He

Mussolini with Hitler.

On June 10, 1940, as the Germans under General Guderian reached the English Channel, Mussolini declared war on Britain and France. In October, Italy attacked Greece in what is generally seen as a failure. In June 1941, he declared war on the Soviet Union and in December he declared war on the United States.

See also: Italian military history of World War II

Following Italian defeats on all fronts and the Anglo-American landing in Sicily in 1943, most of Mussolini's colleagues (Count Galeazzo Ciano, the foreign minister and also Mussolini's son-in-law, included) turned against him at a meeting of the Fascist Grand Council on July 25, 1943. This enabled the king to dismiss and arrest him.

He was then sent to Gran Sasso, a mountain recovery in central Italy (Abruzzo), in complete isolation.

Mussolini was substituted by the Maresciallo d'Italia Gen. Pietro Badoglio, who immediately declared in a famous speech "La guerra continua a fianco dell'Alleato Germanico" ("War continues at the side of our German allies"), but was instead working to negotiate a surrender; in a few days (September the 8th) Badoglio would sign an armistice with allied troops.

Rescued by the Germans several months later in a spectacular raid by Otto Skorzeny, Mussolini set up a Republican Fascist state (RSI, Repubblica Sociale Italiana) in northern Italy with him living in Gargnano. But he was little more than a puppet under the protection of the German Army. In this "Republic of Salo'", Mussolini returned to his earlier ideas of socialism and collectivization. He also executed some of the Fascist leaders who had abandoned him, including his son-in-law, Galeazzo Ciano.

During this period he wrote his memoirs entitled My Rise and Fall.

On April 28, 1945, just before the Allied armies reached Milan, Mussolini, along with his mistress Claretta Petacci, was caught by Italian partisans as he headed for Chiavenna to board a plane for escape to Switzerland. They were both shot on the spot along with their sixteen-man escort. The next day the bodies were hung in Piazzale Loreto (Milan) along with those of other fascists to be abused by the crowds. Mussolini's body was then taken to Predappio and the family chapel.

The Duce was survived by his wife, Donna Rachele, by two sons, Vittorio and Romano Mussolini, and his daughter Edda, the widow of Count Ciano. A third son, Bruno, had been killed in an air accident while testing a military plane.

Mussolini's granddaughter Alessandra, daughter of Romano Mussolini, is currently a deputy in the Republican Chamber representing the Alleanza Nazionale party for Naples.

• "Fascism should more properly be called corporatism, since it is the merger of state and corporate power"

• "Socialism is a fraud, a comedy, a phantom, a blackmail."

• "It's good to trust others but, not to do so is much better."

See also

Classifications

• Low Explosives (Burns through deflagration rather than detonation wave, are usually a mixture, are initiated by heat and require confinement to create an explosion) and
• High Explosives (supersonic reaction, thus will explode without confinement, are compounds, initiated by shock or heat, high brisance). "Brisance" means the shattering effect of an explosion.

dynamite : nitroglycerin mixed into a paste with powdered silica, which acts as a stabilizer.

RDX, PETN : very strong explosives which can be used pure.

TNT

C-4: plastic explosive. Adhesive properties.

Classification by sensitivity of the material

Primary Explosives

They are extremely sensitive and require a small quantity of energy to be initiated. They are mainly used in detonators to initiate secondary explosives (Examples: tetryl, Lead azide, Mercury fulminate, lead styphnate, tetrazene, hexanitromannitol).

Secondary Explosives

They are relatively insensitive and need a great amount of energy to initiate decomposition. They have much more power than primary explosives and are used in demolition. The require a detonator to explode. (Examples: Dynamite, TNT, RDX, PETN, HMX, ammonium nitrate, tetryl, picric acid, nitrocellulose, gelignite)

• Formation of gases
• Evolution of heat
• Rapidity of reaction
• Initiation of reaction

Formation of Gases

Gases may be evolved from substances in a variety of ways. When wood or coal is burned in the atmosphere, the carbon and hydrogen in the fuel combine with the oxygen in the atmosphere to form carbon dioxide and steam, together with flame and smoke. When the wood or coal is pulverized, so that the total surface in contact with the oxygen is increased, and burned in a furnace or forge where more air can be supplied, the burning can be made more rapid and the combustion more complete. When the wood or coal is immersed in liquid oxygen or suspended in air in the form of dust, the burning takes place with explosive violence. In each case, the same action occurs: a burning combustible forms a gas.

