术语表 Glossary#

AC#: alternating current.
alpha decay#: (𝛼) happens when a nucleus emits an alpha particle, otherwise known as a ⁴He nucleus.
alpha particle#: (𝛼) is a ⁴He (helium) nucleus, ejected from a larger nucleus in an alpha decay It therefore consists of two protons and two neutrons.
Ampere#
Amp#: (A, or Amp) is the SI unit of current, defined such that one Ampere is the same as one Coulomb per second (1 A = 1 C/s)
Annual Energy Review#
AER#: is compiled by the U.S. EIA, capturing energy use and trends for all sources and sectors.
Astronomical Unit#
AU#: is a unit of distance, equal to the average Earth-Sun distance of 149.6 million kilometers (1.496 × 10¹¹ m).
asymmetric risk#: describes a condition where given the choice to pursue action B for fear of some future condition instead of the normal action A, the downside of being correct about the threat and not taking action B is far more disastrous than being wrong about the threat and pursuing route B unnecessarily.
atomic mass unit#
a.m.u.#: is defined so that a single neutral carbon atom, consisting of 6 protons, 6 neutrons, and 6 electrons has exactly 12.00000 a.m.u. In other units, it is 931.4941 MeV or 1.66054 × 10^-27 kg. This unit sometimes goes by the name: Dalton.
Avogadro's number#: is 𝑁_A = 6.022 × 10²³, pertaining to one mole of particles (e.g., atoms, molecules).
band gap#: is the energy difference between the conduction band and the valence band, determining how much energy is needed to promote an electron out of an atom and into conduction.
barrel#: (bbl) is a unit of volume used primarily for petroleum. It is exactly 42 U.S. gallons, amounting to 159 L of volume. A commonly used measure of energy is barrels of oil equivalent (b.o.e.), amounting to 6.1 GJ of combustion energy.
beta decay#: (𝛽) happens when a nucleus emits either an electron (𝛽−) or a positron (𝛽+).
Betz limit#: is a theoretical maximum amount of kinetic energy power that can be removed from wind without slowing the wind too much. It computes to 16/27, or 59%, and is independent of technology.
Big Bang#: is the name given to the start of the universe, about 13.8 billion years in the past.
biofuel#: describes a liquid chemical fuel derived from biologically grown plants: algae, sugar, corn, rapeseed, etc. The two most common forms are ethanol and biodiesel.
biomass#: is a generic term for biological matter, but in the energy context usually means firewood or dung that may be burned for thermal energy.
birth rate#: quantifies the number of births per 1,000 people per year, typically. Numbers tend to be in the 10-50 range.
blackbody#: is a term describing the radiative qualities for thermal emission of light (infrared radiation for "normal" temperatures, becoming visible for very hot objects). A perfect blackbody is not reflective (i.e., "black" at the wavelengths of interest) and emits energy as a function of wavelength according to the Planck spectrum.
boiling water reactor#: is a type of nuclear fission reactor in which water surrounding the fuel rod acts both as a moderator and as the means of transporting heat away from the nuclear fuel.
Boltzmann constant#: is a fundamental constant of nature associated with thermodynamics. In SI units, it has a value of 𝑘_B = 1.38 × 10^-23 J/K.
breeder reactor#: is a nuclear fission reactor that transforms non-fissile nuclei into ones that are fissile by means of neutron capture and subsequent radioactive decay.
breeding#: see breeder reactor.
British thermal unit#
Btu#: is a unit of energy in the Imperial unit system, defined as the amount of energy required to heat one pound of water by 1 °F. It is equivalent to 1,055 Joules.
calorie#: (cal) is a unit of energy, defined as the amount of energy required to heat one gram (1 g, 1 mL, 1 cm³) of water by 1 ℃. It is equivalent to 4.184 Joules.
Calorie#: (cal) is a unit of energy, defined as the amount of energy required to heat one kilogram (1 kg, 1 L, 1,000 cm³) of water by 1 °C. It is equivalent to 4,184 Joules.
capacity factor#: is the fraction of energy delivered by an installation compared to what it would deliver if operating continuously at peak operating ("nameplate") capacity.
caprock#: is a geological feature of impermeable rock that can trap oil, gas, or steam below it.
carrying capacity#: refers to the limiting population that can be supported long-term by the environment. No consensus exists for Earth's carrying capacity for humans, though standards of living have a large influence.
