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nanoHUB.org Style Guide 1.5

by Margaret Shepard Morris

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-= '''nanoHUB.org Style Guide and Glossary 1.0''' =
+= '''nanoHUB.org Style Guide 1.5''' =
-In general, nanoHUB style adheres to ''The Chicago Manual of Style'', 15th Ed. (CMS), and ''IEEE Standards Style Manual'' (IEEE) to resolve questions of style and usage on nanoHUB.org
+''For a printer-friendly version, click this link:'' [[File(nanoHUB_Style_Guide_2_0.pdf)]]
-CMS and IEEE styles evolve with the advent of new technologies, genres, and conventions; for this reason, these guidelines are used by the nanoHUB editors to resolve questions of style throughout the website. Familiarity with CMS, then, is key also to maintaining consistency in nanoHUB materials, which are frequently written by multiple authors possessing different bases for style. In other words, when in doubt, see CMS or IEEE manuals.
+In general, nanoHUB style adheres to ''The Chicago Manual of Style'', 15th Ed. (CMS), and ''IEEE Standards Style Manual'' (IEEE) to resolve questions of style and usage on nanoHUB.org.
+CMS and IEEE styles evolve with the advent of new technologies, genres, and conventions; for this reason, these guidelines are used by the nanoHUB editors to resolve questions of style throughout the website. Familiarity with CMS is key also to maintaining consistency in nanoHUB materials, which are frequently written by multiple authors possessing different bases for style. In other words, when in doubt, see CMS or IEEE manuals.
-==Glossary==
+Authors can use forecasting to inform readers where they need to turn for specific information. For example, the introduction of a document can use the forecast of the structure of the document to indicate which readers should begin with a specific section, and which readers can avoid certain sections.
-revised June 12, 2009
+The VEDA manual is comprised of three sections: Part one, for first-time users, introduces readers to the software and guides them through simulations. The second part, for expert users, provides discussions of the theoretical models used to perform the simulations. . . .
-A helpful site: http://ecee.colorado.edu/~bart/book/contents.htm
+== General formatting ==
-'''1-D''', '''2-D''', '''3-D''', or '''one-dimensional''', etc. (hyphenated form is the standard?)
+''Font suggestions'': If the document is intended for print, then headings should be in a sans-serif font (such as Arial or Helvetica), and the body text should be in a serif font (such as Times New Roman). If the document is intended for online publication only, then the headings should be in a serif font, and the body text in a sans-serif font. Any code should be in a fixed-width font, such as Courier.
-'''ab initio''' (Latin, "from the beginning"). Italicize. Hyphenate when used as an adjective, i. e. the ab-initio process
+''Figures and tables'': Both figure and table labels should be in bold font to set the descriptions apart from other body text. Figure labels appear below the figure, and table labels appear above the table.
-'''ABACUS''': Assembly of Basic Applications for Coordinated Understanding of Semiconductor Devices
+== Specific Guidelines ==
-ACUTE: Assembly for Computational Electronics
+''Use of abbreviations''
-AQME: Advancing Quantum Mechanics of Engineers
+Abbreviations, acronyms, initialisms, and portmanteaus: Abbreviation is an umbrella term that covers acronyms, initialisms, and portmanteaus. Acronyms and initialisms are close cousins, with an acronym referring to terms drawn from the first letters of their parts and read as a single word (AIDS, NATO), and initialisms referring to terms that you read as a series of letters (NPR, ATM, AT&T). Portmanteaus are blended terms, combining the forms and meanings of two  words (spin and electronics=spintronics). On nanoHUB, abbreviations typically appear capitalized and without periods.  The exception to this non-use of the period in an abbreviation is any lowercased abbreviation, such as, et al., p.m., or e.g. The use of portmanteaus on nanoHUB often takes the form of a tool name (e.g. ABACUS).
-aTCADlab: A Technology Computer Aided Design Lab
+nanoHUB users come from a variety of educational backgrounds and levels of expertise. To aid novice users, abbreviations should be defined with the initial use. Also, as nanoHUB serves many scholars and researchers whose primary language  is not English, abbreviations for non-field-specific terms (e.g., misc., ASAP, and FYI) should be avoided whenever possible.
+Acceptable: "Carbon nanotubes (CNT) have interesting, structure-dependent electronic properties. In particular, CNTs can be a metallic or semiconducting depending on the way in which the carbon atoms are arranged in the CNT walls."
+Unacceptable: "The program CNDO/INDO is a general purpose combination of the CNDO/S, CNDO/2, INDO, and INDO/S programs. It does RHF (open and closed shell) calculations only, no geometry optimizations, and does Multi-Reference CI. Transition metals are included."
-applied bias: the voltage applied to the structure
+Formatting: Abbreviations, acronyms, and initialisms typically appear capitalized and without punctuation. Abbreviations for non-English terms are not italicized. Portmanteaus typically appear either entirely lowercase or with the initial letter capitalized, as is the case with tool names.
-See <http://ecee.colorado.edu/~bart/book/contents.htm>
-ballistic nanotransistor: a transistor with minimal impediment to speed of current
+''Capitalization''
-ballistic transport: the transport of electrons in a medium with negligible electrical resistivity due to scattering. Without scattering, electrons simply obey Newton's second law of motion at non-relativistic speeds.
+A few general rules for capitalization throughout the site and in supporting documents appear below. Field-specific terms that appear on nanoHUB are sometimes derived from proper nouns and sometimes not, so correct capitalization requires an understanding of these terms' origins. For a list of terms that need to be capitalized, as well as the rationale for capitalization, see the Glossary below.
-See <http://en.wikipedia.org/wiki/Ballistic_transport>
-band structure: In solid-state physics, the electronic band structure (or simply band structure) of a solid describes ranges of energy that an electron is "forbidden" or "allowed" to have. It is due to the diffraction of the quantum mechanical electron waves in the periodic crystal lattice. The band structure of a material determines several characteristics, in particular its electronic and optical properties.
+''Proper names''
-See <http://en.wikipedia.org/wiki/Band_structure>
-bandgap: the range of energies between existing energy bands where no energy levels exist
+Words derived from proper names should be capitalized (e.g., Green's function). Common terms like capacitors and transistors should not be capitalized. See field-specific names and terms for further elaboration. Tool names are proper names and should thus be capitalized.
-See <http://ecee.colorado.edu/~bart/book/contents.htm>
-Bauschinger effect: The Bauschinger effect refers to a property of materials where the material's stress/strain characteristics change as a result of the microscopic stress distribution of the material. For example, an increase in tensile yield strength occurs at the expense of compressive yield strength.
+''Tool names''
-The Bauschinger effect is named after the German engineer Johann Bauschinger.
