Two aspects of how the Second World War commenced helped to delay the development of anti-tank warfare: resignation and surprise. After Poland was attacked, its allies in the West were resigned to its defeat by a numerically superior Wehrmacht. The little information that was brought out about the conduct of combat during that campaign did nothing to convince either France, Britain, or the USSR of the need for improved anti-tank technology and tactics. The reliance on the Maginot Line and the subsequent surprise of the German offensive left no time to develop existing abilities and tactics in the West. The British were preparing the stop lines and the
anti-tank islands to slow enemy progress and restrict the route of an attack. The Red Army, however, was fortunate in having several excellent designs for anti-tank warfare that were either in the final stages of development for production, or had been rejected earlier as unnecessary and could now be rushed into production. The relative ease with which the older models of the Red Army's tank fleet were destroyed by German anti-tank weapons, using tactics already seen in Spain, once and for all focused Stavka's attention on anti-tank warfare as panzer-led strategic pincer maneuvers repeatedly encircled Soviet armies. Of the major iconic Soviet weapons of the Second World War, two were made exclusively for anti-tank warfare, the
T-34 and the
Ilyushin Il-2 Shturmovik. The former was one of the most-produced tanks in history, and the latter, itself dubbed the 'flying tank', was one of the most-produced aircraft. The war also saw the creation and almost immediate abandonment of the self-propelled tank destroyer, which would be replaced post-war by the anti-tank guided missile. File:Fighting Men Crack That Tank (1942).webm|
"Fighting Men: Crack That Tank!" (1943) De-classified official U.S. Army anti-tank warfare training film reel. File:How To Destroy German Tanks.webm|
"How To Destroy German Tanks" De-classified official U.S. Army anti-tank warfare training film reel.
Aircraft planes with 23 mm cannons attacking a German tank column during the
Battle of Kursk As tanks were rarely used in conflicts between the two World Wars, no specific aircraft or tactics were developed to combat them from the air. One solution adopted by almost all European air forces was to use bomb loads for conventional bombers composed of small bombs, allowing a higher bomb density during bombing. This increased the likelihood of directly impacting the tank's thinner top armor while also damaging the track and wheels through proximity detonation. The first aircraft capable of engaging tanks was the
Junkers Ju 87 "Stuka," which used
dive bombing to deliver the bomb close to the target. Some French and German fighters fitted with 20 mm cannons were also able to engage the tanks' thinner top armor early in the war. The Stuka was also equipped with cannons for an anti-armor role. However, it was obsolete by 1942, and was joined by the
Henschel Hs 129 that mounted a podded
MK 101 cannon beneath its fuselage, while the Red Army Air Force fielded the Soviet
Ilyushin Il-2 armed with a pair of 23 mm cannons and unguided rockets, but armored to enable the pilots to approach German tanks at very low altitude, ignoring small arms, machine-gun and even small anti-aircraft cannon fire that usually provided tanks with protection against the bombers. Il-2s could also carry large numbers of 2.5 kg shaped-charge anti-tank
PTAB bombs. To give it more firepower against tanks, the RAF mounted two underwing pod-mounted 40 mm
Vickers S cannon on the
Hawker Hurricane (as the
Mk. IID), which saw service in North Africa in 1942 and the
Hawker Typhoon was given HE rockets. However, these were more effective against other ground vehicles. From March 1943 the Red Army Air Force produced the more agile
Yakovlev Yak-9T (37 mm cannon) and K (45 mm cannon) bomber interceptor also used for ground attack, with one example of either gun in
motornaya pushka mounts attached to the engine's gear reduction unit, that had either one of them firing through a hollow-center propeller shaft. Following
Operation Overlord in 1944, the military version of the slow-flying
Piper J-3 Cub high-wing light civilian monoplane, the L-4 Grasshopper, usually used for liaison and artillery-spotting, began to be used in a light anti-armor role by a few U.S. Army artillery spotter units over France; these aircraft were field-outfitted with either two or four
bazooka rocket launchers attached to the
lift struts, against German armored fighting vehicles. During the summer of 1944, U.S. Army Major
Charles Carpenter managed to successfully take on an anti-armor role with his rocket-armed Piper L-4. His L-4, named
Rosie the Rocketeer, armed with six bazookas, had a notable anti-armor success during an engagement during the
Battle of Arracourt on September 20, 1944, knocking out at least four German armored vehicles, as a pioneering example of taking on heavy enemy armor from a lightweight slow-flying aircraft.