CFL#: compact fluorescent light.
chain reaction#: is a self-feeding process that keeps itself going. In the context of nuclear fission, neutrons released by the fission precipitate the next fission event, and so on.
charge#: is a measure of the degree to which a particle or object is influenced by electromotive forces. Electric charge can be positive or negative, so that like charges repel and opposites attract. The unit for electric charge is the Coulomb.
Chart of the Nuclides#: is a Periodic Table on steroids, listing the properties of every known nuclide including mass or energy, abundance (if stable), half life (if unstable), decay mode, neutron cross section, nuclear spin, and other salient properties; see https://people.physics.anu.edu.au/~ecs103/chart/.
chemical energy#: is energy stored in chemical bonds, like gasoline or wood that might be burned, or in the food we eat.
climate sensitivity parameter#: relates a change in radiative forcing to the net temperature change once all the feedback mechanisms have acted. The units are °C per W/m₂, and a typical value is 0.8.
coefficient of performance#
COP#: refers to the energy gain by a heat pump, usually in the context of heating rather than cooling. It is identical to 𝜀 , as defined in Eq. 6.11
compound#: describes a particular combination of elements that construct a particular molecule. For instance, H:sub:`2`O is the compound we know as water.
concentrated solar power#
CSP#: (CSP) refers to a form of solar thermal (ST) energy, employing troughs or "power towers" or any technique that focuses solar power to create high temperatures, often then used to generate electricity.
conduction band#: is the energy level a step up from that of electrons in the valence band. Electrons in the conduction band are very loosely bound and freely wander about the crystal, hopping from one atom to the next, and therefore able to contribute to a current.
confinement#: in the context of fusion refers to the trapping and holding of a high-temperature plasma, usually by magnetic means.
conservation of energy#: says that energy is never created or destroyed, only shifting from one form to another.
conservation of mass-energy#: extends conservation of energy to include mass, so that the combined mass-plus-energy of a closed system is never created or destroyed, only shifting from one form to another (mass-energy exchange via E = mc²).
control rod#: is used in a nuclear fission reactor to absorb neutrons so that the chain reaction does not get out of control and cause a meltdown.
Coulomb#: (C) is the SI unit of electric charge. An electron has a charge of −1.6 × 10^-19 C and a proton has a charge of +1.6 × 10^-19 C
coupled#: refers to the tight connection often seen between energy/resource use and economic scale (as measured, for instance, by GDP).
critical mass#: is the mass of fissile material (assumed to be in spherical form) above which a self-sustained chain reaction will occur. Below this, the material poses no danger. Right at critical mass, the material will limp along in a slow chain reaction. Above this threshold—super-critical—an exponential growth runaway detonation will occur, and is the basis of nuclear weapons. For :sup:`235`U, critical mass is 50 kg (a bit smaller than a volleyball), and for :sup:`239`Pu, it is 10 kg, and about the size of an American softball.
current#: is a measure of charge flow, expressed in the SI unit of Amps.
D-D fusion#: uses deuterons (^{2`H nuclei) as the fuel for :term:`fusion}, achieving an energy density of 87 million kcal/g.
D-T fusion#: combines a deuteron (^{2`H nucleus) and a triton (:sup:`3`H) as the
fuel for :term:`fusion}, achieving an energy density of 80 million kcal/g.
death rate#: quantifies the number of deaths per 1,000 people per year, typically. Numbers tend to be in the 5-20 range.
decay chain#: refers to a consecutive series of radioactive decay events.
decoupling#: is the notion that economic activities need not incur a large energy or resource cost, breaking the tendency for economic scale to be tightly coupled to physical goods.
demographic transition#: refers to the process in which an undeveloped country initially having high birth rate and high death rate transitions to low death rates followed by low birth rates as medical and resource conditions improve.
deuterium#: is an isotope of hydrogen, in which the nucleus (called a deuteron) contains one proton and one neutron.
deuteron#: is the nucleus of deuterium, consisting of one proton and one neutron.
dietary energy factor#: is the quantitative energy impact of a set of dietary choices compared to a vegetarian diet. A typical American diet has a dietary energy factor around 2, meaning it takes twice as much energy as would a vegetarian diet. This term is not in universal use.
differential equation#: is an equation that relates functions and their derivatives. The subject is often sequenced after calculus within a curriculum.
doping#: is a process by which deliberate impurities are introduced into a semiconductor in order to change its properties with respect to transport of electrons or holes.
doubling time#: is how long it takes a system or collection to double its amount under conditions of growth, such as in exponential growth.
duty cycle#: refers to the percentage of time something is "active." For example, a refrigerator may be on 40% of the time to maintain internal temperature, in which case its duty cycle is 40%.