-See <http://en.wikipedia.org/wiki/Bauschinger_effect>
-bipolar junction transistors
+Band Structure / band structure
+    (always two words; capitalization depends upon context/usage as there is a proper noun and a common noun usage)
-biomedical engineering: the application of engineering principles and techniques to the medical field. It combines the design and problem solving skills of engineering with medical and biological sciences to improve healthcare diagnosis and treatment.
+All citations should conform to [http://www.ieee.org/documents/stylemanual.pdf {{{IEEE guidelines}}}].
-See <http://en.wikipedia.org/wiki/Biomedical_engineering>
-biosensing:
+''Footnotes''
-biosensor: A biosensor is a device for the detection of an analyte that combines a biological component with a physicochemical detector component.
+Bracketed footnote indicators should follow a space: e.g. {{{transport [7]}}} rather than {{{transport[7]}}}.
-It consists of 3 parts: (1) the sensitive biological element (biological material (eg. tissue, microorganisms, organelles, cell receptors, enzymes, antibodies, nucleic acids, etc), a biologically derived material or biomimic) The sensitive elements can be created by biological engineering. (2) the transducer or the detector element (works in a physicochemical way; optical, piezoelectric, electrochemical, etc.) that transforms the signal resulting from the interaction of the analyte with the biological element into another signal (i.e., transducers) that can be more easily measured and quantified; (3) associated electronics or signal processors that is primarily responsible for the display of the results in a user-friendly way.
-See <http://en.wikipedia.org/wiki/Biosensor>
-bipolar junction transistor (BJT): a type of transistor. It is a three-terminal device constructed of doped semiconductor material and may be used in amplifying or switching applications. Bipolar transistors are so named because their operation involves both electrons and holes, as opposed to unipolar transistors, such as field-effect transistors, in which only one carrier type is involved in charge flow. Although a small part of the transistor current is due to the flow of majority carriers, most of the transistor current is due to the flow of minority carriers and so BJTs are classified as minority-carrier devices.
+''Dates''
-See <http://en.wikipedia.org/wiki/Bipolar_junction_transistor>
-Boltmann transport equation (BTE):
+The little endian system (DD MM YYYY) is to be preferred. The big endian system (YYYY-MM-DD) will be found on occasion. The American system of month day, year should be avoided.
+''Names''
+Author names: Digital technologies allow for the inclusion of characters that could not be produced on a typewriters, so when possible, individual's names should appear as they have been entered. This means attention to spelling and the inclusion of non-English alphabet characters, such as umlauts, tildes, and accents. Authors are allowed to use initials instead of a full name, but initials should be capitalized and followed by a period and a space.
-bound state: In physics, a bound state is a composite of two or more building blocks (particles or bodies) that behaves as a single object. In quantum mechanics (where the number of particles is conserved), a bound state is a state in the Hilbert space that corresponds to two or more particles whose interaction energy is negative, and therefore these particles cannot be separated unless energy is spent. The energy spectrum of a bound state is discrete, unlike the continuous spectrum of isolated particles. (Actually, it is possible to have unstable bound states with a positive interaction energy provided that there is an "energy barrier" that has to be tunnelled through in order to decay. This is true for some radioactive nuclei and for some electret materials able to carry electric charge for rather long periods.)
+University names:  Spacing and punctuation conventions in university names are determined by state legislatures and universities, not popular convention. Be aware that faculty, students, and alum often incorrectly format university names, so err on the side of caution when relying on user-submitted content for examples. See university websites to determine proper formatting for university names.
-In general, a stable bound state is said to exist in a given potential of some dimension if stationary wavefunctions exist (normalized in the range of the potential). The energies of these wavefunctions are negative.
-See <http://en.wikipedia.org/wiki/Bound_state>
-Bravais lattice: any of 14 possible three-dimensional configurations of points used to describe the orderly arrangement of atoms in a crystal. Each point represents one or more atoms in the actual crystal, and if the points are connected by lines, a crystal lattice is formed; the lattice is divided into a number of identical blocks, or unit cells, characteristic of the Bravais lattices. The French scientist Auguste Bravais demonstrated in 1850 that only these 14 types of unit cells are compatible with the orderly arrangements of atoms found in crystals.
-See <http://www.britannica.com/EBchecked/topic/78054/Bravais-lattice>
-bulk: back contact of a MOSFET also referred to as a substrate contact
-See <http://ecee.colorado.edu/~bart/book/contents.htm>
-bulk band structure
-bulk semiconductors: Frequently distinguished from mutiple quantum well (MQW) semiconductors by their single crystals and conventional heterojunction structures.
-See "Bulk Semiconductors" in Applied Optics 26.2 (1987): 214.
-Burgers vector: often denoted by b, is a vector that represents the magnitude and direction of the lattice distortion of dislocation in a crystal lattice.
-See <http://en.wikipedia.org/wiki/Burgers_vector>
-capacitance: charge per unit voltage
-See <http://ecee.colorado.edu/~bart/book/contents.htm>
-capacitor: a passive electronic component consisting of a pair of conductors separated by a dielectric. When a voltage potential difference exists between the conductors, an electric field is present in the dielectric. This field stores energy and produces a mechanical force between the plates. The effect is greatest between wide, flat, parallel, narrowly separated conductors.
-See <http://en.wikipedia.org/wiki/Capacitor>
-carbon nanotubes: 100 amps of electricity crackle in a vacuum chamber, creating a spark that transforms carbon vapor into tiny structures. Depending on the conditions, these structures can be shaped like little, 60-atom soccer balls, or like rolled-up tubes of atoms, arranged in a chicken-wire pattern, with rounded ends. These tiny, carbon nanotubes, discovered by Sumio Iijima at NEC labs in 1991, have amazing properties. They are 100 times stronger than steel, but weigh only one-sixth as much! They are incredibly resilient under physical stress; even when kinked to a 120-degree angle, they will bounce back to their original form, undamaged. And they can carry electrical current at levels that would vaporize ordinary copper wires.
-See <http://nanohub.org/tags/carbonnanotubes>
-charge carriers: In physics, a charge carrier denotes a free (mobile, unbound) particle carrying an electric charge. Examples are electrons and ions.
-See <http://en.wikipedia.org/wiki/Charge_carrier>
-chiralities: a property of asymmetry important in several branches of science. An object or a system is chiral if it cannot be superposed on its mirror image. A chiral object and its mirror image are called enantiomorphs (Greek opposite forms) or, when referring to molecules, enantiomers. A non-chiral object is called achiral (sometimes also amphichiral) and can be superposed on its mirror image.
-See <http://en.wikipedia.org/wiki/Chirality>
-CMOS: complimentary metal oxide silicon (transistor)
-See <http://ecee.colorado.edu/~bart/book/contents.htm>
-computational chemistry: a branch of chemistry that uses computers to assist in solving chemical problems. It uses the results of theoretical chemistry, incorporated into efficient computer programs, to calculate the structures and properties of molecules and solids. While its results normally complement the information obtained by chemical experiments, it can in some cases predict hitherto unobserved chemical phenomena. It is widely used in the design of new drugs and materials.