Field artillery Field artillery was often the first ground combat arm to engage a detected concentration of troops, including tanks, through artillery fire, airborne observers, either in assembly areas (for refueling and rearming), during approach marches to the combat zone, or as the tank unit was forming up for the attack. Conventional artillery shells were very effective against the tank's thinner top armor when fired at appropriate density while the tanks were concentrated, enabling direct hits from sufficiently powerful shells. Even a non-penetrating shell could still disable a tank through dynamic shock, internal armor shattering, or simply by overturning it. More importantly, the tanks could be disabled by damage to tracks and wheels, and their supporting vehicles and personnel could be damaged or killed, reducing the unit's ability to fight in the longer term. Because tanks were usually accompanied by infantry mounted on trucks or
half-tracked vehicles that lacked overhead armor, field artillery firing a mix of ground- and air-burst ammunition was likely to inflict heavy casualties on the infantry as well. Field guns, such as the
Ordnance QF 25 pounder, were provided with armor-piercing shot for direct engagement of enemy tanks.
Anti-tank guns Anti-tank guns are guns designed to destroy armored vehicles from defensive positions. To penetrate vehicle armor, they fire smaller caliber shells from longer-barreled guns to achieve higher muzzle velocity than field artillery weapons, many of which are
howitzers. The higher velocity, flatter trajectory
ballistics provides terminal
kinetic energy to penetrate the moving/static target's armor at a given range and contact angle. Any field artillery
cannon with a barrel length 15 to 25 times longer than its
caliber was able to fire anti-tank ammunition, such as the Soviet
A-19. Before
World War II, few anti-tank guns had (or needed) calibers larger than 50 mm. Examples of guns in this class include the
German 37 mm,
US 37 mm (the largest gun able to be towed by the
1⁄4-ton, 4×4 'jeep'),
French 25 mm and
47 mm guns,
British QF 2-pounder (40 mm),
Italian 47 mm and
Soviet 45 mm. All of these light weapons could penetrate the thin armor found on most pre-war and early-war tanks. 50-mm anti-tank gun At the start of
World War II, many of these weapons were still in operational use, along with a newer generation of light guns that closely resembled their WWI counterparts. After the well-armoured Soviet
T-34 medium and
KV heavy tanks were encountered, these guns were recognized as ineffective against
sloped armor, with the German lightweight 37 mm gun quickly nicknamed the "tank door knocker" (), for revealing its presence without penetrating the armor. Germany introduced more powerful anti-tank guns, some of which had been in the early stages of development before the war. By late 1942, the Germans had an excellent
50-mm high-velocity design, while they faced the
QF 6-pounder introduced in the
North African Campaign by the British Army, and later adopted by the
US Army. By 1943, the Wehrmacht was forced to adopt still larger calibers on the
Eastern Front, the
75 mm and the famous
88 mm guns. The Red Army used a variety of 45 mm,
57 mm, and
100 mm guns, and deployed general-purpose 76.2 mm and 122-mm guns in the anti-tank role. By the time of the
Invasion of Normandy, the British had the calibre
QF 17 pounder, which design had begun before the 6 pounder entered service, in general use which proved to be a highly effective anti-tank gun and was also used on the Sherman Firefly tank, the
Archer self-propelled gun, and on the
17-pdr SP Achilles Tank destroyers self-propelled anti-tank gun put the 17-pdr gun on the hull of a
Valentine tank As towed anti-tank cannon guns grew in size and weight, they became less mobile and more cumbersome to maneuver, and required ever larger gun crews, who often had to wrestle the gun into position while under heavy artillery and/or tank fire. As the war progressed, this disadvantage often resulted in the loss or destruction of both the anti-tank gun and its trained crew. This spurred the development of the self-propelled, lightly armored "
