Primary atomic frequency standards at NIST.The development of atomic frequency standards at NIST (National Institute of Standards & Technology, Washington, DC, www.nist.gov) The standards-defining agency of the U.S. government, formerly the National Bureau of Standards. It is one of three agencies that fall under the Technology Administration (www.technology. is discussed and three of the key frequency-standard technologies of the current era are described. For each of these technologies, the most recent NIST implementation of the particular type of standard is described in greater detail. The best relative standard uncertainty achieved to date for a NIST frequency standard is 1.5 X [10.sup.-15]. The uncertainties of the most recent NIST standards are displayed relative to the uncertainties of atomic frequency standards of several other countries. Key words: atomic clock atomic clock, electric or electronic timekeeping device that is controlled by atomic or molecular oscillations. A timekeeping device must contain or be connected to some apparatus that oscillates at a uniform rate to control the rate of movement of its hands or the ; atomic frequency standard; cesium-beam frequency standard; cesium-fountain frequency standard; clock; fountain frequency standard; frequency; frequency standard; ion frequency standard; lasercooling of atoms; stored-ion frequency standard; time. Available online: http://www.nist.gov/jres 1. Introduction The unit of time interval (the second) and the keeping of time depend on primary frequency standards maintained by a number of the world's national standards laboratories. The concept of time involves an arbitrary starting point Noun 1. starting point - earliest limiting point terminus a quo commencement, get-go, offset, outset, showtime, starting time, beginning, start, kickoff, first - the time at which something is supposed to begin; "they got an early start"; "she knew from the (origin), and it is only time interval or frequency that can really be measured. The second plays a pivotal role as a base unit in the International System of Units International System of Units, officially called the Système International d'Unités, or SI, system of units adopted by the 11th General Conference on Weights and Measures (1960). It is based on the metric system. , universally abbreviated SI (from the French name Le Systeme International d'Unites Sys·tème In·ter·na·tion·al d'U·ni·tés n. International System of Units. ). The meter is now directly defined in terms of the second (1), and representations of the volt volt [for Alessandro Volta], abbr. V, unit of electric potential and electromotive force. It is defined as the difference of electric potential existing across the ends of a conductor carrying a constant current of 1 ampere when the power dissipated is 1 watt. are maintained through the Josephson effect Josephson effect Flow of electric current between two pieces of superconducting material (see superconductivity) separated by a thin layer of insulating material. as a constant times frequency (2). Furthermore, because frequency can be measured easily with very low uncertainty, many other measurements are often transduced to frequency where simple counting then directly converts the results into digital form. Thus, the development and maintenance of frequency standards has been a high-priority activity at NIST (formerly NBS (National Bureau of Standards) See NIST. NBS - National Bureau of Standards: part of the US Department of Commerce, now NIST. , the National Bureau of Standards National Bureau of Standards: see National Institute of Standards and Technology. National Bureau of Standards - National Institute of Standards and Technology ) for many years. Work on frequency standards at NIST began in 1911 with J. H. Dellinger's development of a system for calibrating wavemeters. He obtained frequency from a simple calculation of the resonance of an LC circuit. During the next few years, the Years, The the seven decades of Eleanor Pargiter’s life. [Br. Lit.: Benét, 1109] See : Time development of better mathematical expressions A group of characters or symbols representing a quantity or an operation. See arithmetic expression. for inductance inductance, quantity that measures the electromagnetic induction of an electric circuit component; it is a property of the component itself rather than of the circuit as a whole. and capacitance capacitance, in electricity, capability of a body, system, circuit, or device for storing electric charge. Capacitance is expressed as the ratio of stored charge in coulombs to the impressed potential difference in volts. provided for considerable improvement in frequency measurements using these types of standards (3). In the mid-1920s the Bureau began studies of quartz-crystal oscillators as frequency standards and by 1935 had established a national primary standard of radio frequency using a set of four quartz oscillators Noun 1. quartz