Ecological Economics#: is a field that builds economic theory on top of the notion that the planet offers finite resources and flows. A principle aim is that of a steady-state economy capable of indefinite planetary compatibility.
EIA#: Energy Information Administration.
Electric Power Monthly#
EPM#: (EPM) is compiled by the U.S. EIA, capturing electricity production and usage at the state level from all energy sources.
electromagnetic radiation#: refers to any transport of energy by electromagnetic waves, which include light, ultraviolet, infrared, X-rays, microwaves, gamma rays, and radio waves.
electromagnetic spectrum#: refers to the sweep of wavelengths or frequencies of electromagnetic radiation, including light, ultraviolet, infrared, X-rays, microwaves, gamma rays, and radio waves.
electron#: is a fundamental particle typically found in the outer parts of atoms, surrounding the nucleus. Electrons have negative charge equal and opposite to that of protons, but are 1,836 times lighter than the proton, at 0.511 MeV.
electron-volt#: (eV) is a unit of energy, defined as the energy (work) it takes to push a charge of one fundamental charge unit (see entry for Coulomb) through an electric potential of one Volt. 1 eV is equivalent to 1.6 × 10^-19 Joules.
element#: pertains to a single atom on the Periodic Table. For instance, hydrogen, helium, and carbon are all elements.
energy#: is defined as the capacity to do work. The SI unit is the Joule.
energy density#: describes how concentrated energy is in a substance, quantified as energy per unit mass. In chemical contexts, anything around 10 kcal/g or higher is considered energy-dense, while substances at about 5 kcal/g or lower are poor. Carbohydrates and proteins are middling, around 4 kcal/g, while fat is 9 kcal/g, and therefore among the more energy-dense substances.
energy efficiency ratio#
EER#: refers to the energy gain by a heat pump, usually in the context of cooling rather than heating. Its units are odd, defining how many British thermal units (thermal energy) may be moved per Watt-hour of input energy, but relating to 𝜀 (defined in Eq. 6.10 (p. 95)) by a simple cool numerical factor: EER = 3.41𝜀 . Sometimes seen as SEER to represent a seasonal average EER cool value.
energy intensity#: measures the energy use of a society relative to its economic scale. A typical value may be about 5 MJ/$.
energy trap#: refers to a phenomenon in which energy shortage motivates aggressive pursuit of alternative energy schemes, but that pursuit requires substantial energy investment—forcing an even more acute but voluntary energy shortage, which is politically difficult.
enriched#: see enrichment.
enrichment#: refers to the process of increasing the concentration of a particular isotope within a sample of an element. Usually, this term is applied to the concentration of :sup:`235`U from its natural 0.7% to 3–5% for power plants or >90% (typically ~94%) for weapons.
entropy#: is a measure of how many ways a system can be configured for some fixed energy level. The entropy of a closed system cannot decrease.
Environmental Economics#: is an offshoot of neo-classical economics that adds a layer of pricing to capture "externalities," or environmental costs not normally included in market price.
EROEI#: Energy Returned on Energy Invested: a measure of how profitable an energy source is in terms of energy, expressed as a ratio. For instance, a 10:1 EROEI means 10 units were extracted or produced for an investment of 1 unit, leaving a net gain of 9 units of energy. 1:1 is break-even, deriving no net energy benefit.
estimated total resource#: is an educated extrapolation of proven reserve trying to characterize the amount of resource that may be ultimately found and extracted.
ethanol#: (C_{2`H:sub:`5`OH) is a liquid alcohol frequently produced as a :term:`biofuel} having an energy density of ~7 kcal/g.
eV#: electron-volt.
exponential growth#: happens when the rate of growth—as a percentage or fraction—is constant.
feedback#: is the response of a system when a change is made that itself influences the change: either counteracting it as in negative feedback or amplifying it as in positive feedback.