-See <http://en.wikipedia.org/wiki/Computational_chemistry>
-computational electronics: refers to the physical simulation of semiconductor devices in terms of charge transport and the corresponding electrical behavior. It is related to, but usually separate from process simulation, which deals with various physical processes such as material growth, oxidation, impurity diffusion, etching, and metal deposition inherent in device fabrication leading to integrated circuits. Device
-simulation can be thought of as one component of technology for computer-aided design (TCAD), which provides a basis for device modeling, which deals with compact behavioral  models for devices and subcircuits relevant for circuit simulation in commercial packages such as SPICE.
-See Chapter 1 of Dragica Vasileska's Computational Electronics
-computational engineering: a relatively new discipline of engineering. It is typically offered as a masters or doctorate program at several institutions. This is not to be confused with computer engineering (related to building computers).
-See <http://en.wikipedia.org/wiki/Computational_engineering>
-computational materials (context?)
-computational science: Computational science (or scientific computing) is the field of study concerned with constructing mathematical models and numerical solution techniques and using computers to analyze and solve scientific, social scientific and engineering problems. In practical use, it is typically the application of computer simulation and other forms of computation to problems in various scientific disciplines.
-See <http://en.wikipedia.org/wiki/Scientific_computing>
-crystals: materials in which atoms are placed in a highly ordered structure. Materials that are not crystals are amorphous.
-See <http://ecee.colorado.edu/~bart/book/contents.htm>
-CV measurement: capacitance versus voltage measurement
-See <http://ecee.colorado.edu/~bart/book/contents.htm>
-depassivation
-depletion: removal of free carriers in a semiconductor
-See <http://ecee.colorado.edu/~bart/book/contents.htm>
-depletion region: In semiconductor physics, the depletion region, also called depletion layer, depletion zone, junction region or the space charge region, is an insulating region within a conductive, doped semiconductor material where the charge carriers have diffused away, or have been forced away by an electric field.
-See <http://en.wikipedia.org/wiki/Depletion_zone>
-device physics:
-dielectric: a nonconducting substance, i.e. an insulator. Although "dielectric" and "insulator" are generally considered synonymous, the term "dielectric" is more often used to describe the insulating material between the metallic plates of a capacitor, while "insulator" is more often used when the material is being used to prevent a current flow across it.
-See <http://en.wikipedia.org/wiki/Dielectric>
-drain: contact region of a MOSFET to which the electrons in the channel flow
-See <http://ecee.colorado.edu/~bart/book/contents.htm>
-drift: the motion of carriers caused by an electric field
-<http://ecee.colorado.edu/~bart/book/contents.htm>
-drift-diffusion model: model of a semiconductor is frequently used to describe semiconductor devices. The assumptions of the simplified drift-diffusion model are: full ionization: all dopants are assumed to be ionized (shallow dopants); non-degenerate: the Fermi energy is assumed to be at least 3 kT below/above the conduction/valence band edge; steady state: All variables are independent of time; constant temperature: the temperature is constant throughout the device. See <http://ecee.colorado.edu/~bart/book/contents.htm>
-double-gate: same as dual-gate
-dual-gate: having two gates; see gate
-E=kinetic energy
-E(k), E-k: relation of kinetic energy and momentum vector, use the formula E(k).
-ED: electron density
-effective mass: In solid state physics, a particle's effective mass is the mass it seems to carry in the semiclassical model of transport in a crystal. It can be shown that electrons and holes in a crystal respond to electric and magnetic fields almost as if they were particles with a mass dependent upon the their direction of travel, an effective mass tensor.
-The effective mass has important effects on the properties of a solid, including everything from the efficiency of a solar cell to the speed of an integrated circuit.
-See <http://en.wikipedia.org/wiki/Effective_mass_(solid-state_physics)>
-eigenfunctions: In mathematics, an eigenfunction of a linear operator, A, defined on some function space is any non-zero function f in that space that returns from the operator exactly as is, except for a multiplicative scaling factor. More precisely, one has  for some scalar, λ, the corresponding eigenvalue.
-See <http://en.wikipedia.org/wiki/Eigenfunction>
-eigenstates: (quantum mechanics) A dynamical state whose state vector (or wave function) is an eigenvector (or eigenfunction) of an operator corresponding to a specified physical quantity.
-eigenvalues: a special set of scalars associated with a linear system of equations (i.e., a matrix equation) that are sometimes also known as characteristic roots, characteristic values (Hoffman and Kunze 1971), proper values, or latent roots (Marcus and Minc 1988, p. 144).
-The determination of the eigenvalues and eigenvectors of a system is extremely important in physics and engineering, where it is equivalent to matrix diagonalization and arises in such common applications as stability analysis, the physics of rotating bodies, and small oscillations of vibrating systems, to name only a few. Each eigenvalue is paired with a corresponding so-called eigenvector (or, in general, a corresponding right eigenvector and a corresponding left eigenvector; there is no analogous distinction between left and right for eigenvalues).
-See <http://mathworld.wolfram.com/Eigenvalue.html>
-E-k: What is the natural language version of this relationship [k=momentum vector, as below? E=? [mc^2?]
-energy bands: a collection of closely space energy levels
-See <http://ecee.colorado.edu/~bart/book/contents.htm>
-energy levels: A quantum mechanical system or particle that is bound, confined spatially, can only take on certain discrete values of energy, as opposed to classical particles, which can have any energy. These values are called energy levels. The term is most commonly used for the energy levels of electrons in atoms or molecules, which are bound by the electric field of the nucleus. The energy spectrum of a system with energy levels is said to be quantized.
-See <http://en.wikipedia.org/wiki/Energy_level>
-energy states: also called energy level
-Fermi level: The Fermi level is an energy that pertains to electrons in a semiconductor. It is the chemical potential μ that appears in the electrons' Fermi-Dirac distribution function, [formula] which is the probability that there is an electron in a particular single-particle state with energy. T is the absolute temperature and k is Boltzmann's constant.
-See Wikipedia for formula <http://en.wikipedia.org/wiki/Fermi_level>.
-Fermions: Particles such as electrons, protons, and neutrons that are the "constituents" of matter and account for its impenetrability. Other particles -- called, "bosons" -- mediate, or carry, forces between fermions. Examples would be photons, gravitons, and gluons.
-See <http://www.pbs.org/faithandreason/gengloss/index-frame.html?
-field-effect transistor (FET): a type of transistor that relies on an electric field to control the shape and hence the conductivity of a channel of one type of charge carrier in a semiconductor material. FETs are sometimes called unipolar transistors to contrast their single-carrier-type operation with the dual-carrier-type operation of bipolar (junction) transistors (BJT). The concept of the FET predates the BJT, though it was not physically implemented until after BJTs due to the limitations of semiconductor materials and relative ease of manufacturing BJTs compared to FETs at the time.
