Livens Projector

The Livens Projector was a simple, single-use mortar developed by British Army Captain William H. Livens of the Royal Engineers in 1915 for chemical warfare during World War I, consisting of an 8-inch (215 mm) steel tube fixed at a 45-degree elevation and half-buried in the ground to propel large drums filled with gas or flammable oil up to 1,500 meters.^[1]^[2]^[3] Designed to deliver massive, sudden barrages of chemical agents like phosgene or chlorine—or incendiary oil—in batteries of dozens or hundreds of projectors, it allowed the British to saturate enemy positions with minimal warning and high accuracy, firing approximately 60-pound (27 kg) projectiles containing 30 pounds (14 kg) of agents that burst on impact to release their contents over a targeted area.^[3]^[1]^[4]^[5] First deployed by the British Empire forces at the Battle of the Somme in 1916, the weapon saw extensive use in major offensives, including over 1,500 projectors launching flammable drums before the Battle of Messines in June 1917 and 290 units at the Battle of Menin Road in September 1917, proving particularly demoralizing to German troops who described the gas attacks as "utterly unbearable."^[1]^[2]^[3] With over 140,000 projectors and 400,000 projectiles produced, it became the standard British method for gas delivery by 1917, was supplied to allies like the French Army, and influenced German adaptations such as the GasWerfer 17; the design was later standardized by the U.S. Army in 1924 for interwar stockpiles.^[1]^[2]^[4]

Development

Invention

Captain William Howard Livens, an officer in the Royal Engineers, played a pivotal role in British chemical warfare innovations during World War I, particularly as commander of Z Company, a specialized unit focused on developing flame and gas delivery systems. Born in 1889 and trained as an engineer, Livens joined the army at the war's outset and became deeply involved in experimental weaponry by 1916, driven by the need to counter German chemical attacks following their use of chlorine gas at Ypres in 1915.^[6]^[7] The Livens Projector originated in late 1915 as a direct response to the shortcomings of existing gas delivery methods: gas cylinders released clouds that were highly dependent on wind direction and often dissipated ineffectively or endangered friendly troops, while artillery shells provided insufficient gas concentration for saturation and lacked the element of surprise due to visible trajectories. Initial development began after the Battle of Loos in September 1915. Livens conceived the device to merge the mass volume of cylinder-released gas with the ranged accuracy of projectile delivery, enabling sudden, high-density chemical barrages from concealed positions.^[8]^[9]^[10] Initial design sketches and prototypes were developed that summer at Royal Engineers' workshops, beginning with experiments firing oil-filled barrels across no man's land to test propulsion and trajectory before adapting the concept for gas canisters. Initial experiments and uses involved oil-filled barrels for incendiary effects, with the system adapted for chemical agents shortly thereafter. By July 1916, Livens submitted a formal proposal for the projector, which outlined a simple tube-based launcher for 30-pound gas drums, marking the transition from ideation to practical implementation.^[8]^[10] This early work laid the groundwork for rapid evolution into a standardized weapon, though full-scale production followed subsequent testing.

Testing and Production

A demonstration of the Livens Projector was conducted by Captain William H. Livens at the Porton Experimental Ground in December 1916, where a basic version consisting of an 8-inch diameter steel pipe elevated at 45 degrees, using inert projectiles to assess initial performance.^[11] These trials confirmed the device's potential for delivering chemical agents over short ranges, prompting further development amid the urgent needs of trench warfare.^[12] Following its first operational use with oil drums at La Boisselle on 25 July 1916 during the Battle of the Somme, and first gas deployment in September 1916 at Thiepval, refinements were made to enhance reliability and effectiveness, addressing issues like inconsistent ignition and limited projection distance observed in early deployments.^[13]^[10] By June 1917, an electrically triggered version extended the range from an initial approximately 350 yards to 1,300 yards, enabling its successful application at Messines Ridge.^[6] British production scaled rapidly between 1916 and 1918 to meet frontline demands, with total output exceeding 150,000 projectors, supported by the manufacture of hundreds of thousands of accompanying gas drums.^[6] After the United States entered the war in 1917, American forces adopted the design, training troops for five days on its operation as part of the 1st Gas Regiment's preparation starting in February 1918.^[7] U.S. production efforts, managed by the Ordnance Department's Trench Warfare Section, yielded approximately 63,000 projector barrels by companies such as National Tube Co. and Harrisburg Pipe & Pipe-Bending Co., alongside 73,723 gas drums out of a planned 334,000, with 18,600 drums filled with phosgene and shipped overseas.^[14] Logistical challenges during wartime scaling included production delays from welding difficulties in manufacturing the steel components, which were mitigated only by the armistice through alternative fire-welding techniques, compounded by broader material constraints in the munitions industry.^[14] These issues reflected the rapid industrialization required to equip both British and American forces, prioritizing quantity over precision in a resource-strained environment.^[7]