oscillator - an oscillator that produces electrical oscillations at a frequency determined by the physical characteristics of a piezoelectric quartz crystal crystal oscillator calibrated cal·i·brate tr.v. cal·i·brat·ed, cal·i·brat·ing, cal·i·brates 1. To check, adjust, or determine by comparison with a standard (the graduations of a quantitative measuring instrument): against the mean solar second (4). The end of the era of quartz frequency standards began in 1949 with the development at NBS of the world's first atomic frequency standard based on an ammonia absorption line at 23.87 GHz (5). At the beginning of this early period of development of atomic frequency standards, both quartz and atomic standards were achieving frequency uncertainties of about 2 X [10.sup.-8]. (Throughout this paper, relative frequency uncertainty [DELTA]v/[v.sub.0], where [DELTA]v is the frequency uncertainty generally estimated at the level of one sta ndard deviation and [v.sub.0] is the frequency of the standard, is used to describe the performance of the various frequency standards. This is also called the relative standard uncertainty.) The Bureau supported work on both technologies for the next decade, but the rapid advances in the accuracy of atomic frequency standards could not be matched by quartz devices, and the work on quartz frequency standards was stopped in 1959. This paper describes NBS/NIST work on three classes of atomic frequency standards: cesium-beam frequency standards, cesium-fountain frequency standards, and stored-ion frequency standards. No effort has been made to provide a comprehensive institutional history of this work, since the early part of this history is well covered in papers by Beehler (6) and Ramsey (7) and in books by Snyder and Bragaw (8) and Passaglia (9). Although the ammonia frequency standard was developed first, it never played a significant role in supporting frequency measurements at NBS, so it is not described further. In describing work on the three classes of atomic frequency standards, emphasis is placed on the most recent devices and the results achieved with them. In particular, the section on cesium-beam frequency standards emphasizes the most recent device, NIST-7, and only brief coverage is given to the preceding beam standards (NBS-1 to NBS-6). Several general aspects of the various types of atomic frequency standards, including atomic-state interrogation interrogation In criminal law, process of formally and systematically questioning a suspect in order to elicit incriminating responses. The process is largely outside the governance of law, though in the U.S. time, the form of the microwave cavity, and linecenter servomechanisms are briefly discussed next. Primary atomic frequency standards are passive devices; the resonance is located by probing the system with an external oscillator oscillator Mechanical or electronic device that produces a back-and-forth periodic motion. A pendulum is a simple mechanical oscillator that swings with a constant amplitude, requiring the addition of energy at each swing only to compensate for the energy lost because of air that can be tuned across the resonance. Generally, the narrower the linewidth, the less uncertain is the location of the center of the resonance, but noise can also affect the accurate location of the center of the line. Ignoring noise for the moment, the linewidth [DELTA][v.sub.a] of the atomic resonance at frequency [v.sub.0] is reciprocally dependent upon the time [t.sub.d] the atoms spend in the state interrogation region. The fractional linewidth is simply proportional to [DELTA][v.sub.a]/[v.sub.0] [approximately equal to] 1/[t.sub.d][v.sub.0]. (1) This expression shows that the standard should be operated at as high a frequency as is practical and that the atoms should spend as much time as possible in the region where they are probed by the interrogating field provided by the external oscillator. These simple considerations have guided the development of atomic frequency standards, as will become evident as the various standards are described. The basic concepts upon which atomic frequency standards are based were developed in the early 1940s by Rabi (10), but Ramsey contributed a major improvement with his method of successive oscillatory oscillatory characterized by oscillation. oscillatory nystagmus see pendular nystagmus. fields" (11). In the literature, this is more often referred to as the "method of separated oscillatory fields." In Rabi's early molecular-beam experiments at rf frequencies, the molecules or atoms passed through a single rf excitation excitation Addition of a discrete amount of energy to a system that changes it usually from a state of lowest energy (ground state) to one of higher energy (excited state). For example, in a hydrogen atom, an excitation energy of 10. region and the results obtained were critically dependent upon the uniformity of the weak magnetic field in this