At a time when the existence of molecules was still held in doubt by at least some respectable scientists, Johannes Diderik van der W aals developed a model of molecular interactions. His equation of state had the basic features needed for the understanding of a great variety of phenomena occurring in fluids and fluid mixtures. He received the Nobel Prize in 1910. He is considered the founder of molecular science. V a n der W aals was born in Leiden, Netherlands, the son of a carpenter and the eldest of ten children. After finishing middle school at the age of fifteen, he started working as an apprentice elementary school teacher . For over 20 years, van der W aals climbed through the teachers ranks by taking evening classes and, eventually , university courses. After repairing the deficiencies of his early schooling, he was allowed to defend his Ph.D. thesis in 1873. He was a Professor of Physics at the University of Amsterdam, Netherlands, from 1877 to 1908. . V an der W aals considered the molecules as hard spheres surrounded by a sphere of attraction. W ith this model, he could describe the properties of both gases and liquids. A liquid and its vapour are separated by an interface, and the liquid is much denser than the vapour . V an der W aals showed, however , that only below its critical point may a gas be liquefied. Above this point, the transition from vapour -like to liquid-like densities is continuous, without the appearance of an interface. By expressing fluid properties in terms of the critical- point parameters, V a n der W aals obtained the law of corresponding states which maps properties from one fluid to another . This law allowed him to predict the critical point of helium, which, in turn, enabled his friend, Heike Kamerlingh Onnes, to liquefy helium in Leiden in 1908. The thesis was immediately r ecognised as very significant: James Clerk Maxwell learned Dutch in order to r ead it Another major achievement of V a n der W aals was the 1890 generalisation of the law of corresponding states to fluid mixtures of two and more components. Depending on the nature of the components, mixtures may display complex phase behavior , with several liquid and gaseous phases present. V a n der W aals’ mixture equation of state represented most of the types of phase separations which scientists such as Kamerlingh Onnes were finding in the laboratory . The methods worked out by V a n der W aals and the ‘Dutch School’ are widely used in modern chemical process technology , such as the gas and oil industry , and geophysics. V a n der W aals used the concept of continuity of states to develop a theory of capillarity (1893), which describes the structure of the interface between two fluid phases as well as surface tension.V a n der W aals lost his young wife in 1881 and never remarried. His eldest daughter helped him raise the three younger children. His son became a professor of theoretical physics and one daughter was a well known poet. J.M.H.L.S. This work was not widely known, and the theory was r einvented in the middle of the 20th century both in the then USSR and in the U.S.A. Johannes Diderik van der W aals 1837 - 1923 A warded the Nobel Prize for Physics in 1910His ideas are used in the oil industry Graphite works as a because the planes ,held together by strong chemical (covalent) bonds between the carbon atoms , can slide across each other with only weak between the planes being brok en . lubricant V a n der W aals bonds Graphite works as a because the planes ,held together by strong chemical (covalent) bonds between the carbon atoms , can slide across each other with only weak between the planes being brok en . lubricant Va n der W aals bonds carbon atom covalent bond V a n der W aals bond Va n der W aals bond Van der Waals, Johannes Diderik (1837-1923) Johannes Diderik van der Waals was born on November 23, 1837 in Leyden, The Netherlands, the son of Jacobus van der Waals and Elisabeth van den Burg. After having finished elementary education at his birthplace he became a schoolteacher. Although he had no knowledge of classical languages, and thus was not allowed to take academic examinations, he continued studying at Leyden University in his spare time during 1862-65. In this way he also obtained teaching certificates in mathematics and physics. In 1864 he was appointed teacher at a secondary school at Deventer; in 1866 he moved to The Hague, first as teacher and later as Director of one of the secondary schools in that town. New legislation whereby university students in science were exempted from the conditions concerning prior classical education enabled Van der Waals to sit for university examinations. In 1873 he obtained his doctor's degree for a thesis entitled Over de Continu?teit van den Gas - en Vloeistoftoestand (On the continuity of the gas and liquid state), which put him at once in the foremost rank of physicists. In this thesis he put forward an "Equation of State" embracing both the gaseous and the liquid state; he could demonstrate that these two