tank destroyer" (TD). The tank destroyer was usually based on the hull of an existing tank design, using either an integrated gun or a fully rotating turret, much like a conventional tank. These self-propelled (SP) AT guns were first employed as infantry support weapons in place of towed anti-tank guns. Later, due to a shortage of tanks, TDs sometimes replaced the former in offensive armored operations. Early German-designed tank destroyers, such as the
Marder I, employed existing light French or Czech tank chassis and mounted an AT gun within an armored, turretless superstructure. This method reduced both weight and conversion costs. The Soviet Union later adopted this style of self-propelled anti-tank gun or tank destroyer. This type of tank destroyer had the advantage of a reduced silhouette, allowing the crew to more frequently fire from
defilade ambush positions. Such designs were easier and faster to manufacture and offered good crew protection, though the lack of a turret limited the gun's traverse to a few degrees. This meant that, if the TD became immobilized due to engine failure or track damage, it could not rotate its gun to counter opposing tanks, making it an easy target. This vulnerability was later exploited by opposing tank forces. Late in the war, it was not unusual to find even the largest and most powerful tank destroyer abandoned on the field after a battle, having been immobilized by one high-explosive shell to the track or front drive sprocket. US Army pre-war infantry support doctrines emphasized the use of tank destroyers with open-top, fully rotating turrets, featuring less armor than the standard
M4 Sherman tanks but with more powerful cannons. A 76 mm long-barrel tank cannon was fitted to the Sherman-based
M10 GMC and all-new design
M18 designs, with the M18 being the fastest-moving American AFV of any type in World War II. Late in 1944, the Sherman-origin
M36 appeared, equipped with a 90 mm cannon. With rotating turrets and good combat maneuverability, American TD designs generally worked well, although their light armor was no match for enemy tank cannon fire during one-on-one confrontations. Another disadvantage proved to be the open, unprotected turret, and casualties from artillery fire soon led to the introduction of folding armor turret covers. Near the war's end, a change in official doctrine caused both the self-propelled tank destroyer and the towed anti-tank gun to fall out of favor in U.S. service, increasingly being replaced by conventional tanks or infantry-level anti-tank weapons. Despite this change, the M36 tank destroyer continued in service, and was used in combat as late as the
Korean War. The third, and likely most effective kind of tank destroyer was the unturreted,
casemate-style tank destroyer, known by the
Jagdpanzer term in German service, or
Samokhodnaya Ustanovka in Soviet service for their own designs. These generally featured a heavy gun mounted on an older or then-current tank chassis, with the gun pointing forward and limited traverse. Casemate tank destroyers often had the same amount of armor as the tanks they were based on. The removal of the turret allowed for more space to mount a larger gun with a larger breech and left room for the crew. Many casemate tank destroyers either originated as or were dual-purpose vehicles with the duties of a self-propelled gun, and share many (but usually not all) of the same features and layout. Some examples are the German
Sturmgeschütz III – the most-produced German armored fighting vehicle of WW II — and the Soviets'
SU-100, itself based on the
T-34 tank's hull and drivetrain.
Infantry Rifles anti-tank rifle at the
Museum of the Great Patriotic War, Moscow Anti-tank rifles were introduced in some armies before the Second World War to provide infantry with a stand-off weapon against a tank assault. The intention was to preserve the morale of the infantry by providing a weapon capable of actually defeating a tank.