-See <http://en.wikipedia.org/wiki/Field-Effect_Transistor>
-fully coupled
-fully-depleted (FD):
-G: kinetic energy
-gate: electrode of a FET, which controls the charge in the channel; see logic gate
-<http://ecee.colorado.edu/~bart/book/contents.htm>
-graphene: a one-atom-thick planar sheet of sp2-bonded carbon atoms that are densely packed in a honeycomb crystal lattice. It can be viewed as an atomic-scale chicken wire made of carbon atoms and their bonds. The name comes from GRAPHITE + -ENE; graphite itself consists of many graphene sheets stacked together.
-See <http://en.wikipedia.org/wiki/Graphene>
-heterojunction: the interface that occurs between two layers or regions of dissimilar crystalline semiconductors. These semiconducting materials have unequal band gaps as opposed to a homojunction.
-intraband:
-ion channels: pore-forming proteins that help establish and control the small voltage gradient across the plasma membrane of all living cells (see cell potential) by allowing the flow of ions down their electrochemical gradient. They are present in the membranes that surround all biological cells.
-See <http://en.wikipedia.org/wiki/Ion_channel>
-intervalley:
-IV characteristics: Current-Voltage characteristics
-See <http://ecee.colorado.edu/~bart/book/contents.htm>
-    I-V curve: current-voltage curve
-        Are we dealing with current as a function of voltage?
-k= momentum vector
-Kronig-Penney: a simple approximation of a solid
-lamellae: a term for a platelike structure, appearing in multiples, that occurs in various situations, such as biology or materials sciences. It implies a thin layer (Latin), the same derivation as for `laminate'.
-See <http://en.wikipedia.org/wiki/Lamella>
-lamellar: Lamellar structures or microstructures are composed of fine, alternating layers of different materials in the form of lamellae. They are often observed in cases where a phase transformation front moves quickly, leaving behind two solid products, as in rapid cooling of eutectic (such as solder) or eutectoid (such as pearlite) systems.
-See <http://en.wikipedia.org/wiki/Lamellar_structure>
-Laplacian: In mathematics and physics, the Laplace operator or Laplacian, denoted by   or   and named after Pierre-Simon de Laplace, is a differential operator, specifically an important case of an elliptic operator, with many applications. In physics, it is used in modeling of wave propagation, heat flow and forming the Helmholtz equation. It is central in electrostatics and fluid mechanics, anchoring in Laplace's equation and Poisson's equation. In quantum mechanics, it represents the kinetic energy term of the Schrödinger equation. In mathematics, functions with vanishing Laplacian are called harmonic functions; the Laplacian is at the core of Hodge theory and the results of de Rham cohomology. In image processing domain it is used for detecting edges.
-See <http://en.wikipedia.org/wiki/Laplace_operator>
-Lennard-Jones potential: (also referred to as the LJ potential, 6-12 potential or, less commonly, 12-6 potential) is a mathematically simple model that describes the interaction between a pair of neutral atoms or molecules. It was proposed in 1924 by John Lennard-Jones.
-The LJ potential is of the form
-,
-where  is the depth of the potential well and  is the (finite) distance at which the interparticle potential is zero and r is the distance between the particles.
-See <http://en.wikipedia.org/wiki/Lennard-Jones_potential>
-logic gate: A logic gate performs a logical operation on one or more logic inputs and produces a single logic output. The logic normally performed is Boolean logic and is most commonly found in digital circuits. Logic gates are primarily implemented electronically using diodes or transistors, but can also be constructed using electromagnetic relays, fluidics, optics, molecules, or even mechanical elements.
-In electronic logic, a logic level is represented by a voltage or current, (which depends on the type of electronic logic in use). Each logic gate requires power so that it can source and sink currents to achieve the correct output voltage. In logic circuit diagrams the power is not shown, but in a full electronic schematic, power connections are required.
-See <http://en.wikipedia.org/wiki/Logic_gate>
-madFET: many acronym device field effect transistor
-majority carriers: more abundant charge carriers
-material properties
-MATLAB: stands for matrix laboratory, is a numerical computing environment and fourth generation programming language
-See <http://en.wikipedia.org/wiki/MATLAB>
-material science: Nanotechnology bears the promise of engineering at an atomic scale--of assembling atoms in arrangements that are completely unnatural, thereby creating materials with properties that have never been seen before. This may sound like science fiction, but it has been going on for more than 30 years, since the invention of Molecular Beam Epitaxy (MBE). MBE provides a way of growing a block of material one sheet of atoms at a time. By mixing different types of atoms in various combinations, it is possible to "tune" the properties of the resulting material. For example, the laser diode in your CD player is probably made from silicon. It shines a particular wavelength of light based on the energy gap between the conduction and valence bands in silicon. That same laser diode could be "tuned" to emit a different wavelength by building it with a new material engineered to have a different band gap.
-See <http://nanohub.org/tags/materialscience>
-metamaterials: exotic composite materials that display properties beyond those available in naturally occurring materials. Instead of constructing materials at the chemical level, as is ordinarily done, these are constructed with two or more materials at the macroscopic level. One of their defining characteristics is that the electromagnetic response results from combining two or more distinct materials in a specified way which extend the range of electromagnetic patterns because of the fact that they are not found in nature.
-See <http://en.wikipedia.org/wiki/Metamaterial>
-microelectronics: Microelectronics is a subfield of electronics. Microelectronics, as the name suggests, is related to the study and manufacture, or microfabrication, of electronic components which are very small (usually micrometre-scale or smaller, but not always). These devices are made from semiconductors. Many components of normal electronic design are available in microelectronic equivalent: transistors, capacitors, inductors, resistors, diodes and of course insulators and conductors can all be found in microelectronic devices.
-See <http://en.wikipedia.org/wiki/Microelectronics>
-microfabrication: (also micromanufacturing) term to describe processes of fabrication of miniature structures, of micrometre sizes and smaller. Historically the earliest micromanufacturing was used for semiconductor devices in integrated circuit fabrication and these processes have been covered by the term "semiconductor device fabrication," "semiconductor manufacturing," etc. Practical advances in microelectromechanical systems (MEMS) and other nanotechnology, where the technologies from IC fabrication are being re-used, adapted or extended have led to the extension of the scope and techniques of microfabrication.
-Miniaturization of various devices presents challenges in many areas of science and engineering: physics, chemistry, material science, computer science, ultra-precision engineering, fabrication processes, and equipment design. It is also giving rise to various kinds of interdisciplinary research.
-The major concepts and principles of micromanufacturing are laser technology, microlithography, micromechatronics, micromachining and microfinishing (nanofinishing).