states of aggregation not only merge into each other in a continuous manner, but that they are in fact of the same nature. The importance of this conclusion from Van der Waals' very first paper can be judged from the remarks made by James Clerk Maxwell in Nature, "that there can be no doubt that the name of Van der Waals will soon be among the foremost in molecular science" and "It has certainly directed the attention of more than one inquirer to the study of the Low-Dutch language in which it is written" (Maxwell probably meant to say "Low-German", which would also be incorrect, since Dutch is a language in its own right). Subsequently, numerous papers on this and related subjects were published in the Proceedings of the Royal Netherlands Academy of Sciences and in the Archives Néerlandaises, and they were also translated into other languages. When, in 1876, the new Law on Higher Education was established which promoted the old Athenaeum Illustre of Amsterdam to university status, Van der Waals was appointed the first Professor of Physics. Together with Van't Hoff and Hugo de Vries, the geneticist, he contributed to the fame of the University, and remained faithful to it until his retirement, in spite of enticing invitations from elsewhere. The immediate cause of Van der Waals' interest in the subject of his thesis was R. Clausius' treatise considering heat as a phenomenon of motion, which led him to look for an explanation for T. Andrews' experiments (1869) revealing the existence of "critical temperatures " in gases. It was Van der Waals' genius that made him see the necessity of taking into account the volumes of molecules and the intermolecular forces ("Van der Waals forces", as they are now generally called) in establishing the relationship between the pressure, volume and temperature of gases and liquids. A second great discovery - arrived at after much arduous work - was published in 1880, when he enunciated the Law of Corresponding States. This showed that if pressure is expressed as a simple function of the critical pressure, volume as one of the critical volume, and temperature as one of the critical temperature, a general form of the equation of state is obtained which is applicable to all substances, since the three constants a, b, and R in the equation, which can be expressed in the critical quantities of a particular substance, will disappear. It was this law which served as a guide during experiments which ultimately led to the liquefaction of hydrogen by J. Dewar in 1898 and of helium by H. Kamerlingh Onnes in 1908. The latter, who in 1913 received the Nobel Prize for his low-temperature studies and his production of liquid helium, wrote in 1910 "that Van der Waals' studies have always been considered as a magic wand for carrying out experiments and that the Cryogenic Laboratory at Leyden has developed under the influence of his theories ". Ten years later, in 1890, the first treatise on the "Theory of Binary Solutions" appeared in the Archives Néerlandaises - another great achievement of Van der Waals. By relating his equation of state with the Second Law of Thermodynamics, in the form first proposed by W. Gibbs in his treatises on the equilibrium of heterogeneous substances, he was able to arrive at a graphical representation of his mathematical formulations in the form of a surface which he called "Psi-surface" in honour of Gibbs, who had chosen the Greek letter Psi as a symbol for the free energy, which he realised was significant for the equilibrium. The theory of binary mixtures gave rise to numerous series of experiments, one of the first being carried out by J. P. Kuenen, who found characteristics of critical phenomena fully predictable by the theory. Lectures on this subject were subsequently assembled in the Lehrbuch der Thermodynamik (Textbook of thermodynamics) by Van der Waals and Ph. Kohnstamm. Mention should also be made of Van der Waals' thermodynamic theory of capillarity, which in its basic form first appeared in 1893. In this, he accepted the existence of a gradual, though very rapid, change of density at the boundary layer between liquid and vapour - a view which differed from that of Gibbs, who assumed a sudden transition of the density of the fluid into that of the vapour. In contrast to Laplace, who had earlier formed a theory on these phenomena, Van der Waals also held the view that the molecules are in permanent, rapid motion. Experiments with regard to phenomena in the vicinity of the critical temperature decided in favour of Van der Waals' concepts. Van der Waals was the recipient of numerous honours and distinctions, of which the following should be particularly mentioned. He received an honorary doctorate of the University of Cambridge; was made honorary member of the Imperial Society of Naturalists of Moscow, the Royal Irish Academy and the American Philosophical Society; corresponding member of the Institut de France and the Royal Academy of Sciences of Berlin; associate member of the Royal Academy of Sciences of Belgium; and