Characteristics Of Military Explosives

To determine the suitability of an explosive substance for military use, its physical properties must first be investigated. The usefulness of a military explosive can only be appreciated when these properties and the factors affecting them are fully understood. Many explosives have been studied in past years to determine their suitability for military use and most have been found wanting. Several of those found acceptable have displayed certain characteristics that are considered undesirable and, therefore, limit their usefulness in military applications. The requirements of a military explosive are stringent, and very few explosives display all of the characteristics necessary to make them acceptable for military standardization. Some of the more important characteristics are discussed below:

Power

The term power (or more properly, performance) as it is applied to an explosive refers to its ability to do work. In practice it is defined as its ability to accomplish what is intended in the way of energy delivery (i.e., fragments, air blast, high-velocity jets, underwater bubble energy, etc.). Explosive power or performance is evaluated by a tailored series of tests to assess the material for its intended use. Of the test listed below, cylinder expansion and air-blast tests are common to most testing programs, and the others support specific uses.

• Cylinder expansion test--A standard amount of explosive is loaded in a cylinder usually manufactured of copper. Data is collected concerning the rate of radial expansion of the cylinder and maximum cylinder wall velocity. This also establishes the Gurney constant or 2E.
• Cylinder fragmentation test--A standard steel cylinder is charged with explosive and fired in a sawdust pit. The fragments are collected and the size distribution analyzed.
• Detonation pressure (Chapman-Jouget)--Detonation pressure data derived from measurements of shock waves transmitted into water by the detonation of cylindrical explosive charges of a standard size.
• Determination of critical diameter--This test establishes the minimum physical size a charge of a specific explosive must be to sustain its own detonation wave. The procedure involves the detonation of a series of charges of different diameters until difficulty in detonation wave propagation is observed.
• Infinite diameter detonation velocity--Detonation velocity is dependent on landing density (c), charge diameter, and grain size. The hydrodynamic theory of detonation used in predicting explosive phenomena does not include diameter of the charge, and therefore a detonation velocity, for an imaginary charge of infinite diameter. This procedure requires a series of charges of the same density and physical structure, but different diameters, to be fired and the resulting detonation velocities interpolated to predict the detonation velocity of a charge of infinite diameter.
• Pressure versus scaled distance--A charge of specific size is detonated and its pressure effects measured at a standard distance. The values obtained are compared with that for TNT.
• Impulse versus scaled distance--A charge of specific size is detonated and its impulse (the area under the pressure-time curve) measured versus distance. The results are tabulated and expressed in TNT equivalent.
• Relative bubble energy (RBE)--A 5- to 50-kg charge is detonated in water and piezoelectric gauges are used to measure peak pressure, time constant, impulse, and energy.

Kx 3

RBE = Ks

where K = bubble expansion period for experimental (x) or standard (s) charge.

Oxygen Balance (OB%)

Oxygen balance is an expression that is used to indicate the degree to which an explosive can be oxidized. If an explosive molecule contains just enough oxygen to convert all of its carbon to carbon dioxide, all of its hydrogen to water, and all of its metal to metal oxide with no excess, the molecule is said to have a zero oxygen balance. The molecule is said to have a positive oxygen balance if it contains more oxygen than is needed and a negative oxygen balance if it contains less oxygen than is needed. The sensitivity, strength, and brisance of an explosive are all somewhat dependent upon oxygen balance and tend to approach their maximums as oxygen balance approaches zero.

The oxygen balance (OB) is calculated from the empirical formula of a compound in percentage of oxygen required for complete conversion of carbon to carbon dioxide, hydrogen to water, and metal to metal oxide.

The procedure for calculating oxygen balance in terms of 100 grams of the explosive material is to determine the number of gram atoms of oxygen that are excess or deficient for 100 grams of a compound.

- 1600 Y

OB (%) = Mol. Wt. of Compound 2X + 2 + M - Z

where

X = number of atoms of carbon, Y = number of atoms of hydrogen, Z = number of atoms of oxygen, and M = number of atoms of metal (metallic oxide produced).