-See <http://en.wikipedia.org/wiki/Microfabrication>
-minority carriers: less abundant charge carriers
-miscut: a cut that does not follow a plane
-MO theory (Molecular Orbital Theory): In chemistry, molecular orbital theory (MO theory) is a method for determining molecular structure in which electrons are not assigned to individual bonds between atoms, but are treated as moving under the influence of the nuclei in the whole molecule. In this theory, each molecule has a set of molecular orbitals, in which it is assumed that the molecular orbital wave function ψf may be written as a simple weighted sum of the n constituent atomic orbitals χi, according to the following equation:
-See <http://en.wikipedia.org/wiki/Molecular_orbital_theory>
-modulator:
-molecular dynamics: a form of computer simulation in which atoms and molecules are allowed to interact for a period of time by approximations of known physics, giving a view of the motion of the atoms. Because molecular systems generally consist of a vast number of particles, it is impossible to find the properties of such complex systems analytically.
-See <http://en.wikipedia.org/wiki/Molecular_dynamics>
-molecular electronics: Molecular electronics (sometimes called moletronics) is an interdisciplinary theme that spans physics, chemistry, and materials science. The unifying feature of this area is the use of molecular building blocks for the fabrication of electronic components, both passive (e.g. resistive wires) and active (e.g. transistors). The concept of molecular electronics has aroused much excitement both in science fiction and among scientists due to the prospect of size reduction in electronics offered by molecular-level control of properties. Molecular electronics provides means to extend Moore's Law beyond the foreseen limits of small-scale conventional silicon integrated circuits.
-See <http://en.wikipedia.org/wiki/Molecular_electronics>
-molecular mechanism
-molecular orbital: In chemistry, a molecular orbital (or MO) is a mathematical function that describes the wave-like behavior of an electron in a molecule. This function can be used to calculate chemical and physical properties such as the probability of finding an electron in any specific region. The use of the term "orbital" was first used in English by Robert S. Mulliken in 1925 as the English translation of Schrödinger's use of the German word Eigenfunktion. It has since been equated with the "region" generated with the function. Molecular orbitals are usually constructed by combining atomic orbitals or hybrid orbitals from each atom of the molecule, or other molecular orbitals from groups of atoms. They can be quantitatively calculated using the Hartree-Fock or Self-Consistent Field method.
-See <http://en.wikipedia.org/wiki/Molecular_orbital>
-molecular simulations
-MOS: metal-oxide-silicon or metal-oxide-semiconductor (see the about page for Schred).
-MOSCAP: metal-oxide-silicon capacitor
-MOSFET: The metal–oxide–semiconductor field-effect transistor (MOSFET, MOS-FET, or MOS FET) is a device used to amplify or switch electronic signals. The MOSFET includes a channel of n-type or p-type semiconductor material (see article on semiconductor devices), and is accordingly called an NMOSFET or a PMOSFET (also commonly nMOS, pMOS). It is by far the most common transistor in both digital and analog circuits, though the bipolar junction transistor was at one time much more common.
-See <http://en.wikipedia.org/wiki/MOSFET>
-MolST: Molecular Structure Tracer
-multiscale models: Nanotechnology sometimes involves mixing something very small into a larger, more conventional system. For example, mixing carbon nanotubes into a conventional polymer gives it added strength. Or, using a carbon nanotube as the channel between two larger, source-drain contacts creates a transistor with improved channel mobility. But simulating such systems becomes a huge challenge. The smaller parts of the system must be solved with great accuracy–for example, by simulating each atom within a carbon nanotube. But the same approach can't possibly be applied to the larger system–for example, to each atom in the thousands of polymer molecules in a realistic sample–or the whole problem would be too big to solve!
-Multi-scale methods attempt to solve the problem by stitching together smaller domains (where atomistic models apply) and larger domains (where continuum models apply) into a coherent solution.
-See <http://nanohub.org/tags/multiscalemodels>
-multi-well: see well
-n-type semiconductor: An N-type semiconductor (N for Negative) is obtained by carrying out a process of doping, that is, by adding an impurity of valence-five elements to a valence-four semiconductor in order to increase the number of free charge carriers (in this case negative).
-When the doping material is added, it gives away (donates) weakly-bound outer electrons to the semiconductor atoms. This type of doping agent is also known as donor material since it gives away some of its electrons.
-See <http://en.wikipedia.org/wiki/N-type_semiconductor>
-NAND chain (or nand-chain): NAND= not and
-nand gate: a gate using not/and
-nano electro-mechanical system: Nano Electro-Mechanical Systems (NEMS) are tiny machines built at the nanometer scale. Current NEMS applications are simple machines, such as the tiny cantilever shown at the right. An electrical circuit measures the deflection of the lever. A larger version of this device, with dimensions at the micrometer or millimeter scale, is commonly used as an airbag sensor in automobiles. A sudden stop causes a strong deflection of the lever, which signals that the airbags should be deployed. At the nano scale, such a lever is sensitive enough to measure the weight of individual atoms or molecules resting upon it!
-See <http://nanohub.org/tags/nanoelectromechanicalsystems>
-nanoelectronics: Progress in technology has brought microelectronics to the nanoscale, but nanoelectronics is not yet a well-defined engineering discipline with a coherent, experimentally-verified, theoretical framework. The NCN has a vision for a new, 'bottom-up' approach to electronics, by which we mean understanding electronic conduction at the atomistic level, formulating new simulation techniques, developing a new generation of software tools, and bringing this new understanding and perspective into the classroom. We address problems in atomistic phenomena, quantum transport, percolative transport in inhomogeneous media, reliability, and the connection of nanoelectronics to new problems such as biology, medicine, and energy. We work closely with experimentalists to understand nanoscale phenomena and to explore new device concepts. In the course of this work, we produce open source software tools and educational resources that we share with the community through the nanoHUB.
-nanomedicine: the medical application of nanotechnology. The approaches to nanomedicine range from the medical use of nanomaterials, to nanoelectronic biosensors, and even possible future applications of molecular nanotechnology. Current problems for nanomedicine involve understanding the issues related to toxicity and environmental impact of nanoscale materials.
-see <http://en.wikipedia.org/wiki/Nanomedicine>
-nanoparticles: a small object that behaves as a whole unit in terms of its transport and properties. It is further classified according to size: In terms of diameter, fine particles cover a range between 100 and 2500 nanometers, while ultrafine particles, on the other hand, are sized between 1 and 100 nanometers. Similarly to ultrafine particles, nanoparticles are sized between 1 and 100 nanometers, though the size limitation can be restricted to two dimensions. Nanoparticles may or may not exhibit size-related properties that differ significantly from those observed in fine particles or bulk materials.
-See <http://en.wikipedia.org/wiki/Nanoparticle>
-nanophotonics: the study of the behavior of light on the nanometre scale. It is considered as a branch of optical engineering which deals with optics, or the interaction of light with particles or substances, at deeply subwavelength length scales. Technologies in the realm of nano-optics include near-field scanning optical microscopy (NSOM), photoassisted scanning tunnelling microscopy, and surface plasmon optics.