foreign member of the Chemical Society of London, the National Academy of Sciences of the U.S.A., and of the Accademia dei Lincei of Rome. In 1864, Van der Waals married Anna Magdalena Smit, who died early. He never married again. They had three daughters and one son. The daughters were Anne Madeleine who, after her mother's early death, ran the house and looked after her father; Jacqueline Elisabeth, who was a teacher of history and a well-known poetess; and Johanna Diderica, who was a teacher of English. The son, Johannes Diderik Jr., was Professor of Physics at Groningen University 1903-08, and subsequently succeeded his father in the Physics Chair of the University of Amsterdam. Van der Waals' main recreations were walking, particularly in the country, and reading. He died in Amsterdam on March 8, 1923. From Nobel Lectures, Physics 1901-1921. VAN DER WAALS EQUATION OF STATE l The Ideal Gas Law, PV = nRT, can be derived by assuming that the molecules that make up the gas have negligible sizes, that their collision with themselves and the wall are perfectly elastic, and that the molecules have no interactions with each other. l The van der Waal's equation is a second order approximation of the equation of state of a gas that will work even when the density of the gas is not low. l Here a and b are constants particular to a given gas. Some van der Waals Constants l The parameter b is related to the size of each molecule. The volume that the molecules have to move around in is not just the volume of the container V, but is reduced to ( V - nb ). l The parameter a is related to intermolecular attractive force between the molecules, and n/V is the density of molecules. The net effect of the intermolecular attractive force is to reduce the pressure for a given volume and temperature. l When the density of the gas is low (i.e., when n/V is small and nb is small compared to V) the van der Waals equation reduces to that of the ideal gas law. l One region where the van der Waals equation works well is for temperatures that are slightly above the critical temperature Tc of a substance Substance a (J. m3/mole2) b (m3/mole) Pc (MPa) Tc (K) Air .1358 3.64x10-5 3.77 133 K Carbon Dioxide (CO2) .3643 4.27x10-5 7.39 304.2 K Nitrogen (N2) .1361 3.85x10-5 3.39 126.2 K Hydrogen (H2) .0247 2.65x10-5 1.30 33.2 K Water (H2O) .5507 3.04x10-5 22.09 647.3 K Ammonia (NH3) .4233 3.73x10-5 11.28 406 K Helium (He) .00341 2.34x10-5 0.23 5.2 K Freon (CCl2F2) 1.078 9.98x10-5 4.12 385 K l Observe that inert gases like Helium have a low value of a as one would expect since such gases do not interact very strongly, and that large molecules like Freon have large values of b. l There are many more equations of state that are even better approximation of real gases than the van der Wall equation. [ Home ] [ Up ] Gas Constant, R, in Various units Van der Waals Constants for Gaseous Molecules MadSci Network : Chemistry Re: Van der Waals constant (b) for neon Date: Fri Feb 13 13:30:14 1998 Posted By: Dan Berger, Faculty Chemistry/Science, Bluffton College Area of science: Chemistry ID: 886784809.Ch Message: While teaching the Van der Waal's equation for real gases, I came across something i did not completely understand: If the "b" constant is correlated to molecular volume, why would the b value for neon be smaller than the value for H or He? I checked the Handbook of Chemistry and Physics, and the closest I could come to an explanation was the fact that the b value was also correlated to a compressibility factor. By the way, the van der Waals equation is According to P.W. Atkins ( Physical Chemistry, 3 d Edition ), a relates to the density of the gas and b to the total volume occupied by the gas molecules. It is important to recognize that these constants are derived from experiment, that is, they are empirical . The first thing I did was to check my handy Sargent - Welch periodic table. It gives atomic and covalent radii. A few calculations (and a check of the Handbook of Chemistry and Physics ) gave the following information: For hydrogen (a diatomic molecule), we need the covalent radius (0.32) to convert the information into a molecular volume; I assumed a cylinder, with hemispheric ends, with radius 0.79 and length 2.22 (= 2*0.32+2*0.79). The volume is then given by: where r cov is the covalent radius of hydrogen. (The two hemispheres add to the volume of a sphere of radius r , and the remainder of the volume is a cylinder with radius r and height 2 r cov .) Element Atomic Radius Molecular Volume van der Waals a constant * van der Waals b constant * Hydrogen 0.79 3.3 0.24 0.027 Helium 0.49 0.49 0.03 0.024 Neon 0.51 0.55 0.21 0.017 * van der Waals constants taken from the Handbook of Chemistry and Physics, 61 st Edition For helium and neon, (monatomic) molecular volume is just . These results explain the difference with hydrogen (which is, after all, H 2 ) by showing that a hydrogen molecule will be rather larger than a neon atom. (In fact, hydrogen's b constant is much smaller than one might expect, given