Design

Components

The Livens Projector is a simple smoothbore mortar designed for mass chemical or incendiary attacks, featuring a fixed elevation of 45 degrees and no traverse capability to facilitate rapid deployment in batteries. Its primary components include a barrel and a base plate, constructed primarily from mild steel to enable economical mass production and field durability. The following specifications primarily describe the US M1 adaptation standardized in 1924, which differed slightly from the original British design (e.g., bore diameter of 215 mm).^[2] The barrel, designated M1 in the U.S. adaptation, is a drawn seamless steel tube closed and rounded at the breech end, with an internal rust-preventive compound and external acidproof black paint for corrosion resistance.^[15] The barrel measures 37.5 inches in length, with a bore diameter ranging from 7.875 to 8.00 inches (approximately 203 mm caliber) and a wall thickness of 0.344 to 0.406 inches, allowing it to accommodate 8-inch projectiles for ranges up to about 1,450 yards when emplaced correctly. It weighs 104 pounds and is marked at the muzzle with the model designation, manufacturer, and production date for identification. A lightweight canvas muzzle cover, weighing 6.5 ounces and measuring 9 inches in diameter by 4 inches high, protects the open end during transport and storage.^[15] The base plate, also M1, is a rectangular pressed steel component weighing 28 pounds, measuring 12.75 inches wide by 19.75 inches long and 4.25 inches high, with rounded shorter sides and a central circular depression (10.5 inches in diameter and 3.75 inches deep) to securely seat the barrel. A rope handle aids in handling. For stability, the entire assembly is mounted in a shallow trench or steel trough embedded in the ground, ensuring the barrel is fixed at the 45-degree angle; this ground emplacement prevents movement during simultaneous firing of multiple projectors. The total weight of the projector (barrel and base plate) is approximately 132 pounds, though its modular design allows a single soldier to carry either component, with teams of engineers responsible for quick emplacement using carts for multiple units in the field.^[15] An integrated electrical firing system connects the projectors via buried cables to a central blasting machine, enabling synchronized detonation of propelling charges across a battery; a galvanometer tests circuit continuity prior to firing. This setup, combined with the projector's lightweight steel construction, prioritized simplicity and rapid setup over precision aiming, making it suitable for large-scale, short-range bombardment.^[15]^[16]

Ammunition and Projectiles

The standard projectile for the Livens Projector was a cylindrical drum approximately 23 inches long and 7.75 inches in diameter, constructed from seamless drawn steel tubing with a wall thickness of about 0.19 inches and forged-steel welded ends.^[17] Empty, it weighed around 33 pounds, but when filled, the total weight reached 60-63 pounds depending on the agent.^[15] These drums were designed for mass chemical or incendiary delivery, integrating directly into the projector's smoothbore barrel via a simple drop-loading mechanism.^[17] The primary filling was phosgene gas (CG) for chemical attacks, with each drum containing about 28-30 pounds of the agent, making four drums equivalent in payload to the 120 pounds released from a standard gas cylinder.^[3] Incendiary variants used flammable oil for firebombing purposes, also loaded to approximately 30 pounds per drum to create burning effects upon dispersal.^[18] Other agents like chlorine or smoke-producing mixtures (e.g., FS) were tested but less common in operational use.^[15] Each projectile featured a simple fuze and burster system to ensure rupture on impact and agent release. The fuze was typically a Bickford time-delay type, such as the 22-second model, paired with a small TNT burster charge of 2-3.5 ounces housed in a central tube to fracture the drum and form a gas or oil cloud upon landing.^[17] This low-explosive design prioritized agent dissemination over fragmentation or blast effects.^[15] The projectiles followed a high ballistic arc at a fixed 45-degree elevation, achieving a maximum range of up to 1,450 yards (approximately 1,300 meters), though minimum effective range was around 910 yards depending on propellant charge.^[15] Due to the absence of elevation or traverse adjustments on the projector, trajectories were inherently unstable, resulting in significant inaccuracy with a circular error probable (CEP) of 50-100 yards.^[15] Safety and handling protocols emphasized careful transport and storage to mitigate risks associated with the volatile fillings. Sealed drums were moved by wagon in separate components—projectiles apart from propellants—to minimize accident potential, but leaks during prolonged storage posed hazards from agent vaporization or corrosion.^[15] Misfire procedures required a one-minute wait before inspection, with a defined danger zone extending 1,800 yards in length and 300-600 yards wide to account for potential erratic flights.^[15]