-See <http://en.wikipedia.org/wiki/Nanophotonics>
-When optical components are reduced to the nano scale, they exhibit interesting properties that can be harnessed to create new devices. For example, imagine a block of material with thin layers of alternating materials. This creates a periodic arrangement of alternating dielectric constants, forming a "photonic crystal" analogous to the electronic crystals used in semiconductor devices. Photonic crystals, along with quantum dots and other devices patterned at the nano scale, may form the basis for sensors and switches used in computers and telecommunications.
-See <http://nanohub.org/tags/nanophotonics>
-nanoscale: refering to structures between 1-100 nanometers (sometimes, more formally termed 'nanometer scale')
-nanoscale entity: used to describe objects on the nanoscale; considered by some to be more acceptable that nanothing
-Nanosphere (also Nanosphere, Inc.): a company that has no relation to nanoHUB.org
-NanoSphere®: a textile product created by Schoeller Textiles
-nanostructured surfaces: materials with microstructures modulated in zero to three dimensions on length scales less than 100nm
-See "Advanced Nanotechnology Thin Film Approaches for the Food and Medical Industry: an overview of current status" by Vasco Teixera <https://nanohub.org/resources/2257>
-nanotechnology: the study of the control of matter on an atomic and molecular scale. Generally nanotechnology deals with structures of the size 100 nanometers or smaller, and involves developing materials or devices within that size. Nanotechnology is very diverse, ranging from novel extensions of conventional device physics, to completely new approaches based upon molecular self-assembly, to developing new materials with dimensions on the nanoscale, even to speculation on whether we can directly control matter on the atomic scale.
-See <http://en.wikipedia.org/wiki/Nanotechnology>
-nanothing: a zingier, happier [and more childish?] alternative to nanoscale entity
-nanotube: a nanometer-scale tube-like structure
-See <http://en.wikipedia.org/wiki/Nanotubes>
-nanotransistors: a nanoscale transistor
-nanowire: A nanowire is a nanostructure, with the diameter of the order of a nanometer (10−9 meters). Alternatively, nanowires can be defined as structures that have a thickness or diameter constrained to tens of nanometers or less and an unconstrained length. At these scales, quantum mechanical effects are important — hence such wires are also known as "quantum wires".
-See <http://en.wikipedia.org/wiki/Nanowire>
-Nanowire: Nanowire is a simulation tool for of silicon nanowire FETs in the nanometer regime (diameter <= 5 nm) where quantum effects are important and (channel length <= 10 nm) where transport is mostly ballistic in nature.
-See <http://nanohub.org/resources/4531>
-NCN Supported
-NCN@Purdue Supported
-NEGF: The non-equilibrium Greens function (NEGF) formalism provides a powerful conceptual and computational framework for treating quantum transport in nanodevices. It goes beyond the Landauer approach for ballistic, non-interacting electronics to include inelastic scattering and strong correlation effects at an atomistic level.
-See <http://nanohub.org/topics/Negf>
-NEMS/MEMS: Nanoelectromechanical systems (NEMS) are microelectromechanical systems (MEMS) with dimensions in the submicron region. Carbon nanotubes, whose dimensions can be several nanometers, are good examples of nanostructures that can be used in NEMS.
-NOR chain: a chain using NOR operator
-observables: results that can be directly observed instead of being inferred
-OMEN: OMEN is also a fully parallelized using message passing interface(MPI) for wave vectors in the bandstructure and energy grids in the transport. Great flexibility in OMEN Nanowire for device structure and simulation options allows users to simulate a circular or rectangular nanowire with or without strain effect.
-on-state:
-Orowan loops
-p-type semiconductor: A P-type semiconductor (P for Positive) is obtained by carrying out a process of doping, that is adding a certain type of atoms to the semiconductor in order to increase the number of free charge carriers (in this case positive).
-When the doping material is added, it takes away (accepts) weakly-bound outer electrons from the semiconductor atoms. This type of doping agent is also known as acceptor material and the vacancy left behind by the electron is known as a hole.
-See <http://en.wikipedia.org/wiki/P-type_semiconductor>
-PADRE (Pisces And Device REplacement)
-passivation: the process of making a material "passive" in relation to another material prior to using the materials together. For example, prior to storing hydrogen peroxide in an aluminium container, the container can be passivated by rinsing it with a dilute solution of nitric acid and peroxide alternating with deionized water. The nitric acid and peroxide oxidizes and dissolves any impurities on the inner surface of the container, and the deionized water rinses away the acid and oxidized impurities. Another typical passivation process of cleaning stainless steel tanks involves cleaning with sodium hydroxide and citric acid followed by nitric acid (up to 20% at 120 °F) and a complete water rinse. This process will restore the film, remove metal particles, dirt, and welding-generated compounds (e.g. oxides).
-In the context of corrosion, passivation is the spontaneous formation of a hard non-reactive surface film that inhibits further corrosion. This layer is usually an oxide or nitride that is a few atoms thick.
-See <http://en.wikipedia.org/wiki/Passivation>
-parallel computing: a form of computation in which many calculations are carried out simultaneously, operating on the principle that large problems can often be divided into smaller ones, which are then solved concurrently ("in parallel"). There are several different forms of parallel computing: bit-level, instruction level, data, and task parallelism. Parallelism has been employed for many years, mainly in high-performance computing, but interest in it has grown lately due to the physical constraints preventing frequency scaling. As power consumption (and consequently heat generation) by computers has become a concern in recent years, parallel computing has become the dominant paradigm in computer architecture, mainly in the form of multicore processors.
-See <http://en.wikipedia.org/wiki/Parallel_computing>
-parallel programming: A parallel programming model is a set of software technologies to express parallel algorithms and match applications with the underlying parallel systems. It encloses the areas of applications, programming languages, compilers, libraries, communications systems, and parallel I/O. Due to the difficulties in automatic parallelization today, people have to choose a proper parallel programming model or a form of mixture of them to develop their parallel applications on a particular platform.
-See <http://en.wikipedia.org/wiki/Parallel_programming_model>
-periodic potential: particle in a one-dimentional lattice
-piecewise: In mathematics, a piecewise-defined function (also called a piecewise function) is a function whose definition is dependent on the value of the independent variable. Mathematically, a real-valued function f of a real variable x is a relationship whose definition is given differently on disjoint subsets of its domain (known as subdomains).
-The word piecewise is also used to describe any property of a piecewise-defined function that holds for each piece but may not hold for the whole domain of the function. A function is piecewise differentiable or piecewise continuously differentiable if each piece is differentiable throughout its domain. In convex analysis, the notion of a derivative may be replaced by that of the subderivative for piecewise functions. Although the "pieces" in a piecewise definition need not be intervals, a function is not called "piecewise linear" or "piecewise continuous" or "piecewise differentiable" unless the pieces are intervals.