fill factor#: is a generic term describing the fraction of total area occupied. For instance a polka-dot pattern of circles on a piece of fabric might have a fill factor of 50%.
fissile#: describes a nucleus that is prodded into fission by a (slow) thermal neutron. The three fissile nuclides of interest are :sup:`233`U, :sup:`235`U, and :sup:`239`Pu.
fission#: is a nuclear process in which a heavy nucleus splits into two lighter nuclei. Only ^{233`U, :sup:`235`U, and :sup:`239`Pu are usually considered as
accessible :term:`nuclides<nuclide>} that are fissile in the presence of slow (thermal) neutrons.
flexitarianism#: is the practice of pursuing dietary choices based on quantitative assessment of energy costs in an effort to keep the dietary energy factor low, without enforcing complete strictness, enjoying the occasional deviation on special occasions or just to avoid being a pain to others.
fossil fuel#: refers to an energy source buried in the ground, in the form of coal (solid), petroleum (liquid), or natural gas (gaseous). Fossil fuels represent ancient solar energy captured in living matter, processed and stored underground over millions of years.
fracking#: is slang for hydraulic fracturing, a technique used to extract "tight" oil and gas resources locked up in less permeable rock formations. High-pressure fluids are used to create cracks in the rock that allow oil and/or gas to flow.
frequency#: characterizes the number of cycles per second in a periodic phenomenon (often in wave phenomena). The units are Hertz, or 1/s.
fuel rod#: is a long cylinder having a high-enough concentration of fissile material to be used in a nuclear fission reactor.
fusion#: is a nuclear process in which two light nuclei merge to form a larger nucleus. Repulsion of the charges in the nuclei make it exceedingly hard to achieve, requiring temperatures of many millions of degrees.
galaxy#: is a collection of stars held together by mutual gravitational attraction, generally numbering in the billions of stars.
gamma decay#: (𝛾) is when a nucleus in an energetically excited state emits a high-energy photon.
gamma ray#: (𝛾) is a high-energy photon, as may be generated by a gamma decay or by annihilation of an electron and positron.
GDP#: Gross Domestic Product, effectively representing the total monetary flow of goods and serviceswithin a society, typically over a one year period.
generator#: converts mechanical motion (rotation, typically) into electrical current, generally by the relative motion of wire loops and a strong magnetic field.
geothermal#: refers to thermal energy within the earth, both from the original heat of formation and from radioactive decay.
Gppl#: is a short-hand unit for giga-people, or billion people.
gravitational potential energy#: is the energy stored in a mass, m, lifted a height, h, above some reference in the presence of gravity, g ≈ 10 m/s². The energy amounts to mgh, and will be in Joules if the inputs are in kg, m, and s.
Green Revolution#: refers to the modernization of agricultural practices worldwide beginning around 1950, when fossil fuels transformed both fertilization and mechanization.
greenhouse gas#: (GHG) absorbs infrared radiation and acts as a thermal blanket in a planetary atmosphere. H₂O, CO₂, and CH₄ are powerful greenhouse gases.
grid tied#: refers to a photovoltaic system connected to the local electrical utility grid, enabling export of solar production by day and use of utility electricity by night.
half life#: is the time after which half a sample of radioactive nuclei will have undergone radioactive decay. After N half-life periods, the remaining fraction will be 1/2^N.
heat capacity#: is the amount of energy it takes to raise an object's temperature by 1◦C. The specific heat capacity is the heat capacity divided by mass, becoming an intrinsic property of the material. Water's specific heat capacity is 4,184 J/kg/℃, intimately tied to the definition of the kilocalorie.
heat engine#: is a device that converts thermal energy into another form, usually mechanical motion. Automobile engines are a common example, as are power plants that create steam from a thermal source that itself drives a turbine and generator.
heat loss rate#: as used in this book is the power per Δ𝑇 (in ◦C) required to maintain a temperature differential. Units are W/◦C, and typical houses might be a few hundred W/◦C.
heat of fusion#: is the energy barrier associated with either forming (fusing) or melting a solid from a liquid. In the case of water (ice), the heat of fusion is 335 J per gram.
heat of vaporization#: is the energy barrier associated with turning a liquid into gas. In the case of water going to water vapor, the heat of vaporization is about 2,260 J per gram.
heat pump#: is a device that moves thermal energy from a cold environment to a hotter one, against normal flow. Some energy input is required to drive this reverse flow, but thermodynamic principles permit a small amount of input energy to drive a larger amount of thermal energy transfer.
heating seasonal performance factor#
HSPF#: refers to the energy gain by a heat pump in the context of heating, but in the same units as the EER so that HSPF is COP times 3.41, numerically.
heavy oil#: refers to oil that is very viscous—closer to tar than to gasoline. Heavy oil is more difficult to extract, process, and obtain gasoline via refinement.