In the case of TNT (C₆H₂(NO₂)₃CH₃),

Molecular weight = 227.1

X = 7 (number of carbon atoms)

Y = 5 (number of hydrogen atoms)

Z = 6 (number of oxygen atoms)

Therefore

OB (%) = -1600 [14 + 2.5 - 6]

227.1 = - 74% for TNT

Because sensitivity, brisance, and strength are properties resulting from a complex explosive chemical reaction, a simple relationship such as oxygen balance cannot be depended upon to yield universally consistent results. When using oxygen balance to predict properties of one explosive relative to another, it is to be expected that one with an oxygen balance closer to zero will be the more brisant, powerful, and sensitive; however, many exceptions to this rule do exist. More complicated predictive calculations, such as those discussed in the next section, result in more accurate predictions.

One area in which oxygen balance can be applied is in the processing of mixtures of explosives. The family of explosives called amatols are mixtures of ammonium nitrate and TNT. Ammonium nitrate has an oxygen balance of +20% and TNT has an oxygen balance of -74%, so it would appear that the mixture yielding an oxygen balance of zero would also result in the best explosive properties. In actual practice a mixture of 80% ammonium nitrate and 20% TNT by weight yields an oxygen balance of +1%, the best properties of all mixtures, and an increase in strength of 30% over TNT.

TNT:C₆H₂(NO₂)₃CH₃; constituents: 7C + 5H + 3N + 6O

7C + 6O → 6CO with one mol of carbon remaining

3N → 1.5N₂

The balanced equation, showing the products of reaction resulting from the detonation of TNT is:

C₆H₂(NO₂)₃CH₃ → 6CO + 2.5H₂ + 1.5N₂ + C

Based upon this simple beginning, it can be seen that the volume of the products of explosion can be predicted for any quantity of the explosive. Further, by employing Charles' Law for perfect gases, the volume of the products of explosion may also be calculated for any given temperature. This law states that at a constant pressure a perfect gas expands 1/273 of its volume at 0°C, for each degree of rise in temperature.

Therefore, at 15°C the molecular volume of any gas is,

V15 = 22.4 (1 + 15/273) = 23.63 liters per mol

V = 23.63 l (7.25 mol) = 171.3 liters/mol

Potential and Relative Strength of the Explosive

The potential of an explosive is the total work that can be performed by the gas resulting from its explosion, when expanded adiabatically from its original volume, until its pressure is reduced to atmospheric pressure and its temperature to 15°C. The potential is therefore the total quantity of heat given off at constant volume when expressed in equivalent work units and is a measure of the strength of the explosive.

An explosion may occur under two general conditions: the first, unconfined, as in the open air where the pressure (atmospheric) is constant; the second, confined, as in a closed chamber where the volume is constant. The same amount of heat energy is liberated in each case, but in the unconfined explosion, a certain amount is used as work energy in pushing back the surrounding air, and therefore is lost as heat. In a confined explosion, where the explosive volume is small (such as occurs in the powder chamber of a firearm), practically all the heat of explosion is conserved as useful energy. If the quantity of heat liberated at constant volume under adiabatic conditions is calculated and converted from heat units to equivalent work units, the potential or capacity for work results.

Therefore, if

Qmp represents the total quantity of heat given off by a gram molecule of explosive of 15°C and constant pressure (atmospheric);

Qmv represents the total heat given off by a gram molecule of explosive at 15°C and constant volume;and

W represents the work energy expended in pushing back the surrounding air in an unconfined explosion and thus is not available as net theoretical heat;

Then, because of the conversion of energy to work in the constant pressure case,

Qmv = Qmp + W

Using the principle of the initial and final state, and heat of formation table (resulting from experimental data), the heat released at constant pressure may be readily calculated.

m n

Qmp = viQfi - vkQfk

1 1

where:

Qfi = heat of formation of product i at constant pressure

Qfk = heat of formation of reactant k at constant pressure

v = number of mols of each product/reactants (m is the number of products and n the number of reactants)

The work energy expended by the gaseous products of detonation is expressed by:

W = Pdv

W = PV₂

W = 10.132 × 10⁴ N )(23.63 l )(Nmol)

m2 mol

and by applying the appropriate conversion factors, work is determined in units of kcal/mol.

W = (10.132 × 10⁴ N)(23.63 l )(Nmol)(10-3m3

m2 mol l

Joules 1 Kcal

Newton-meter 4185 Joules

Consolidating terms:

W = (.572)(Nmol) Kcal mol

Once the chemical reaction has been balanced, one can calculate the volume of gas produced and the work of expansion. With this completed, the calculations necessary to determine potential may be accomplished.