its molecular volume. Of that, more anon.) However, the neon atom will be slightly larger than a helium atom, so that volume cannot be the whole story. We must again be reminded that the van der Waals constants are empirical . Thus, they reflect many real - world variables, such as "compressibility." Compressibility ought to be affected by how well the molecules can interact with each other; the better the interactions, the higher the compressibility. You see, the stronger the non - bonded intermolecular (that is, the van der Waals) forces, the more closely the molecules will be able to approach each other and the lower the value of the b constant. One source of van der Waals interactions is thought to be "induced - dipole/induced - dipole" interactions, in which a temporary dipole in one molecule induces an opposite dipole in a neighbor. The two temporary dipoles then attract each other. However, the more tightly electrons are held within a molecule, the harder it will be to induce a dipole (this is called polarizability ) and the weaker the van der Waals interactions. Indeed, the volume occupied by the molecules will go up because of electron - electron repulsions. Therefore, I think a clue to the van der Waals b constant may be found in ionization potentials, which measure how tightly electrons are held. Looking at the three elements (and the same periodic table), we find: Here, at last, we find an explanation not only for neon but also for hydrogen. Both neon and hydrogen are more polarizable than helium -- hydrogen very much so -- and thus their van der Waals b constants are lower than one would expect from volumes alone. I am afraid that I have been carried away! Current Queue | Current Queue for Chemistry | Chemistry archives Element Ionization Potential Hydrogen 13.6 Helium 24.6 Neon 21.6 ? Dan Berger ? Bluffton College ? http://cs.bluffton.edu/~berger Try the links in the MadSci Library for more information on Chemistry . MadSci Home | Information | Search | Archives | Mad Library | MAD Labs | MAD FAQs | Ask a question | Join Us! MadSci Network, webadmin@www.madsci.org ? 1995 - 1998. All rights reserved. The Behavior of Gases Real Gases vs. Ideal Gases Most of the discussions of gases assume that the gases exhibit ideal behavior. Ideal behavior involves two things: the first is that the gas can be infinitely compressed or infinitely cooled and the gas will not liquefy. The second is that the gas molecules have no volume. With these assumptions, the ideal gas law, PV=nRT, can be used. In reality, however, if a gas is compressed enough the particles will attract and will liquefy. Similarly if the gas is cooled to its boiling point, it will liquefy. Therefore at low temperatures or high pressures, the effect of the attractive forces becomes larger. However, if the gas is moving fast enough, attractive forces between the molecules that cause liquefaction are not a factor. Gas molecules also definitely have a volume, small though it may be, and the volume of the molecules play a factor under conditions of large gas molecules and small container volumes. Joseph van der Waals studied the behavior of real gases and made comparisons to the ideal gas law. He derived an equation to account for the differences. The equation adds in two constants, a and b, to the ideal gas law. These constants are derived to give the best agreement between the observed behavior and the equation. Therefore each gas has its own values for the constants. The van der Waals equation is stated as: P + n 2 a/V 2 deals with attractive forces between molecules and how they reduce the ideal pressure. V - nb accounts for volume of the particles, where the constant b is related to the size of the molecule and since the molecules take up space, the effective size of the container is decreased. Van der Waals received a Nobel Prize in physics in 1910 for his work in gases and liquids. Below is a table giving the a and b constants for various gases. The a values are small for those gases with small intermolecular attractions, such as He. In general the larger molecules have a larger b constant, as can be seen for octane, though this is not the only factor for determining b. Gas Formula a [(L 2 · atm)/mole 2 ] b [L/mole] Helium He 0.03412 0.02370 Hydrogen H 2 0.2444 0.02661 Nitrogen N 2 1.390 0.03913 To illustrate the differences between the two equations, an example using acetylene and helium gas will be shown. Example: One mole of acetylene gas is placed in a 20.0 L container at 25 ° C. a) The pressure using the Ideal Gas Law is shown to be: b) The pressure using the van der Waals equation is shown to be: There is approximately a 0.66% difference between the two values. If the same calculation was done with helium gas, the difference would only be about 0.13%. Return to the additional information page. Return to the Chem homepage Oxygen O 2 1.360 0.03183 Carbon dioxide CO 2 3.592 0.04267 Acetylene C 2 H 2 4.390 0.05136 Chlorine Cl 2 6.493 0.05622 n - Butane C 4 H 10 14.47 0.1226 n - Octane C 8 H 18 37.32 0.2368