Hertz#: (Hz) is the SI unit for frequency, and is equivalent to cycles per second, or 1/s.
hockey stick#: is a term used to describe plots that suddenly shoot up after a very long time of relative inaction. Plots of human population, atmospheric CO₂, energy use, all tend to show this 2 characteristic—which resembles an exponential curve.
hole#: in the context of semiconductors is the absence of an electron—or an electron vacancy. When another electron fills the hole, it leaves behind another hole, and it is as if the hole moved—effectively like a positive charge able to roam through the crystal.
HST#: Hubble Space Telescope.
hydrocarbon#: is a chain of carbon and hydrogen atoms such as the alkanes (methane, ethane, propane, butane, octane, etc.) having chemical formula C_{n`H:sub:`2n+2}, where n = 1 for methane, 2 for ethane, 8 for octane, etc.
hydrological cycle#: is the solar-driven process by which evaporation of water from the surface (bodies of water or moist land) forms clouds, and the clouds deliver rain back to the surface.
infrared radiation#: is the property that all objects glow in light, or electromagnetic radiation. For objects that are not "red hot," the emission is invisible to the human eye, at longer wavelengths than the visible spectrum. The power radiated obeys the Stefan-Boltzmann law.
insolation#: is the annual average solar flux reaching flat, level ground for a particular location. A typical number is 200 W/m², but can range from half that at high latitudes to about 300 W/m² for arid areas at lower latitudes.
inverse function#: is a mathematical operation that "undoes" its counterpart, like the square root undoes the square, or the natural logarithm undoes the exponential.
isotope#: is what we call atoms that have various nuclear configurations for the same element. That is, variants of a nucleus having the same number of protons but differing numbers of neutrons, and therefore differing mass number.
ISS#: International Space Station.
Jevons paradox#: is named after early economist William Stanley Jevons, and describes the backfire of efficiency improvements leading to increased usage of the associated resource due to greater demand for the more attractive, efficient technology. Also called the rebound effect.
Joule#: (J) is the SI unit of work or energy, and is equivalent to Newtons times meters (N·m), or kg · m²/s²
junction#: describes an interface between two semiconductors that have different doping. Junctions are the basis of photovoltaic, diodes, light emitting diodes (LEDs), transistors, and many light detectors.
Kill-A-Watt#: is the name of a relatively inexpensive device that can measure instantaneous power in Watts and accumulated energy in kWh of electrical appliances. The name is a pun on units.
kilocalorie#
kcal#: (kcal) is a unit of energy, equivalent to 1,000 calories, defined as the amount of energy required to heat one kilogram (1 kg, 1 L, 1,000 cm³) of water by 1 °C. It is equivalent to 4,184 Joules.
kilowatt-hour#: (kWh) is a unit of energy, constructed as a power (kilowatts) times time (hours). It is equivalent to 3,600,000 Joules, or 3.6 MJ.
kinetic energy#: is the energy of motion, given by 1/2 𝑚𝑣² for a mass, 𝑚, at velocity, 𝑣. If input units are kg and m/s, the resulting unit will be Joules.
kWh#: kilowatt-hour.
LED#: light emitting diode.
life-cycle CO2 emission#: is an assessment of how much CO₂ is released from an energy source when considering the entire enterprise—including manufacture/construction, operation, etc. See the Wikipedia page on List of life-cycle greenhouse gas emissions.
liquefied natural gas#
LNG#: (LNG) is cryogenically-cooled natural gas (methane) at −160 °C that can be stored much more compactly than the gaseous form, making it suitable to transport.
logistic#: describes a mathematical model in which rate of growth depends on how close the population is to the carrying capacity. The resulting population curve over time is called the logistic function, or more informally, an S-curve.
macro-economics#: concerns itself with the allocation of goods and services across the marketplace, optimizing supply and demand, aiming to minimize surplus or deficits.
mass number#: (A) is simply the total number count of protons and neutrons (nucleons) in a nucleus. For example, a carbon atom having 6 protons and 6 neutrons has A = 12.
meltdown#: refers to a failure mode of nuclear fission reactors, in which the chain reaction becomes uncontrolled due to too many neutrons triggering new fission events (as may happen if control rod is absent or insufficiently deployed).