For TNT:

C₆H₂(NO₂)₃CH₃ → 6CO + 2.5H₂ + 1.5N₂ + C

Then:

Qmp = 6(26.43) (+16.5) = 142.08 Kcal mol

Qmv = 142.08 + .572(10) = 147.8 Kcal mol

Potential = Qmv Kcal 4185 J 103g 1mol

mol Kcal Kg MW gm

Potential = Qmv (4.185 × 10⁶) Joules

MW Kg

For TNT,

Potential = 147.8 (4.185 × 10⁶) = 2.72 × 10⁶ J

227.1 Kg

Rather than tabulate such large numbers, in the field of explosives, TNT is taken as the standard explosive, and others are assigned strengths relative to that of TNT. The potential of TNT has been calculated above to be 2.72 × 10⁶ Joules/kg. Relative strength (RS) may be expressed as

R.S. = Potential of Explosive/(2.72 × 10⁶)

Example of Thermochemical Calculations

The PETN reaction will be examined as an example of thermo-chemical calculations.

PETN: C(CH₂ONO₂)₄

MW = 316.15 Heat of Formation = 119.4 Kcal/mol

5C + 12O → 5CO + 7O

8H + 7O → 4H₂O + 3O

5CO + 3O → 2CO + 3CO₂

4N → 2N₂

C(CH₂ONO₂)₄ → 2CO + 4H₂O + 3CO₂ + 2N₂

Nm = 2 + 4 + 3 + 2 = 11 mol-volume/mol

The heat liberated at constant volume (Qmv) is equivalent to the liberated at constant pressure (Qmp) plus that heat converted to work in expanding the surrounding medium. Hence, Qmv = Qmp + Work (converted).

a. Qmp = Qfi (products) - Qfk (reactants)

For the PETN reaction:

Qmp = 2(26.43) + 4(57.81) + 3(94.39) - (119.4) = 447.87 Kcal/mol

b. Work = .572(Nm) = .572(11) = 6.292 Kcal/mol

c. Potential J = Qmv (4.185 × 10⁶

Kg MW = 454.16 (4.185 × 10⁶)

316.15 = 6.01 × 10⁶ J

Kg

This product may then be used to find the relative strength of PETN, which is

e. RS = Pot (PETN = 6.01 × 10⁶ = 2.21 Pot (TNT) 2.72 × 10⁶

References/Bibliography

Army Research Office. Elements of Armament Engineering (Part One). Washington, D.C.: U.S. Army Material Command, 1964.

Commander, Naval Ordnance Systems Command. Safety and Performance Tests for Qualification of Explosives. NAVORD OD 44811. Washington, D.C.: GPO, 1972.

Commander, Naval Ordnance Systems Command. Weapons Systems Fundamentals. NAVORD OP 3000, vol. 2, 1st Rev. Washington, D.C.: GPO, 1971.

Departments of the Army and Air Force. Military Explosives. Washington, D.C.: 1967.

• Explosives used during WW II
• shaped charge
• weapon
• nuclear weapon

External links:

Under standard temperature and pressure helium exists only as a monatomic gas. Helium condenses only under very extreme conditions.

It has the lowest melting point of any element and is the only liquid that can't be solidified by lowering its temperature; remaining liquid all the way to absolute zero at standard pressure (it can only be solidified by increasing the pressure). In fact, the critical temperature, above which there is no difference between the liquid and gaseous phases, is only 5.19 K. Solid He-3 and He-4 are unique in that by applying pressure a researcher can change their volumes by more than 30%. The specific heat capacity of helium gas is very high and helium vapor is very dense, expanding rapidly when it is warmed to room temperature.

Solid helium only exists at great pressures, around 100 MPa at 15 K, and at roughly this temperature helium undergoes a transition between high temperature and low temperature forms, in which the atoms have cubic and hexagonal close packings, respectively. At a fraction of the temperature and pressure a third form occurs where the atoms have a body-centered cubic arrangement. All these arrangements are fairly similar in energy and density, and the reasons for the changes have to do with the details of how the atoms interact.