Anti-tank rifles were developed in several countries during the 1930s. By the beginning of WW2, anti-tank rifle teams could knock out most tanks from a distance of about 500 m, using a weapon that was man-portable and easily concealed. Although the AT rifle's effectiveness was negated by the increased armor of medium and heavy tanks by 1942, it remained viable against lighter- and unarmored vehicles and against field fortification embrasures. Notable examples include the Finnish
Lahti L-39 (which was also used as a sniper rifle during the
Continuation War), the automatic Japanese
Type 97 20 mm anti-tank rifle, the German
Panzerbüchse 38,
Panzerbüchse 39, the Polish
wz.35 and the
Soviet 14.5 mm
PTRD and
PTRS-41. By 1943, most armies judged anti-tank rifles to be ineffective in combat due to their diminished ability to penetrate the thicker armor of new tanks – the British Army had abandoned them by 1942 and the Wehrmacht by 1943, while the US Army never adopted the weapon. However, the USMC used
Boys anti-tank rifles in the Pacific Theater. However, the
anti-tank rifle remained in Soviet use during the conflict due to its importance in its doctrine of anti-tank in-depth defense, first demonstrated during the defense of Moscow and again during the Kursk battles. This became particularly true later in the war, when the Red Army launched an almost constant offensive, and anti-tank, in-depth defensive deployments were used to protect the flanks of operational breakthroughs against German tactical counterattacks. By firing on the lighter armored infantry and support vehicles (e.g.,
artillery tractors) the anti-tank rifle units helped to separate the supporting infantry (
panzergrenadiers) and artillery of the German tanks and so forced the tanks to halt at short distances from the concealed anti-tank guns leaving them exposed to fire from larger, longer ranged anti-tank guns. PTRS-41 semi-automatic anti-tank rifles were also used for sniping since an additional tracer round enabled rapid fire adjustment by the gunner. Although optical sniper scopes were tried on the PTRS-41, the weapons proved too inaccurate at sniping distances (800 m or more) and had too much recoil for effective use of the scopes.
Rockets and shaped charges The development of light, man-portable, anti-tank weapons increased during the Second World War. Most were based on the
Munroe effect, which led to the development of the
high-explosive shaped charge. These weapons were called
high-explosive anti-tank (HEAT). The destructive effect relies entirely on the kinetic energy of the explosion rather than on the round's ballistic speed in inflicting damage to the armor. The effect was also concentrated and could penetrate more armor for a given amount of explosives. The first HEAT rounds were rifle grenades, but better delivery systems were soon introduced: the British
PIAT was propelled like the
spigot mortar with a blackpowder charge contained in the tailfin assembly, the US
bazooka and the German
Panzerschreck used rockets; the German
Panzerfaust was a small
recoilless gun. The HEAT warhead was retroactively used to give more power to smaller caliber weapons, such as in the conversion of the otherwise limited German 37 mm PaK guns to fire a large shell, called
Stielgranate 41, that fitted over the barrel rather than down in it, to a greater range than the
Panzerschreck could manage. The
Hungarian 44M "Buzogányvető" was a successful unguided rocket used extensively in the
Siege of Budapest. with HEAT warhead of the
German Army. After the war, research on infantry anti-tank weapons continued, with most designers focused on two primary goals: first, an anti-tank weapon capable of defeating more heavily armored postwar tanks and fighting vehicles; and second, a weapon lightweight and portable enough for infantry use.
Mines and other explosives in production • Though unsophisticated, the
satchel charge was an effective anti-tank weapon during World War II; the blast could sever the tracks of a tank, damage internal components, or injure the crew. •
Hawkins mine • The
Wehrmacht employed the
Goliath tracked mine, an unmanned demolition vehicle. • The
Soviet Union employed
anti-tank dogs during World War II, with very limited success; as a counterpart to the German Goliath, the
Teletank was used as a remote-controlled unmanned tank. • The Japanese forces employed suicide attacks with pole-mounted anti-tank mines dubbed
lunge mines during late World War II. In Vietnam, similar mines were called
bom ba càng due to the three contact points at the head of each mine.
Grenades Regular
fragmentation grenades were ineffective against tanks, so many types of anti-tank grenades were developed. These ranged from
hollow charge designs (e.g., the British
No. 68 AT Grenade) to those containing a large amount of explosive (the British
No. 73 Grenade). To increase their effectiveness, some grenades were designed to adhere to the tank either with an adhesive (
sticky bomb) or with a magnet. The Germans used a magnetic grenade, the
Hafthohlladung, to ensure that the
shaped charge would fire at the optimal 90° angle to the armor. There was also a special type of grenade called the
Nebelhandgranaten or
Blendkörper ("smoke hand grenades"), which was supposed to be smashed over an air vent to fill the tank with smoke and was widely used by both sides in
World War II.