Operation

Deployment Procedures

The deployment of the Livens Projector was managed by specialized units such as the British Special Brigade of the Royal Engineers, with American forces later adopting similar procedures through the 1st Gas Regiment.^[7] These teams typically handled the emplacement and preparation, focusing on rapid setup to maintain tactical surprise.^[7] Site selection prioritized positions near the front lines, often in forward trenches, to optimize range and gas cloud concentration over enemy targets.^[7] Emplacement occurred under cover of darkness to minimize detection risk, with teams digging angled pits or trenches for stability.^[7] Each pit measured approximately 8 inches wide, 8 inches deep, and 13 inches long, with 45-degree slopes and an undercut front wall to secure the base plate.^[15] The projector barrels were then inserted and aligned at a 45-degree elevation—equivalent to 800 mils—using a clinometer for precise targeting based on maps or compass bearings.^[7]^[15] Batteries ranged from 25 projectors for smaller operations to hundreds or thousands for major assaults, such as the 700 used in a single 1918 shoot or the 3,728 employed at Lens.^[7] Projectors within a battery were positioned to create dense gas clouds upon arrival, with electrical ignition wires connected in series to a central battery or blasting machine for synchronized firing.^[15] Pre-fire preparations involved verifying wind direction and speed to confirm the gas would drift toward enemy positions, alongside circuit testing with a galvanometer.^[19]^[15] To enhance secrecy and survivability, pits were filled and tamped with earth for camouflage, while cables were buried to obscure them from enemy observation and reduce vulnerability to counter-battery fire.^[15] This logistical process allowed batteries to be readied efficiently, often emplaced the night before use.^[7]

Firing Mechanism

The firing mechanism of the Livens Projector utilized an electrical system to enable simultaneous discharge across multiple units, facilitating large-scale salvoes for maximum tactical surprise. Projectors in a battery were wired in series via ignition leads connected to a central firing point, powered by a hand-cranked electric blasting machine or dynamo that delivered current to electric squibs in the propelling charges. This setup allowed batteries of up to 25 projectors to be fired instantaneously by activating a switch, with common configurations linking groups of 20 units for coordinated release.^[15]^[6] Loading proceeded by inserting the black powder propelling charge drum breech-first into the tube's base, followed by the projectile drum containing gas or other agents, with the ignition wires secured to a nearby stake to prevent displacement. Upon firing, the electric current ignited the squib, detonating the charge and launching the projectile along a fixed 45-degree elevation trajectory. Range was controlled solely by adjusting the propelling charge weight, such as 24 ounces for approximately 910–1,010 yards or 40 ounces for 1,350–1,450 yards, without altering the tube's angle.^[15] Salvo tactics emphasized massed launches, with hundreds of projectors often discharged in rapid succession to saturate target areas; the entire battery ignited nearly simultaneously, producing a near-instantaneous barrage that formed dense gas clouds within seconds of launch. Following a salvo, tubes were cleared of residue and cleaned to dissipate heat and prevent corrosion, allowing for reloading and potential follow-up fires after debris removal and wire inspections. Safety protocols required personnel to remain at least 50 yards to the rear during firing, with circuits tested via galvanometer beforehand to ensure reliability.^[15]

Combat History

World War I Engagements

The Livens Projector was first tested in secret during the Battle of the Somme at Thiepval in September 1916, marking its initial battlefield evaluation to deliver phosgene gas in support of infantry operations. This trial shifted the weapon from experimental status toward operational use, with the projectors buried in forward trenches and fired simultaneously to create gas clouds over German positions. A subsequent trial at Beaumont-Hamel in October–November 1916 during the Battle of the Ancre further refined the system, testing gas canister delivery under combat conditions and demonstrating its potential for saturating narrow sectors with chemical agents. In April 1917, the Livens Projector played a prominent role in the Canadian Corps' assault on Vimy Ridge as part of the Battle of Arras, where approximately 2,000 projectors fired a massive phosgene salvo to neutralize German defenses ahead of the advance. The coordinated barrage blanketed enemy lines in toxic vapor, contributing to the capture of the ridge with relatively low Allied losses in the targeted areas. Later that year, during the Battle of Messines in June 1917, approximately 1,500 projectors launched flammable oil drums to create a fire barrier isolating German reserves and supporting the explosion of underground mines, enhancing the effectiveness of the creeping artillery barrage that preceded the infantry push.^[1] At the Third Battle of Ypres (including Passchendaele) from July 1917 to early 1918, multiple salvos involving hundreds of projectors were integrated into gas operations to disrupt German counterattacks amid the muddy terrain.^[11] The projector's ability to deliver gas equivalent to thousands of cylinders in a single volley proved highly effective, often inflicting significant casualties among exposed troops while British, Canadian, and later U.S. forces adopted it for chemical attacks. U.S. Army units, arriving in 1918, conducted projector-based gas assaults, such as during the Meuse-Argonne Offensive, drawing on British designs to supplement their artillery. Its integration with creeping barrages allowed gas clouds to advance in tandem with high-explosive shells, timing releases to mask infantry movements and suppress machine-gun nests. However, wind shifts posed significant risks, occasionally blowing gas back onto Allied lines and inflicting unintended casualties.^[7] Beyond physical harm, the Livens Projector induced profound psychological effects on German troops, with sudden, overwhelming gas clouds triggering panic and flight from trenches, as reported by captured prisoners who described it as the most demoralizing Allied weapon encountered.^[3] This terror factor amplified its tactical value, often breaking enemy morale before direct engagement, though operational reliance on favorable winds limited its predictability in fluid battles.