It is often used as a lifting gas in lighter-than-air vessels which in turn are used for advertising, atmospheric research, military reconnaissance and as a novelty. In addition, helium has 92.64% of the lifting power of hydrogen but is not flammable and is therefore considered safer. Other uses;

• Helium-oxygen atmospheres are used in high-pressure breathing work such as deep diving suits or submersibles because helium is inert, less soluble in blood than nitrogen, and diffuses 2.5 times faster than nitrogen. This reduces the time required for degassing on decompression, eliminates the danger of nitrogen narcosis, and is less likely to collect as bubbles in joints.
• It has the lowest melting and boiling points of any element which makes liquid helium an ideal coolant for many extremely low-temperature applications such as superconducting magnets and cryogenic research where temperatures close to absolute zero are needed.
• Helium is also used as an inert carrier gas, such as in gas chromatography.
• The fusion of hydrogen into helium provides the energy needed for the hydrogen bomb.
• It is also used for; pressuring liquid fuel rockets, as an inert gas shield for arc welding, as a protective gas for growing silicon and germanium crystals, as a cooling agent for nuclear reactors, and as a gas for supersonic wind tunnels.

Helium (Greek helios meaning "the sun") was discovered by Frenchman Pierre Janssen and Englishman Norman Lockyer working independently of each other in 1868. Both men were studying light from the sun during a solar eclipse that year and spectroscopically found an emission line of a previously unknown element. Eduard Frankland confirmed Janssen's findings and also proposed that the element should named after Helios, the Greek god of the sun, with the added suffix -ium because the new element was expected to be a metal. It was isolated by Sir William Ramsay in 1895, from clevite and conclusively found to not be a metal, but the name was unchanged. Swedish chemists Nils Langlet and Per Theodor Cleve, working independently of Ramsay, also were able to isolate helium from clevite at about the same time.

In 1907 Ernest Rutherford and Thomas Royds were able to show that alpha particles are helium nuclei. In 1908 Dutch physicist Heike Kamerlingh Onnes produced the first liquid helium by cooling the gas to 0.9°K, a feat that earned him a Nobel Prize. In 1926 his student Willem Hendrik Keesom was the first person to solidify helium.

Helium is the second most abundant element in the universe after hydrogen and forms about 20 percent of the matter in stars. It is also plays an important role in both the proton-proton reaction and the carbon cycle in stars which accounts for much of their energy. The abundance of helium is far too large to be explained by production by stars, but is consistent with the big bang model, and the vast majority of helium in the universe is believed to have been formed in the first three minutes of the universe.

This element is also present in earth's atmosphere at about 1 part in 200,000 and is found as a decay product in various radioactive minerals. Specifically, it is found in minerals of uranium and thorium, such as clevites, pitchblende, carnotite, monazite and beryl; it is produced from these elements by radioactive decay in the form of alpha particles. It is also found in some mineral waters (1 part helium per thousand water in some Iceland springs), in volcanic gases, and in certain natural gas deposits in the United States (from which most of the commercial helium on Earth is derived). Helium can be synthesized by bombardment of lithium or boron by high-velocity protons.

Helium is the first of the noble gases and is chemically unreactive for practical purposes but under the influence of electric glow discharge or electron bombardment helium does form compounds with tungsten, iodine, fluorine, sulfur and phosphorus.

The most common isotope of helium is He-4, where the nucleus has two protons and two neutrons. This is an unusually stable nuclear arrangement since it has a magic number of nucleons, that is, a number where they are arranged into complete shells. Many heavier nuclei decay by the emission of He-4 nuclei, a process called alpha decay, and helium nuclei are thus called alpha particles. Most of the helium on earth is generated by this process. Helium has a second isotope, helium-3, where the nucleus only has a single neutron, as well as several heavier isotopes that are radioactive. Helium-3 is virtually unknown on the Earth's surface, as the internal sources of helium only produce the He-4 isotope as alpha particles and atmospheric helium escapes into space over relatively short geological timescales.

Liquid helium (He-4) is found in two forms: He-4 I and He-4 II, which share a sharp transition point at 2.1768 K at its vapor pressure. He-4 I (above this point) is a normal liquid, but He-4-II (below this temperature) is unlike any other known substance.