-See <http://en.wikipedia.org/wiki/Piecewise>
-pn junction: a junction between an n-type and a p-type semiconductor
-See <http://ecee.colorado.edu/~bart/book/contents.htm>
-Prophet/PROPHET: a general PDE solver; suitable for continuum-based simulations of semiconductor and nano-bio devices
-quantum: In physics, a quantum (plural: quanta) is an indivisible entity of a quantity that has the same units as the Planck constant and is related to both energy and momentum of elementary particles of matter (called fermions) and of photons and other bosons. The word comes from the Latin "quantus", for "how much." Behind this, one finds the fundamental notion that a physical property may be "quantized", referred to as "quantization". This means that the magnitude can take on only certain discrete numerical values, rather than any value, at least within a range. There is a related term of quantum number.
-A photon is often referred to as a "light quantum". The energy of an electron bound to an atom (at rest) is said to be quantized, which results in the stability of atoms, and of matter in general. But these terms can be a little misleading, because what is quantized is this Planck's constant quantity whose units can be viewed as either energy multiplied by time or momentum multiplied by distance.
-Usually referred to as quantum "mechanics", it is regarded by virtually every professional physicist as the most fundamental framework we have for understanding and describing nature at the infinitesimal level, for the very practical reason that it works. It is "in the nature of things", not a more or less arbitrary human preference.
-See <http://en.wikipedia.org/wiki/Quanta>
-quantum chemistry: a branch of theoretical chemistry, which applies quantum mechanics and quantum field theory to address issues and problems in chemistry. The description of the electronic behavior of atoms and molecules as pertaining to their reactivity is one of the applications of quantum chemistry. Quantum chemistry lies on the border between chemistry and physics, and significant contributions have been made by scientists from both fields. It has a strong and active overlap with the field of atomic physics and molecular physics, as well as physical chemistry.
-See <http://en.wikipedia.org/wiki/Quantum_chemistry>
-quantum computing: a device for computation that makes direct use of quantum mechanical phenomena, such as superposition and entanglement, to perform operations on data. The basic principle behind quantum computation is that quantum properties can be used to represent data and perform operations on these data.
-See <http://en.wikipedia.org/wiki/Quantum_computing>
-quantum dots: Quantum dots have a small, countable number of electrons confined in a small space. Their electrons are confined by having a tiny bit of conducting material surrounded on all sides by an insulating material. If the insulator is strong enough, and the conducting volume is small enough, then the confinement will force the electrons to have discrete (quantized) energy levels. These energy levels can influence the device behavior at a macroscopic scale, showing up, for example, as peaks in the conductance. Because of the quantized energy levels, quantum dots have been called "artificial atoms." Neighboring, weakly-coupled quantum dots have been called "artificial molecules." Not spelled out "quantum-dots."
-quantum mechanics: theory which describes particles by a wavefunction
-See <http://ecee.colorado.edu/~bart/book/contents.htm>
-quantum Monte Carlo: a large class of computer algorithms that simulate quantum systems with the idea of solving the many-body problem. They use, in one way or another, the Monte Carlo method to handle the many-dimensional integrals that arise. Quantum Monte Carlo allows a direct representation of many-body effects in the wavefunction, at the cost of statistical uncertainty that can be reduced with more simulation time. For bosons, there exist numerically exact and polynomial-scaling algorithms. For fermions, there exist very good approximations and numerically exact exponentially scaling quantum Monte Carlo algorithms, but none that are both.
-See <http://en.wikipedia.org/wiki/Quantum_Monte_Carlo>
-quantum optics: a field of research in physics, dealing with the application of quantum mechanics to phenomena involving light and its interactions with matter.
-See <http://en.wikipedia.org/wiki/Quantum_optics>
-quantum theory: A theory of the interaction of matter and radiation developed early in the twentieth century which is based on the quantization of energy and applied to a wide variety of processes that involve an exchange of energy at the atomic level.
-See <http://www.pbs.org/faithandreason/physgloss/qm-body.html>
-quantum transport
-quantum well: Quantum well structures (QWs) consist of ultrathin layers of semiconductors having different composition and grown alternately one after another. Because of this structure, the position of the electronic energy levels is modulated in the direction normal to the layers.
-See "Multiple quantum wells" in Applied Optics 26.2 (1987): 216.
-quasibound: having closed boundaries at one side and open boundaries at the other
-See <http://www.iue.tuwien.ac.at/phd/gehring/node53.html>
-qubit: a quantum bit or unit of quantum information
-Rappture: Rapid Application Infrastructure. Because the word is a portmanteau, only the initial letter should be capitalized.
-resistivity: the ration of the applied voltage to the current
-<http://ecee.colorado.edu/~bart/book/contents.htm>
-scanning probe microscopy: Scanning Probe Microscopy (SPM) is a branch of microscopy that forms images of surfaces using a physical probe that scans the specimen. An image of the surface is obtained by mechanically moving the probe in a raster scan of the specimen, line by line, and recording the probe-surface interaction as a function of position. SPM was founded with the invention of the scanning tunneling microscope in 1981.
-See <http://en.wikipedia.org/wiki/Scanning_probe_microscopy>
-Schottky barriers: a potential barrier formed at a metal-semiconductor junction which has rectifying characteristics, suitable for use as a diode. The largest differences between a Schottky barrier and a p-n junction are its typically lower junction voltage, and decreased (almost nonexistent) depletion width in the metal.
-See <http://en.wikipedia.org/wiki/Schottky_barrier>
-Schred: a tool that calculates the envelope wavefunctions and the corresponding bound-state energies in a typical MOS (Metal-Oxide-Semiconductor) or SOS (Semiconductor-Oxide-Semiconductor) structure and a typical SOI structure by solving self-consistently the one-dimensional (1-D) Poisson equation and the 1-D Schrödinger equation.
-See <https://nanohub.org/resources/schred>. As in the case with Rappture, the word is a portmanteau; hence, only the initial letter should be capitalized.
-Schrödinger's equation: In physics, especially quantum mechanics, the Schrödinger equation is an equation that describes how the quantum state of a physical system changes in time. It is as central to quantum mechanics as Newton's laws are to classical mechanics.
-See <http://en.wikipedia.org/wiki/Schr%C3%B6dinger_equation>
-self-consistent
-semiconductor: a material that has a resistivity value between that of a conductor and an insulator. The conductivity of a semiconductor material can be varied under an external electrical field. Devices made from semiconductor materials are the foundation of modern electronics, including radio, computers, telephones, and many other devices. Semiconductor devices include the transistor, many kinds of diodes including the light-emitting diode, the silicon controlled rectifier, and digital and analog integrated circuits. Solar photovoltaic panels are large semiconductor devices that directly convert light energy into electrical energy. In a metallic conductor, current is carried by the flow of electrons. In semiconductors, current can be carried either by the flow of electrons or by the flow of positively-charged "holes" in the electron structure of the material.