Post-War Applications

Following the Armistice of 1918, the Livens Projector remained in the British Army's inventory during the interwar period for potential chemical warfare contingencies, despite the 1925 Geneva Protocol's prohibition on the use of asphyxiating gases. It influenced interwar chemical warfare doctrine and was supplied in limited quantities to allies like the French Army.^[2] With the onset of World War II, the projector was considered for gas defense preparations in 1939–1940 amid fears of German chemical attacks, though no offensive or large-scale employment occurred due to the Protocol's constraints and mutual deterrence. By the mid-1940s, the weapon was phased out of service, supplanted by more precise artillery, aerial bombing, and improved mortars suited to mobile warfare. Surplus stockpiles were disposed of in compliance with international agreements.^[4]

Equivalents and Influences

German Gaswurfminen

The German adaptation of the Livens Projector, known as the Gaswurfminen or 18 cm Gaswerfer, emerged in 1917 as a direct response to captured British examples encountered on the Western Front.^[20] Development was led by the firm Rheinmetall, which produced the weapon starting in late 1917 to enhance chemical warfare capabilities in static trench positions.^[20] This design drew inspiration from the British original's simple, mass-fire concept but incorporated refinements for greater reliability in deployment.^[2] The Gaswerfer maintained a similar 18 cm calibre to align with existing German ammunition stocks, such as those from the Ladungswerfer, while using existing 18 cm minenwerfer projectiles.^[20] It fired projectiles typically filled with phosgene or mustard gas for area saturation attacks, allowing batteries of tubes to deliver synchronized barrages over enemy lines.^[20] Unlike conventional mortars, the system relied on electrical ignition for precise, simultaneous firing from buried tubes, mimicking the British model's battery tactics but without a separate base plate for faster setup in forward positions.^[20] Rheinmetall produced approximately 44,000 units, with thousands deployed across the Central Powers' fronts by war's end.^[20] The weapon saw its first combat use during the Battle of Caporetto in October 1917, where 894 projectors—part of a larger array—unleashed a devastating phosgene attack against Italian positions in the Flitscher Basin, contributing to the rapid breakthrough.^[20] These modifications addressed limitations in the original's rudimentary sighting, making the Gaswerfer more adaptable for the German army's defensive and offensive needs.^[2]

Other International Adaptations

The American Expeditionary Forces adopted the Livens Projector in early 1918 as part of their chemical warfare capabilities, following training provided by the British Special Brigade to the U.S. 1st Gas and Flame Regiment.^[7] The weapon was integrated into operations with minimal modifications, primarily for logistical compatibility with existing Allied supply chains, and the U.S. Army standardized its design for field use.^[4] The first independent American gas attack using the projector occurred on June 18, 1918, when Company B of the 1st Gas Regiment fired 700 eight-inch projectors loaded with 60-pound phosgene drums at targets 1,500 meters away, inflicting at least 50 casualties including 10 fatalities.^[7] Subsequent uses included a October 2, 1918, shoot with 56 projectors near Bois La Ville and a larger barrage of 230 projectors on October 16, 1918, supported by French logistical aid.^[7] While the U.S. requisitioned 50,000 projector shells in September 1917, production of the projectors themselves remained largely British-led, with American efforts focused on ammunition and emplacement techniques rather than mass manufacturing.^[7] The French Army also employed the Livens Projector during the final year of World War I, acquiring several hundred units directly from British production to supplement their own chemical delivery systems.^[2] These were deployed in joint emplacements alongside British and American forces in 1918, particularly for large-scale gas cloud attacks that mirrored British tactics.^[21] French applications emphasized chemical agent dispersion over incendiary payloads under the designation "lance-bombes chimiques," though these did not lead to widespread independent production.^[21] Collaboration with U.S. units, such as providing 100 soldiers and 47 horses for a October 1918 barrage, highlighted integrated Allied use of the weapon.^[7] Post-World War I, the Livens Projector's simple design influenced limited adaptations in other nations, though mass production was rare outside the major combatants. The Soviet Red Army developed chemical mortar variants in the late 1920s through Group D, drawing on World War I projector concepts for civil war-era applications, but these evolved into independent 107 mm systems rather than direct copies.^[22] Japanese forces showed interest in similar projection technologies during the 1930s Manchurian campaigns, incorporating chemical delivery mortars influenced by Allied designs, yet opted for bespoke systems suited to their biological and chemical programs without widespread Livens replication.^[23] Neutral countries like Sweden and the Netherlands conducted interwar evaluations of the projector for defensive purposes, analyzing captured or licensed examples, but neither pursued mass production due to international treaties and strategic priorities.^[24] Overall, non-Axis adaptations prioritized gas and incendiary payloads tailored to national logistics, diverging from the British emphasis on rapid mass deployment.^[21]