MeV#: is a mega-electron-volt, or 10⁶ eV. In Joules, it is equivalent to 1.6 × 10^-13 J. Nuclear masses are often expressed in MeV/c² terms, where 1 a.m.u. is equivalent to 931.4941 MeV.
micro-economics#: concerns itself with the production of goods, including raw resources, marketing, and distribution.
micron#: (𝜇m) is 10⁻⁶ meters, or a micro-meter.
moderator#: in the context of nuclear fission is a material used to slow down neutrons speeding out from the break-up so that they can become thermal neutrons and stimulate subsequent fission events in a chain reaction. Light atoms like water are a good choice for absorbing the neutron impacts.
molar mass#: is the mass of one mole of an element or compound. The molar mass for carbon, for instance, is 12 grams. The number is often found on a Periodic Table, in addition to the proton number for the element.
mole#: is a number of atoms or molecules, tuned so that one mole of the carbon-12 isotope is exactly 12.000 grams. It takes 6.022 × 10²³ atoms for this to happen, which is called Avogadro's number.
negative feedback#: involves a reaction to some stimulus in the direction opposite the stimulus, performing a corrective action and leading to stability. Systems in equilibrium must have negative feedback keeping them there.
neo-classical economics#: is the prevailing economic regime practiced today, driven by supply and demand, fueled by growth, market investment, and focus on micro-economics and macro-economics.
neutrino#: is a fundamental particle associated with the weak nuclear force that has almost no mass, travels near the speed of light, and interacts so weakly with matter that it could pass through light-years of rock before being likely to hit anything. Neutrinos from the sun stream through our bodies constantly, day and night, since Earth is transparent to them.
neutron#: is one of two basic building blocks of atomic nuclei, the other being the proton. Neutrons have no electric charge, and a mass of 939.565 MeV, or 1.008665 atomic mass unit (a.m.u.). Neutrons are made up of three quarks: 1 up and 2 down.
Newton#: (N) is the SI unit of force, and is equivalent to kg · m/s²
nuclear binding energy#: is the energy associated with the strong nuclear force that holds a nucleus together against charge repulsion. Typical levels are 8 MeV per nucleon.
nuclear energy#: derives from reconfiguring the nuclei of atoms, releasing tremendous thermal energy that can be harnessed in a heat engine.
nucleon#: is either of the two building blocks of a nucleus, meaning that it is either a proton or a neutron.
nucleus#: is at the center of an atom, composed of protons and neutrons and spanning ∼ 10^-15 m. The vast majority (99.97%) of an atom's mass is in the positively charged nucleus, which attracts a cloud of negative-charge electrons to complete the neutral atom.
nuclide#: is any bound arrangement of protons and neutrons. Every nucleus of every isotope is one of the possible nuclides, designated, for instance as ^{12`C, C-12, or :sup:`12}C.
overshoot#: occurs when the negative feedback in a system is delayed. After surpassing the equilibrium, oscillation may ensue.
parts per million#
ppm#: is a unit used to measure small contributions. One ppm is 0.0001%.
parts per million by mass#: (ppm_m) is a parts per million measure in terms of fractional mass. For instance, a gram is 1 ppm_m of a metric ton (1,000 kg).
parts per million by volume#: (ppm_v) is a parts per million measure in terms of fractional volume occupied. For instance, a cubic millimeter (1 𝜇m, or micro-liter) is 1 ppm_v of a liter.
payback time#: is how long it takes to recuperate an investment by removing a chronic cost. For example, spending $3,000 to no longer pay an annual $300 charge has a payback time of 10 years.
photon#: is the smallest indivisible particle of light: a minimum quantum packet of energy. Each photon has a well defined energy, which can also be expressed as a wavelength or frequency.
photosynthesis#: is the process by which living matter captures sunlight and stores some of it as chemical energy. Effectively, it takes CO₂ out of the atmosphere, combines the carbon with water to make sugars, releasing oxygen back into the air.
photovoltaic#
PV#: (PV) is a semiconductor technology by which light directly drives an electrical current by interacting with electrons in the material.
