW, the proposed 2040 CVW assumes the Navy’s ongoing plan to replace the C-2A logistics aircraft with the CMV-22 Osprey. The 2040 CVW also includes in its helicopter squadrons a medium-altitude, long-endurance (MALE) Vertical Take-Off and Landing Tactical Unmanned Aerial Vehicle (VTUAV) based on ongoing development efforts in the Navy and Marine Corps for an unmanned multi-mission aircraft, known as the Marine Air-Ground Task Force (MAGTF) Unmanned Aerial System (UAS) Expeditionary (or MUX).

Future CVW Composition

CSBA’s proposed 2040 CVW, shown below, includes the new and existing aircraft described above in a mix that improves the Navy’s CVW range, endurance, survivability, and payload capacity. Whereas the Navy’s planned CVW would center around 20 F-35C and 24 F-18 E/F or FA-XX strike-fighters, the proposed CVW is built around 18 UCAVs, ten FA-XX fighters, ten F-35C strike-fighters, and six UCAV-based AEA aircraft. Although the aggregate payload capacity of the proposed CVW is about the same as the Navy’s plan, the 2040 CVW could deliver its payload twice as far or remain on station much longer.

The proposed CVW also incorporates more specialized aircraft to address the growing capability of great power competitors. The long-range FA-XX fighter will be better able to counter enemy DCA aircraft, and the UCAV will be a more effective platform to support long-endurance CAP missions for air defense, ASW, SUW, and ISR&T than the Navy’s planned CVW of short-range strike-fighters. The CVW also includes more MQ-25 tankers to maximize the CVW’s reach and endurance.

CSBA’s Proposed 2040 CVW (CSBA Graphic)

Making the New CVW a Reality

There are several different combinations of programmatic changes that could be used to reach the proposed CVW by 2040. CSBA recommends the following actions, starting with the President’s Budget for FY 2020. Notably, the new procurement proposed by this study would not begin until after the FY 2020–2024 Future Year’s Defense Plan (FYDP), although some research and development funding would be repurposed within the FYDP.

  • Sustain procurement of F/A-18 E/Fs as planned through 2023. Although the future CVW requires half the strike-fighters of the Navy’s planned CVW, these aircraft will fill near- to mid-term capacity gaps. F/A-18 E/Fs still in service by 2040 can be used in place of UCAVs or F-35Cs if those aircraft are not yet fully fielded.
  • Sustain F-35C procurement as planned through the first half of production, ending in 2024, to support the proposed 2040 CVW’s squadron of ten F-35Cs.
  • Develop the FA-XX fighter during the 2020–2024 timeframe as a derivative of an existing aircraft, with production starting in 2025. Block III F/A-18 E/Fs and F-35Cs will be in production during the FY 2020–2024 FYDP, and either they or another in-production fighter or strike-fighter could be modified into an FA-XX. Although this approach will require some additional funding for non-recurring engineering between about 2020 and 2024, it will save billions of dollars compared to the Navy’s plan to develop a new fighter aircraft from scratch.
  • Develop a low-observable UCAV attack aircraft during the 2020–2024 timeframe, with production starting in 2025. Although the UCAV could be based on an existing design such as the X-47B, 1–2 years of development may be needed to create a missionized version.
  • Continue development of the MQ-25, transitioning the program to the UCAV-based refueling aircraft when sufficient attack UCAVs are fielded. Increase the overall procurement of MQ-25 and UCAV-based refueling aircraft to support twelve per CVW.
  • Retire E/A-18Gs as they reach the end of their service lives starting in the late 2020s, replacing their capability with NGJ-equipped UCAVs and UAV- and missile-expendable EMW payloads.
  • In concert with the U.S. Marine Corps, field a MALE rotary-wing UAV such as the Tactically Exploitable Reconnaissance Node (TERN), which can augment CVW helicopter squadrons and could take over some of their ASW operations by the mid-2030s.

The fixed-wing carrier aircraft inventory associated with these recommendations is shown below. Under this plan, research and development of the planned MQ-25, modified FA-XX, and new UCAV would occur during the 2020–2024 timeframe, with production of new aircraft starting in 2025. Today’s F/A-18 E/Fs and E/A-18Gs would begin retiring in the late 2020s, to be replaced by UCAVs. The overall inventory of CVW aircraft will decrease as unmanned aircraft replace manned platforms, because operators and maintainers of unmanned aircraft can practice using simulators that will be as realistic as actual UAVs, eliminating the need for unmanned aircraft in training squadrons or in fleet squadrons that are not deployed or preparing to deploy. The smaller number of aircraft and squadrons results in a cost savings for unmanned aircraft compared to manned aircraft.

Fixed-Wing CVW Aircraft Inventory to Build Proposed 2040 CVW. (CSBA graphic)

The approximate cost of the proposed 2040 CVW is shown below. Except for developmental spending associated with the proposed UCAV, proposed new development, procurement, and operations spending does not begin until FY 2024. The cost associated with the proposed 2040 CVW is less than the Navy would likely incur with its planned strike-fighter focused CVW. The continued reliance on manned strike-fighters results in a larger overall number of aircraft being required compared to the proposed CVW, primarily to train pilots and maintain their proficiency when not deployed. The higher aircraft inventory increases operations and maintenance (O&M) costs during the first decade of the period shown and raises procurement costs during the 2030s when today’s F/A-18 E/Fs are replaced with a new manned strike-fighter.

Total Cost of Proposed and strike-fighter Focused CVWs (CSBA Graphic)

A Clear Choice

The proposed 2040 CVW will be more expensive in the near-term than the Navy’s planned CVW, but the Navy will need to incur these additional costs if it is to prevent carrier aviation from becoming irrelevant to the most pressing defense challenges of the near future. The threats posed by great power competitors, and increasingly by regional powers such as Iran and North Korea, preclude relying on legacy capabilities to protect American allies and interests overseas.

Naval forces will be instrumental in deterring and defeating aggression by these adversaries, as described in the NDS. Carrier air wings provide the ability to sustain naval combat operations beyond the first few days, when ship and submarine missile inventories are depleted. Without a clear plan to improve the Navy’s CVWs, the United States may not be able to implement its defense strategy, and DoD leaders would need to reconsider if they want to continue the Navy’s investment in carrier aviation or shift resources to other, more effective, capabilities.

Bryan Clark is a Senior Fellow at the Center for Strategic and Budgetary Assessments. He was a career enlisted and officer submariner and held several positions in the Chief of Naval Operations staff, including Director of the CNO’s Commander’s Action Group.

Featured Image: South China Sea (Feb. 10, 2018) The Nimitz-class aircraft carrier USS Carl Vinson (CVN 70) transits the South China Sea. (U.S. Navy photo by Mass Communication Specialist Third Class Jasen Morenogarcia/Released)