Legacy

Tactical Impact

The Livens Projector revolutionized gas delivery in World War I by enabling surprise mass releases of chemical agents, such as phosgene, that created dense clouds over enemy positions without the inaccuracies inherent in artillery gas shells. Unlike earlier cylinder methods, which required favorable winds for release, the projector allowed batteries of up to 3,728 tubes to fire simultaneously, propelling 30-pound drums over 1,200 to 1,900 meters and saturating targeted areas rapidly—for instance, the 31 March 1918 attack at Lens released an estimated 56 tons of phosgene in minutes, bypassing the dispersion issues of shell fire and achieving concentrations comparable to cylinder attacks but with minimal warning.^[7] This tactical advantage supported infantry advances by forming "gas curtains," temporary barriers that suppressed machine-gun nests and disrupted enemy defenses.^[7] Despite these benefits, the weapon had notable limitations, including heavy reliance on weather conditions; wind shifts could redirect gas clouds back toward Allied lines, contributing to friendly casualties across major attacks. Additionally, emplacing the projectors in front-line trenches at a 45-degree angle exposed crews to counter-battery fire during nighttime setup, increasing vulnerability in static trench warfare.^[7] These factors sometimes reduced operational reliability, though the projector's simplicity allowed for rapid deployment in batteries, influencing a doctrinal shift toward integrated chemical barrages in 1918 offensives that prioritized overwhelming suppression over prolonged engagements.^[25] The projector's psychological effects were profound, often leading to high demoralization among German troops, who described it as the most unbearable Allied weapon and reported instances of surrenders due to the sudden, suffocating gas onslaughts. It contributed significantly to overall World War I gas warfare casualties, with British projector attacks alone causing 444 casualties and 81 deaths between December 1917 and May 1918, amid total estimates of approximately 90,000 fatalities from chemical agents across all belligerents.^[3] This escalation spurred innovations in protective equipment, including advancements in respirators like the small box type, which improved filtration against phosgene and other persistent gases to counter the projector's dense releases.^[3]^[26]

Preservation and Surviving Examples

In 2006, an unexploded phosgene gas cylinder, likely from a Livens Projector projectile, was recovered from the Somme battlefield in northern France during archaeological work.^[27] Ongoing explosive ordnance disposal (EOD) operations in Belgium and France frequently encounter and neutralize World War I chemical munitions, including remnants of Livens Projector batteries and projectiles, as part of efforts to address the legacy of millions of tons of unexploded ordnance across former battlefields, including thousands of tons of chemical munitions buried or dumped post-war; approximately 400 tonnes of munitions (including metal casings) are recovered annually in France, with around 10% being chemical weapons.^[28]^[29] Several surviving examples of Livens Projectors and their components are held in museums. The Imperial War Museum in London displays a preserved metal Livens Projector barrel, measuring 1250 mm in length and associated with First World War gas delivery operations.^[6] At the Sanctuary Wood Museum (Hill 62) in Zillebeke, Belgium, multiple rusted barrels recovered from nearby battlefields are exhibited outdoors, illustrating their battlefield deployment.^[30] Preservation of these artifacts faces significant challenges, including severe corrosion caused by residual chemical agents that degrade the steel over time.^[31] Additionally, legal restrictions govern their handling due to the hazardous nature of any remaining toxic residues, requiring specialized protocols under programs like the U.S. Department of Defense's Recovered Chemical Warfare Material initiative for safe storage and disposal.^[4]