As it is cooled past 2.1768 K at its vapor pressure, the so-called lambda point, it becomes a superfluid known as liquid Helium II (as opposed to "normal" liquid Helium I) which has many unusual characteristics due to quantum effects; it was one of the first observed examples of quantum effects operating on a macroscopic scale. This transition takes place at much lower temperatures in Helium-3 than it does in Helium-4, as the effect relies on condensation of bosons but the nuclei of the former are fermions, which can't condense individually but must do so in bosonic pairs. Since the transformation is one of higher order, without latent heat at the lambda point, the two liquid forms never coexist.

Helium II has zero viscosity and has a heat conductivity much higher than any other substance. Furthermore, helium II exhibits a thermomechanical (fountain) effect; if two vessels containing helium II are connected by a narrow capillary and one of the two is heated a flow of helium toward the heated vessel will occur. Conversely, in the mechanocaloric effect, a forced flow of helium II through a capillary will result in cooling of the helium II leaving the capillary. Pulses of heat introduced into helium II will propagate through the liquid in the same manner as the density pulses of sound, a phenomenon which has been dubbed "second sound." Solid surfaces in contact with helium II are covered with a film 50 to 100 atoms thick, along which frictionless flow of the liquid can occur; as a result it is impossible to contain helium II in an open vessel without it flowing out over the edge. Mass transport through the helium II film takes place at a constant rate which only depends on temperature. Finally, a mass of helium II will not rotate as a unit; instead, attempts to set it rotating will induce small frictionless vortices throughout the liquid.

Containers filled with gaseous helium at 5 to 10 K should be stored as if they contained liquid helium due to the large increase in pressure that results from warming the gas to room temperature.

Further Reading

Hea-Hec

• Head, Edith, (1907-1981), costumer
• Headon, Topper, (born 1955), musician ("The Clash")
• Headrick, Ed, (died 2002), developer of the Frisbee
• Heald, Anthony, (born 1944), actor.
• Healey, Jeff, blind guitar virtuoso and singer
• Healy, Dermot, Aosdána
• Healy, Tim, (1855-1931)
• Heaney, Seamus, (born 1939), Saoi of Aosdána
• Heap, Jimmy, musician
• Heard, J.C, musician
• Heard, John, (born 1945), actor
• Hearn, Chick, (1916-2002), pro-basketball announcer
• Hearnes, Warren E, US governor
• Hearn, Lafcadio, (1850-1904), American chronicler of Japanese tales
• Hearn, Richard, comedian
• Hearns, Thomas, (born 1958), world champion boxer
• Hearst, Patricia, (born 1954), one-time member of Symbionese Liberation Army
• Hearst, William Randolph, (1863-1951), newspaper magnate
• Heartfield, John, (1891-1968)
• Heath, Albert 'Tootie', musician
• Heath, Edward, (born 1916), politician
• Heath, Lady Mary, early aviator
• Heath-Stubbs, John, poet
• Heath, Thomas, (1861-1940), mathematician
• Heatter, Gabriel, (1890-1972), journalist
• Heaviside, Oliver, (1850-1925), physicist
• Heatwole, Nathaniel (born 1983), suspected airplane attacker
• Hebbel, Friedrich, dramatist, author
• Hébert, Anne, Acadian author, educator Kamouraska
• Heche, Anne, actress
• Hecht, Anthony, poet
• Hecht, Ben, (1894-1964), playwright, screenwriter
• Hechter, Daniel, inventor of ready-to-wear
• Heckerling, Amy, (born 1954), director
• Heckman, James, economist