Molotov cocktails also saw widespread use, especially in the
Winter War, with early tanks (such as the
T-26) being very vulnerable to them; later tanks required a well-thrown bottle directly over the engine compartment to have any effect at all. On the whole, thrown anti-tank weapons suffered from a variety of drawbacks. In addition to the inherently short range, they required careful aim to be effective, and those that relied on explosive force were often so powerful that the user had to take cover immediately. Additionally, with hand-thrown grenades, the requirement for the attacker to get close to the tank made the attacker exceptionally vulnerable to counterattack from the tank (typically by machine gun), or from infantry – mounted or dismounted troops – accompanying the tank. However, if the attacker were very low to the ground, and in very close proximity to the tank – for instance, or less – it might be impossible for the tank crew to see the attacker.
Tactics with a Molotov cocktail in the 1939–40
Winter War. Anti-tank tactics developed rapidly during the war, but along different paths across armies, depending on the threats they faced and the technologies they could produce. Very little development took place in the UK because weapons available in 1940 were judged adequate for engaging Italian and German tanks during most of the
North African Campaign. Its experience, therefore, failed to influence the US Army's anti-tank doctrine before 1944. From 1941, German anti-tank tactics developed rapidly after being surprised by previously unknown Soviet tank designs, prompting the introduction of new technologies and tactics. The Red Army also faced a new challenge in anti-tank warfare after losing most of its tank fleet and a considerable portion of its anti-tank-capable cannons. Anti-tank tactics during the war were largely integrated with the offensive or defensive posture of the troops being supported, usually infantry. Most anti-tank tactics depend on the effective ranges of the available weapons and weapon systems. These are divided as follows: • Operational range over the horizon (20–40 km range) • :Bomber aircraft and long-range artillery • Tactical staging areas (7–20 km range) • :Ground attack aircraft and field artillery including
MRLs • Tactical zone forming-up area and rear combat zone (2–7 km range) • :Heavy anti-tank guns and mortars • Tactical forward combat zone (1–2 km range) • :Anti-tank guns and tanks deployed in defense • Engagement distance (200–1000 m range) • :Mines and anti-tank rifles • Close combat distance (25–200 m range) • :Infantry anti-tank weapons Ground-to-air cooperation was not yet systematic in any army of the period, but, given sufficient warning, ground attack aircraft could support ground troops, even during an enemy attack, in an attempt to interdict enemy units before they entered the tactical combat zone. Various bomb loads can be used depending on the type of tank unit engaged at the time or who its accompanying troops are. This is an indirect form of anti-tank warfare in which tanks are denied the opportunity even to reach combat. Field artillery was particularly effective in firing against tank formations because, although they were rarely able to destroy a tank by direct penetration, they would severely crater the area, preventing the tanks from moving, therefore causing them to become nearly stationary targets for the ground attack aircraft, or disrupting the enemy schedule and allowing their own troops more time to prepare their defense. s deployed on the
Atlantic Wall in the vicinity of
Calais. Anti-tank defense proper was, by 1942, designed in First World War fashion, with several prepared trench lines incorporating anti-tank weapons of varying capabilities. Depending on terrain and the available line-of-sight, the longer-ranged guns could begin to fire on approaching tanks from as far as 2 kilometers, which was also the range at which German Panther and Tiger tank gunners were trained to fire. Anti-tank guns were usually deployed to cover terrain more suitable for tanks and were protected by minefields laid by combat engineers at about 500 meters to 1 kilometer from their positions. In the Red Army, anti-tank rifle units would be positioned throughout the forward trench line and would engage lighter tanks and other vehicles, such as infantry half-tracks, to separate them from the tanks. The anti-tank guns deployed further back would often hold their fire until enemy tanks were within the most effective range for their ammunition. Where there were insufficient anti-tank weapons, engineers would construct anti-tank obstacles such as
dragon's teeth or
Czech hedgehog. Towed anti-tank guns were considered the primary means of defeating tanks. At the
battle of Kursk, for example, the Red Army deployed more artillery regiments than infantry regiments, and towed gun densities reached over 20 guns per kilometer of defended tactical zone. A towed gun was much cheaper than a tank and could be concealed in a shallow position. When time allowed, dugouts with strong overhead cover could be constructed. Guns deployed on reverse slopes and in flanking positions could take a toll on attacking tanks. However, gun crews were vulnerable to artillery, mortar HE fire, and enemy infantry. Their positions had to be carefully selected, and once engaged, they generally could not redeploy. Experience strongly suggested that towed AT guns were less effective than self-propelled AT weapons and took heavier casualties. The tactic of ambushing enemy armor at grazing shot distances was perfected during World War 2. Some combatants, such as the Soviet Red Army, doctrinally applied it to engage heavy German armor at optimal ranges and angles. Self-propelled anti-tank guns were rare at the beginning of WW2, although the
Belgian Army deployed a few T.15 tank destroyers and the French Army was developing several wheeled and tracked designs. The advantages of mobility and even thin armor protection were so compelling that most armies were using self-propelled AT guns by mid-war. Examples of these weapons included the US
M10 GMC, German
Jagdpanzer IV, and Soviet
SU-85.
