Patent Application
20090035742
The invention relates to a classroom science model and play set for demonstrating the organization of electrons in atoms.
In school science classes at all grade levels students are taught the basic principles of atomic structure: that atoms are composed of a tiny, heavy, nucleus around which very lightweight electrons are circulating in some unexplained manner. Students are further taught about the periodic table of chemical elements which keeps count of, and lists in sequence, the names of all chemical elements. Counting through the periodic table from Hydrogen, element number one, each successive type of atom has in its nucleus a number of protons with positive electrical charge equal to its atomic number. Surrounding the nucleus are an equal number of electrons.
Each electron in an atom is assigned a set of labels which define its position or energy level in the atom. The labels, four for each electron, known as “quantum numbers”, have been likened to theater seat assignments, one attendee to a seat. In the same way, no two electrons in an atom can have the same set quantum numbers. The student is instructed that the quantum numbers place each electron in a “shell” surrounding the nucleus like layers of an onion. Electron-by-electron, the shells become filled through a build-up or “aufbau” sequence element-to-element according to each one's atomic number. For example, two electrons completely fill up shell number one, the shell closest to the nucleus; 8 electrons fill up the next larger shell (number 2), 18 in the third shell, 32 in the fourth shell; again 32 in the fifth shell. In the final (synthetic) element, 103, Lawrencium, its seven shells are listed to contain, 2, 8, 18, 32, 32, 9, 2 electrons.
In addition to the sequence of shells and their maximum allowed numbers of electrons, there are also “sub shells” that generally describe partially occupied shells. Shell number two is made up of two sub shells containing, respectively, 2 (s electrons) and 6 (p electrons) totaling 8 electrons for the whole shell. In bigger atoms, in shell number three, added to the 2 “s” electrons and the 6 “p” electrons, there is a “d” sub shell with 10 electrons to complete the shell. The fourth shell can have additionally, 14 “f” electrons.
The standard textbook visualization of an atom with many-electrons is a flat drawing with a set of concentric circles representing the electron shells. Dots arranged around the rings represent the individual electrons. While such a diagram serves as a reasonable schematic, it offers the student zero spatial understanding about a three-dimensional atom. It is especially unsatisfactory in that it reinforces the long rejected conception of atomic electrons as tiny comets flying around the nucleus rather than understanding them as electron matter-waves, the founding conception of the standard Schrödinger wave model.
My previous patents, U.S. Pat. No. 3,276,148 “Model For Atomic Forms”, issued Oct. 4, 1966; and U.S. Pat. No. 4,099,339; “Model For Atomic Forms”, issued Jul. 11, 1978 describe the magnetic spatial relationships between atomic electrons in the geometry of circlespheres, i.e., symmetrical patterns of small circles on spheres. Models based on shells of magnets are excellent for representing individual shells but for concentric shells within shells, the manufacturing costs are prohibitive for casual classroom use.
Thus, there is a need for improved atom modeling sets for introduction to students in their beginning studies, so that they can fix the image of atoms as three dimensional entities; and with atomic electrons understood as matter waves and not as flying particles within the atom. The present invention now satisfies these needs.
The present invention describes a simpler, more workable and attractive, device which overcomes the practical problems of a permanent magnet model. The invention adds new construction features for manufacturing an inexpensive and attractive classroom teaching device.
The invention relates to a construction kit such as for the depiction of atoms and their arrangements in elements and compounds. This kit comprises a plurality of ring components each having plural connection points for connection to other ring components. The connection points typically comprise male connectors or female connectors with each ring component including one or more male connectors, one or more female connectors, or both male and female connectors, so that multiple ring components can be connected in different configurations to form three-dimensional objects.
The kit generally includes 6 to 110 ring components and further comprises a stand component for engaging one or more of the ring components to support the three dimensional objects. The ring components of the kit are generally circular or oval. Some or all of the ring components may have a non-uniform body portion with increased dimensions at locations supporting the connection points. The most preferred connection points comprise tabs and grooves or snap locking members.
The invention also relates to a three dimensional object formed by connection of ring components from the kits described herein. These objects typically have a generally spherical shape termed circlespheres with a number of the ring components connected to other components at the connection points. A hemispherical shape is also desirable as an alternative. The components can be connected in a way which leaves openings between at least some adjacent ring components in either shape. Also, additional connected ring components can be present within the sphere or hemisphere as a second structure, and each structure can move or rotate independently of the other.
Thus, an atom modeling device comprising the kit disclosed herein and/or the objects disclosed herein represent additional embodiments of the invention.
a is an exploded view of the pedestal stand of
In this invention each electron is represented as a wave-like small circle on a sphere. The ring-shaped orbitals made of plastic or other suitable material join with one another to form a spherical mosaic by means of tongue-in-groove or snap-fit joints which bind the entire shell firmly in place by means of a unique joining geometry. A spherical shell is formed by joining a set of orbitals which represents an atomic electron energy level with all electrons labeled and accounted for. The completed shells fit one inside another to represent a whole atom. The user may also construct a shell that is only partially filled. Finally, a display stand is shown that is able to hold the concentric spheres in position one to another. Another embodiment of the invention allows the separate spheres within spheres to revolve freely in the atom model.
The preferred features of my invention include:
An atom model constructed of plastic or other suitable material with parts that link together by means of a male/female joining system, taking advantage of the binary properties of select polyhedra.
A model of the atom's electron shells displayed in three dimensions rather than on a flat page.
An atom model capable of displaying, three-dimensionally, filled or partially filled shells and sub shells containing from 1 to 32 electrons.
A model whose electron orbitals are shaped like waves in order to develop understanding that atomic electrons form de Broglie standing waves.
An atom model of electron shells with each electron orbital labeled with its individual set of four quantum numbers.
A snap-in-place connecting principle that results in a firm spherical construction for each electron shell.
An atom model accompanied by a support-stand that interlocks with each shell and positions all shells centrally in relation to one-another and to the nucleus.
An atom model with spherical shells and sub shells able to revolve individually within the atom model.
An atom model with hemispherical shells and sub shells able to rotate independently.
Instructors of chemistry and physics must introduce the student to the concept of the atom as a heavy tiny nucleus surrounded by electrons. The challenge is to impart the idea that the atom is three-dimensional while the convention for presenting the atom's electron configuration customarily relies on a two-dimensional diagram as shown in
By contrast, the present invention is a simple and economical building set and classroom device for representing any atomic element's full electron configuration in a three-dimensional model as shown in
Each construction item or module, as drawn in
When the modules are joined to build shells,
The electron parts may be given quantum number labels according to the building-up principle of the periodic table. During the model's construction, beginning with shell number one, nearest to the nucleus each larger shell is constructed surrounding the previous sphere so that finally the shells are a set of spheres-within-spheres.
If desired, the invention can be configured in the shape of a hemisphere or other partial sphere rather than as a full sphere. This discloses the arrangement of the atoms without completing the symmetry of the full sphere and allows other kit components to be available to form additional atomic models. For example, in
In the preferred embodiment of the invention the pedestal stand,
In a variation of the invention,
In either of these preferred embodiments of the invention, when construction of the atom model is completed, it becomes not only a valuable instrument for visualizing the atom with its electrons but also an attractive art work, bringing the satisfaction to the owner of having succeeded in creating a complex construction.