Hed-Hel

• Hedayat, Sadeq, author
• Hedberg, Mitch, comedian, stand-up comedian
• Hedin, Sven, (1865-1952), explorer
• Hedningarna, musician
• Hedren, Tippi, (born 1931), US actress
• Heeney, Tom, boxer
• Heeremann, Constantin Freiheer von, (born 1931), president of Germany's National Farmers' Union
• Heer, Joachim, (1825-1879), Swiss president
• Heerup, Henry, (1907-1993), Danish painter
• Hee Seop Choi, (MLB Player)
• Heesters, Johannes, (born 1903), singer and actor
• Heflin, Van, (1910-1971), actor
• Hefner, Hugh, (born 1926), US founder of Playboy magazine
• Hegamin, Lucille, (1894-1970), musician
• Hegel, Georg, (1770-1831), philosopher
• Hegley, John, also performs as half of the "Popticians"
• Heidegger, Martin, (1889-1976), German philosopher
• Heiden, Eric, (born 1958), Olympic speed skater
• Heidenreich, Elke, (born 1943), journalist and writer
• Heidenstam, Verner von, (1859-1940), Swedish writer
• Heidt, Horace, (1901-1986), band leader
• Heifetz, Jascha, (1901-1987), musician
• Heihachiro, Togo, (1846-1934)
• Heijden, A.F.Th. van der, novelist
• Heilwig, Martin, (1516-1574), cartographer
• Hein, Christoph, dramatist, author
• Heine, Alice, (1858-1925), first American Princess of Monaco
• Heine, Heinrich, (1797-1856), poet
• Heineken, Freddy, (1923-2002), Dutch businessman
• Heinemann, Gustav, (1899 - 1976), German government minister
• Heinkel, Ernst, aerospace engineer
• Heinlein, Robert A, (1907-1988), U.S. Science fiction author
• Hein, Piet (Denmark), (1905-1996)
• Hein, Piet (Netherlands), (1577-1629), naval officer
• Heintzleman, Benjamin Franklin, (Rep.) 1953-1957
• Heinz, Henry, (1844-1916), food manufacturer
• Heisenberg, Werner Karl, (1901-1976), German quantum physicist
• Heiss, Carol, (born 1940), Olympic figure skating gold medalist
• Heisterkamp, Peter, (1943-1977), aka Palermo, artist
• Heizei, emperor of Japan
• Hekmatyar, Gulbuddin, (born 1947)
• Helena, Princess of the United Kingdom, (1846-1923), third daughter of Queen Victoria, aunt of [[George V of the Unite
• Helias, Mark
• Helias, Peter, scholastic philosopher
• Heliogabalus, (203-222), Roman Emperor
• Hellendaal, Pieter, (1721-1799), composer
• Heller, Andre, (born 1946), artist
• Heller, Joseph, (1923-1999), US author
• Heller, Keith, author
• Hellman, Lillian, (1905-1984), US playwright and political activist
• Hellman, Monte, film director
• Hell, Richard, (born 1949), songwriter
• Hell, Rudolf, (1901-2002), inventor
• Helm, Brigitte, (1908-1996), actress
• Helmholtz, Hermann von, (1821-1894), physicist
• Helm, Levon, (born 1942), musician ("The Band)"
• Helms, Jesse, (born 1921), Senator from North Carolina
• Helmsley, Harry, (1909-1997), real estate entrepreneur
• Helms, Richard, (1913-2002), director of the Central Intelligence Agency
• Helms, Susan, astronaut
• Heloise, (born 1951), newspaper columnist
• Helou, John, Maronite Patriarch

Hem

• Hemans, Felicia, (1793-1835), poet
• Hemingway, Ernest, (1899-1961), American novelist
• Hémon, Louis, (1880-1913), novelist and journalist, Maria Chapdelaine
• Hempel, Carl Gustav, philosopher
• Hemphill, Essex, poet
• Hemsley, Sherman, (born 1938), comedian, actor

Hen

Hend-Henq

• Henderson, Fletcher, band leader, orchestrator, pianist
• Henderson, Florence, (born 1934), actress
• Henderson, Hamish, folk song collector and writer
• Henderson, J. Pinckney, (1846-1847), American Governor of Texas
• Henderson, J. W, (1853-1853), American Governor of Texas
• Henderson, Paul, scored winning goal in 1972 Canada/Russia match
• Henderson, Rickey, (born 1958), baseball player
• Henderson, Scott, musician
• Henderson, Skitch, (born 1918), musician, band leader
• Henderson, Thomas, (1798-1844), astronomer
• Henderson, Zenna, US science fiction author
• Hendrickson, Waino Edward, (Rep.) 1958-1959
• Hendricks, Thomas A, (1819-1885), former Vice President of the United States
• Hendricks, Tyler, former President of US church, now president of Unification Theological Seminary
• Hendrix, Jimi, (1942-1970), US singer
• Hengest, King of Kent
• Henie, Sonja, (1912-1969), US figure skater and movie star
• Henin-Hardenne, Justine, (born 1982), (Belgium)
• Henisch, Peter, novelist
• Henize, Karl, astronaut
• Henkel, Heinrich, dramatist, author
• Henlein, Konrad, Sudeten German politician
• Henley, Don, (born 1947), singer-songwriter
• Henley, John, (1692-1759), 'Orator'
• Henley, William Ernest, (1849-1903), poet
• Henman, Tim, tennis player
• Hennen, Thomas, astronaut
• Hennessy, Jillian, actress, Law & Order