Planck spectrum#: describes a mathematically precise spectrum of light emission from a blackbody, fully defined by the temperature of the blackbody.
Planck's constant#: is a fundamental constant of nature associated with quantum mechanics and the world of the very small. In SI units, its value is h = 6.626 × 10^-34 J · s
plasma#: is a gas hot enough to strip electrons from atoms to create a highly-ionized medium, such as the gas comprising the sun.
positive feedback#: involves a reaction to some stimulus in the same direction as the stimulus, thus amplifying the effect. Positive feedback leads to an unstable, runaway process—like exponential growth.
positron#: is an elementary particle of anti-matter, and specifically an anti-electron, having the same mass and opposite charge as the electron and will annihilate with an electron into gamma rays.
power#: is the rate of energy, or change in energy per change in time. The units are Joules per second (J/s), or Watts (W).
predicament#: describes a seemingly intractable situation: more than a problem, but possibly a tangled set of interconnected problems. Predicaments require responses rather than tidy solutions.
proliferation#: is used to describe widespread distribution of dangerous nuclear materials, which becomes difficult to control if they exist in abundance due to increased reliance on nuclear energy.
proton#: is one of two basic building blocks of atomic nuclei, the other being the neutron. Protons have positive charge, equal and opposite to that of the electron. Protons have a mass of 938.272 MeV, or 1.0072765 a.m.u.. Protons are made up of three quarks: 2 up and 1 down.
proven reserve#: pertains to the amount of resource known to exist, having been discovered and surveyed to a degree of certainty.
Quadrillion#
Quad#: is 10¹⁵ British thermal units, and is equivalent to 1.055 × 10¹⁸ Joules.
R-value#: describes the thermal resistance, or insulating quality of a wall or similar barrier. It is an inverse to the U-value, numerically 5.7/𝑈. Units are ◦F ·ft² · hr/Btu, and larger numbers translate to better insulation.
R/P ratio#: or reserves-to-production ratio is a means to assess time remaining for a resource of quantity R units, being used (produced) at a rate of P units per year. The result is years available at the present rate, absent discovery of additional resources or change in rate of use.
radiation#: is a broad term that can describe light (e.g., electromagnetic radiation, infrared radiation, gamma rays) or particles from radioactive decay or cosmic origin. High-energy radiation of any form can cause damage to materials and biological tissues (DNA being perhaps most critical).
radiative forcing#: is used to describe the areal power (in W/m₂) of absorbed solar energy and infrared radiation to space. In equilibrium, a balance exists so that the net radiative forcing is zero.
radioactive#: describes a nucleus, or nuclide that is unstable and will undergo radioactive decay with some half life.
radioactive decay#: involves a change in the nucleus of an atom, most commonly in the form of alpha decay, beta decay, or gamma decay.
rebound effect#: describes the counterintuitive process by which efficiency improvements lead to greater use of the resource as the enhanced appeal and lower cost results in more widespread adoption and use. Also called the Jevons paradox.
recombination#: is when an electron in the conduction band of a semiconductor finds a vacancy (hole) for it to settle into. By disappearing from the conduction band, it is no longer available to contribute to current, and the energy it had becomes unrecoverable.
rule of 70#: is a quick estimation tool: divide 70 by the percentage growth rate to get the doubling time. Its units depend on how the time over which percentage growth is expressed—like 2% per day or 7% per year, for instance. The rule works most accurately for smaller growth rates, under 10%.
sea level rise#: is one of the inevitable consequences of climate change, as land-bound ice melts and ocean water thermally expands.
sector#: refers to a domain of activity, typically dividing into residential, commercial, industrial, and transportation.
semiconductor#: is a material poised between being a good conductor of electrical current and an insulator (not passing current). Silicon is the most commonly used semiconductor.
SI#: Système International.
solar constant#: measures 1,360 W/m², and is the power flux of the sun at the top of Earth's atmosphere. It is not technically a constant, but is very stable.
solar system#: refers to our own star, the sun, and the planets that surround it, including Earth.
solar thermal#
ST#: (ST), also called concentrated solar power (CSP), typically refers to troughs or "power towers" or any technique that focuses solar power to create high temperatures, often then used to generate electricity via a heat engine and generator.
spectrum#: describes a distribution, often associated with light. In this context, a light spectrum specifies how much light is present as a function of wavelength or frequency. The Planck spectrum is a good example.