Infantry close assault , 1945. The tank is still vulnerable to infantry, especially in close country or built-up areas. Rough terrain may expose the floor armor, and high ground, such as multi-story buildings, may expose the top armor. Their large size and loud noise can allow enemy infantry to spot, track, and evade tanks until an opportunity presents itself for counterattack. Because tank crews have limited visibility from inside the tank, infantry can get close to a tank, given enough concealment and closed hatches. If tank crew members unbutton for better visibility, they become vulnerable to small arms fire, grenades, and Molotov cocktails. A foot soldier cannot be targeted by a tank's main gun when close, as it cannot depress sufficiently. Close-defense weapons such as pistol ports, hull-mounted, coaxial, and pintle-mounted machine guns, however, gave them some protection. Whilst many handheld infantry anti-tank weapons will not penetrate the front armor of a tank, they may penetrate the less heavily armored top, rear, and sides. Anti-tank weapons can damage the tracks or running gear to inflict a
mobility kill. Early WWII tanks had open vision slits that could be fired through to harm the crew. Later tanks' slits had thick glass, sights, and periscopes that could still be damaged by powerful small arms such as
anti-tank rifles and
heavy machine guns, hampering the crew. If all else fails, the hatch could be forced open and grenades thrown inside, although later tank designs often have hatches that are difficult to open from the outside. Tanks were also vulnerable to hand-placed anti-tank mines. Infantry have even immobilized tanks using a set of plates covered with leaves and dirt as dummy mines – the ruse being augmented by the crew's obscured vision – infantry can then attack the stopped tank. This tactic was taught to the
British Home Guard during World War II, as they were rarely provided with long-range anti-tank weapons. In the Japanese Army, the use of satchel charges and pole charges was widespread. Although the charges could knock out any allied tank, the tactic was extremely close-range, and the sappers were vulnerable to allied weapons.
Suicide bombing . Chinese troops in the
Second Sino-Japanese War used
suicide bombing against Japanese tanks. Chinese troops
strapped explosives like grenade packs or dynamite to their bodies and threw themselves under Japanese tanks to blow them up. This tactic was used during the
Battle of Shanghai, where a Chinese suicide bomber stopped a Japanese tank column by exploding himself beneath the lead tank, and at the
Battle of Taierzhuang where dynamite and grenades were strapped on by Chinese troops who rushed at Japanese tanks and blew themselves up. During one incident at Taierzhuang, Chinese suicide bombers obliterated four Japanese tanks with grenade bundles. South Koreans attacked North Korean tanks with suicide tactics during the North Korean invasion of the South. North Korean suicide squads attacked American tanks at Seoul, who used satchel charges. A North Korean soldier who exploded an American tank with a suicide bomb named Li Su-Bok is hailed as a hero in North Korean propaganda. During the
Iran–Iraq War, the Iranian
Mohammad Hossein Fahmideh blew himself up under an Iraqi tank with a grenade. According to the Sudanese writer Mansour Al-Hadj, Sudanese jihadists were trained to attack enemy tanks by suicide bombing them. ==Korean War==