Henr

• Henreid, Paul, (died 1992), actor
• Henri, Adrian, poet
• Henricks, Terence, astronaut
• Henri, Robert, (1865-1929), American painter

Henry

• Henry, Beulah Louise, nicknamed lady Edison
• Henry, Buck, (born 1930), actor, comedian, writer, director, producer
• Henry, Frogman, singer & musician
• Henry I , Duke of Brabant, (1165-1235)
• Henry I, Duke of Poland, (1232-1238), Polish ruler
• Henry II, Duke of Poland, (1238-1241), Polish ruler
• Henry II, Holy Roman Emperor, (972-1024), king 1002, emperor 1014-1024
• Henry III, Holy Roman Emperor, (1017-1056), king 1039, emperor 1046-1056
• Henry III of Castile, the Infirm 1390-1406
• Henry III of England, (1207-1272), English monarch
• Henry III of France, (1551-1589)
• Henry II of Castile, the Bastard 1369-1379
• Henry II of England, (1133-1189), English monarch
• Henry II of France, (1519-1559)
• Henry II of Navarre, (died 1555)
• Henry I of Castile, Castilian monarch
• Henry I of England, (1068-1135), English monarch
• Henry I of France, (1008-1060)
• Henry IV, Duke of Poland, (1288-1290), Polish ruler
• Henry IV, Holy Roman Emperor, (1050-1093), king 1056, emperor 1084-1106
• Henry IV of England, (1367-1413), English monarch
• Henry IV of France, (1553-1610)
• Henry, John (senator), (1750-1798), US governor
• Henry, Joseph, (1797-1878), physicist
• Henryk II Walezy, (1572-1573), Polish ruler
• Henry, Lenny, (born 1958), British comedian
• Henry, Marguirite, author of King of the Wild, Misty of Chincoteague
• Henry, O, (1862-1910), author
• Henry of Flanders, (died 1216), emperor of the Latin Empire (poisoned)
• Henry of Ghent, scholastic philosopher
• Henry of Harclay, scholastic philosopher
• Henry of Langenstein, scholastic philosopher
• Henry of Portugal, Cardinal, (1578-1580), Portuguese monarch
• Henry, Patrick, (1736-1799), US politician
• Henry, Pierre, writer of musique concrete and electronic music
• Henry, Prince, Duke of Gloucester, (died 1974)
• Henry , Prince of Wales, (born 1594), the eldest son of King James VI of Scotland/James I of England and Anne of Denmark.
• Henry the Fowler, (876-936), king 919-936
• Henry the Navigator, (1394-1460), Portuguese prince and patron of African exploration
• Henry, Thierry, (born 1977), athlete
• Henry V, Holy Roman Emperor, (1081-1125), king 1106, emperor 1111-1125
• Henry VI, Holy Roman Emperor, (1165-1197), king 1190, emperor 1191-1197
• Henry VII, Holy Roman Emperor, (ca. 1275-1313), king 1309, emperor 1311-1313
• Henry VIII, (1491-1547), king of England
• Henry VIII of England, (1491-1547), separated English Catholicism from link with the Roman Catholic Church
• Henry VII of England, (1457-1509), English monarch
• Henry VI of England, (1421-1471), English monarch
• Henry V of England, (1387-1422), English monarch

Hens-Henz

• Hensel, Luise, (1798-1876), poet
• Hensley, Ken, (born 1945), rock musician (Uriah Heep)
• Henson, Jim, (1936-1990), US Muppet master
• Henson, Josiah, (1789-1883), ex-slave, settlement founder
• Henson, Matthew, (born 1866), explorer (North Pole)
• Henstridge, Natasha, (born 1974), US model and actress
• Henty, George, (1832-1902), author of more than 80 popular books for boys
• Henze, Hans Werner, composer

Hep

• Hepburn, Audrey, (1929-1993), Belgian-born actress
• Hepburn, Katharine, (1907-2003), US actress
• Heppner, Ben, operatic tenor
• Hepworth, Barbara, (1903-1975), sculptor

Her