Stefan-Boltzmann constant#: (𝜎) has a value of 5.67 × 10^-8 W/m²/K⁴ and is used in the Stefan-Boltzmann law relating to infrared radiation.
Stefan-Boltzmann law#: says that the power emitted from a surface of area, 𝐴, and temperature, 𝑇 will be 𝑃 = 𝐴𝜎𝑇⁴, where 𝜎 is the Stefan-Boltzmann constant.
stoichiometry#: amountstothecountingofatomsandbalancingformulasinchemicalreactionstoreflectthe survival of everyatom in a reaction: none createdordestroyed.
strong nuclear force#: is the force that binds nucleons together in a nucleus, overcoming the electrical repulsion of protons.
substitution#: refers to interchangeability between goods and services, so that an unavailable or inferior resource can be replaced by an alternative, possibly superior one.
terraforming#: is the speculative idea of transforming the atmosphere and environment of a planet hostile to human life into one that is suited to human needs.
Therm#: is a unit of energy defined as 100,000 British thermal units, and is equivalent to 1.055 × 10⁸ Joules.
thermal energy#: is the energy of heat, and is really just randomized kinetic energy (motion) of atoms and molecules vibrating and zipping around.
thermal equivalent#: is a construct used to compare thermal energy sources like coal, oil, and natural gas to sources like solar, wind, and hydroelectricity, which do not derive from thermal sources. Usually in the context of electricity production, multiplying by about 2.7 puts non-thermal sources into thermal-equivalent terms.
thermal expansion#: describes how materials expand, or swell, as temperature increases. Typical rates of expansion are in the range of 10–100 ppm per °C.
thermal neutron#: is a neutron whose kinetic energy (speed) is no greater than it would naturally possess based on the temperature of its surroundings. Sometimes it is called a "slow" neutron because it is not traveling faster than thermal jostling would establish.
tokamak#: is the name of a donut-shaped chamber in which high-temperature plasma can be confined, and potentially used to generate fusion.
transmutation#: describes the transformation of a nucleus into a different one, usually via neutron absorption—possibly followed by radioactive decay.
tritium#: is an isotope of hydrogen, in which the nucleus (called a triton) contains one proton and two neutrons.
triton#: is the nucleus of tritium, consisting of one proton and two neutrons.
turbine#: is essentially fan blades on a rotating shaft, which can be compelled to move by a flow of air, water, or steam through the blades.
U-value#: describes the insulating quality of a wall or similar barrier, in terms of how many Watts move through each square meter of surface area for each 1 ◦C difference in temperature across the barrier. Units are W/m²/◦C, and smaller numbers mean better insulation. The U-value is an inverse measure to the R-value, numerically 5.7/𝑅.
valence band#: is the energy level of outer electrons bound to an atom. Valence electrons stay home, as opposed to electrons in the conduction band.
Volt#: (V) is a unit of voltage, or electric potential, and can be thought of as the electrical analog to gravitational potential energy, and is also somewhat like pressure in a fluid system.
voltage#: is a measure of electric potential energy, expressed in units of Volts.
Watt#: (W) is a unit of power, defined so that 1 W is 1 J/s (one Joule per second).
watt-hour#
Wh#: (Wh) is a unit of energy, constructed as a power (watts) times time (hours). It is equivalent to 3,600 Joules, or 3.6 kJ.
wavelength#: measures the length of a wave from crest to crest or trough to trough, and can apply to waves in water, air (sound), or electromagnetic waves (light). The symbol 𝜆 (lambda) is often used to denote wavelength. The units are length (m), often expressed in microns (𝜇m).
weak nuclear force#: joins gravity, electromagnetism, and the strong nuclear force as one of nature's four fundamental forces, responsible for beta decay and neutrino interactions.
Wien law#: describes the wavelength for which the Planck spectrum is at maximum brightness. It is roughly 2.9 mm divided by the blackbody temperature, in Kelvin.
work#: is a mechanical expression of energy, defined as a force (Newtons) times distance (meters) through which the force acts (along the same direction). The resulting unit is the Joule.