-See <http://en.wikipedia.org/wiki/Semiconductor>
-semi-empirical methods: Semi-empirical quantum chemistry methods are based on the Hartree-Fock formalism, but make many approximations and obtain some parameters from empirical data. They are very important in computational chemistry for treating large molecules where the full Hartree-Fock method without the approximations is too expensive. The use of empirical parameters appears to allow some inclusion of electron correlation effects into the methods.
-Within the framework of Hartree-Fock calculations, some pieces of information (such as two-electron integrals) are sometimes approximated or completely omitted. In order to correct for this loss, semi-empirical methods are parametrized, that is their results are fitted by a set of parameters, normally in such a way as to produce results that best agree with experimental data, but sometimes to agree with ab initio results.
-See <http://en.wikipedia.org/wiki/Semi-empirical_quantum_chemistry_methods>
-SOI: Silicon-on-insulator technology (SOI) refers to the use of a layered silicon-insulator-silicon substrate in place of conventional silicon substrates in semiconductor manufacturing, especially microelectronics, to reduce parasitic device capacitance and thereby improving performance.
-See <http://en.wikipedia.org/wiki/Silicon_on_Insulator>
-In Schred, SOI means "semiconductor-oxide-insulator."
-SOS: semiconductor-oxide-semiconductor (see about page for Schred).
-SPICE: Simulation Program with Integrated Circuit Emphasis
-In 1973, SPICE was introduced to the world by Professor Donald O. Pederson of the University of California at Berkeley, and a new era of computer-aided design (CAD) tools was born. As its name implies, SPICE is a "Simulation Program with Integrated Circuit Emphasis." You give it a description of an electrical circuit, made up of resistors, capacitors, inductors, and power sources, and SPICE will predict the performance of that circuit. Instead of bread-boarding new designs in the lab, circuit designers found they could optimize their designs on computers–in effect, using computers to build better computers. Since its introduction, SPICE has been commercialized and released in a dozen variants, such as H-SPICE, P-SPICE, and ADVICE.
-See <http://nanohub.org/tags/circuits>
-SPICE3f4: developed at the University of California, Berkeley
-spintronics: Spintronics (a neologism meaning "spin transport electronics"), also known as magnetoelectronics, is an emerging technology which exploits the intrinsic spin of electrons and its associated magnetic moment, in addition to its fundamental electronic charge, in solid-state devices.
-See <http://en.wikipedia.org/wiki/Spintronics>
-state: a single solution to Schrödinger's equation defined by a unique set of quantum numbers
-See <http://ecee.colorado.edu/~bart/book/contents.htm>
-surface state: midgap state caused by the termination of the lattice at the surface of a semiconductor
-See <http://ecee.colorado.edu/~bart/book/contents.htm>
-TCAD: Technology Computer Aided Design
-TEDVis: Theoretical Electron Density Visualizer
-thermal transport: Thermal transport at sub-micron scales differs substantially from that at normal length scales. Physical laws for heat transfer, such as Fourier's law for heat conduction, fail when the mean free path of energy carriers becomes comparable to the length scales of interest. This occurs in modern microelectronic devices, where for example, channel dimensions, now below 100 nm in length, are comparable to the mean free path of phonons in silicon at room temperature. Research in the nanoscale thermal transport area addresses novel physics at small length and time scales and novel technologies that exploit this class of physics.
-See <http://nanohub.org/tags/thermaltransport>
-thermodynamics: In physics, thermodynamics (from the Greek θερμ-<θερμότης, therme, meaning "heat" and δυναμις, dynamis, meaning "power") is the study of the conversion of energy into work and heat and its relation to macroscopic variables such as temperature and pressure. Its underpinnings, based upon statistical predictions of the collective motion of particles from their microscopic behavior, is the field of statistical thermodynamics, a branch of statistical mechanics. Historically, thermodynamics developed out of need to increase the efficiency of early steam engines.
-See <http://en.wikipedia.org/wiki/Thermodynamics>
-thyristors:
-tight-binding: In solid-state physics, the tight-binding model is an approach to the calculation of electronic band structure using an approximate set of wavefunctions based upon superposition of wavefunctions for isolated atoms located at each atomic site. The method is closely related to the linear combination of atomic orbitals molecular orbital method used for molecules.
-See <http://en.wikipedia.org/wiki/Tight-binding_model>
-time-independent
+"Sponsored by" lines should omit "NSF" from before Network for Computational Nanotechnology.
+    (NSF will remain if a specific grant number is listed.)
-transistor: contraction of transresistance, a term used to describe a resistance which is controlled by a voltage at another node
+toward (not "towards")
-See <http://ecee.colorado.edu/~bart/book/contents.htm>
-tunneling: quantum mechanical process by which a particle can pass through a barrier rather than having to go over a barrier
+Spacing guidelines:
-See <http://ecee.colorado.edu/~bart/book/contents.htm>
+Newer print and online publishing styles indicate a preference for single spacing where of double spacing used to be the standard. Chicago guidelines also stipulate that there should be one space between sentences instead of two. The same holds true of spacing following colons and semicolons.
-Vander Walls, van der Walls (tag also in Carbon nanotube based fixed-fixed NEMS): In physical chemistry, the van der Waals force (or van der Waals interaction), named after Dutch scientist Johannes Diderik van der Waals, is the attractive or repulsive force between molecules (or between parts of the same molecule) other than those due to covalent bonds or to the electrostatic interaction of ions with one another or with neutral molecules.
+== Punctuation ==
-See <http://en.wikipedia.org/wiki/Van_der_Waals_force>
-visualization: Simulators can produce all sorts of numbers, but the numbers themselves aren't terribly meaningful until they are put into context by visualization techniques. For example, the coordinates of the various atoms in a molecule don't readily convey the shape of the molecule. But once those coordinates are loaded into VMD, the the resulting picture conveys not only the shape of the molecule, but other important properties as well.
+''Commas''
-See <http://nanohub.org/tags/visualization>
-wavefunction: mathematical tool used in quantum mechanics to describe any physical system. See <http://en.wikipedia.org/wiki/Wavefunction>
+Commas should generally be used (1) at the end of a dependent clause (or introductory clause) preceding a main clause; (2) between items in a list of three or more items, including before the conjunction "and" or "or"; (3) surrounding interjections and descriptive phrases; (4) separating two or more adjectives modifying a noun.
-workfunction:
+Clauses and use of commas:
+Commas should not be inserted before a restrictive subordinating clause. If the subordinating clause is essential to the meaning of the main clause, commas preceding the subordinate clause are not needed. need example
-well: doped region of opposite doping type used in a CMOS process
+''Colon''
-See <http://ecee.colorado.edu/~bart/book/contents.htm>
-zeta function
+The initial word after a colon should be uppercase if what follows the colon is a complete sentence; otherwise, the initial word after a colon will be lowercase.