region (the so-called C field is needed to establish a quantization (1) The division of a range of values into a single number, code or classification. For example, class A is 0 to 999, class B is 1000 to 9999 and class C is 10000 and above. (2) In analog to digital conversion, the assignment of a number to the amplitude of a wave. axis for the atoms). In Ramsey's method the rf excitation field is divided into two spatially separated zones that are driven in phase, so that the atoms are first subjected to a short oscillatory field where a transition is initiated and then drift through the C field to a second region where another short oscillatory field induces a completion of the transition. The effect of this process, now called R amsey interrogation, is to sharpen the resonance and substantially relax the requirements on the homogeneity Homogeneity The degree to which items are similar. of the C field. All primary atomic frequency standards now use this means of interrogation. While a variety of methods have been used to servo-control a local oscillator Noun 1. local oscillator - an oscillator whose output heterodynes with the incoming radio signal to produce sum and difference tones heterodyne oscillator to the atomic resonance, most modern atomic standards now use square-wave modulation modulation, in communications modulation, in communications, process in which some characteristic of a wave (the carrier wave) is made to vary in accordance with an information-bearing signal wave (the modulating wave); demodulation is the process by which and digital processing Digital processing is the process of altering digital data in any form. The most common situations where digital processing is involved are computer graphics and digital audio processing. to achieve the lock. In this method, the local oscillator spends a certain period on one side of the resonance where the signal amplitude is measured, and then is shifted to the other side of the line for a similar measurement. The difference between the amplitudes of these two signals is driven to zero by the servo-control system, thus assuring that the center of the resonance is at the midpoint mid·point n. 1. Mathematics The point of a line segment or curvilinear arc that divides it into two parts of the same length. 2. A position midway between two extremes. between these two positions. This of course requires that the shape of the resonance be symmetric, a consideration that must be checked during evaluation of the accuracy of the standard. 2. Cesium-Beam Frequency Standards 2.1 Standards Based on Magnet State Preparation and Detection Figure 1 shows a schematic A graphical representation of a system. It often refers to electronic circuits on a printed circuit board or in an integrated circuit (chip). See logic gate and HDL. diagram of a conventional cesium-beam frequency standard. The cesium cesium (sē`zēəm) [Lat.,=bluish gray], a metallic chemical element; symbol Cs; at. no. 55; at. wt. 132.9054; m.p. 28.4°C;; b.p. 669.3°C;; sp. gr. 1.873 at 20°C;; valence +1. oven, operated near 100 [degrees]C, creates a vapor of atoms that are collimated In a straight line. Collimated light beams are parallel rays of light. and passed successively through the state-preparation region (the A magnet in Fig. 1), the microwave cavity, and then the state-detection region (the B magnet and detection system). As they emerge from the oven the [Cs.sup.133] atoms are evenly distributed in the 16 [m.sub.F] states of the [[blank].sup.2][S.sub.1/2] ground electronic state. In the state-preparation region, a magnet with an inhomogeneous Adj. 1. inhomogeneous - not homogeneous nonuniform heterogeneous, heterogenous - consisting of elements that are not of the same kind or nature; "the population of the United States is vast and heterogeneous" field (Stern-Gerlach magnet) spatially separates atoms in the various [m.sub.F] states, and atoms in one of the ground-state levels (F = 3, [m.sub.F] = 0 or F = 4, [m.sub.F] = 0, often designated as \3,0> or \4,0>) are transmitted through the microwave cavity. Because of the velocity spread in the atomic beam Atomic beam or atom laser is special case of particle beam; it is the collimated flux (beam) of neutral atoms. The imaging systems using the slow atomic beams can use the Fresnel zone plate (Fresnel diffraction lens) of a Fresnel diffraction mirror as focusing element. , this separation is not perfect, so some atoms in other [m.sub.F] states are mixed in with the ground-state atoms that go through the cav ity. This type of state preparation naturally involves a rejection of most of the atoms entering the system. State detection uses an identical Stern-Gerlach magnet arranged so that atoms are directed to the hot-wire detector only if they have been stimulated by the microwave field to the other ground, [m.sub.F] = 0 level. The designs of the seven NBS/NIST cesium-beam frequency standards, developed between 1950 and 1993 were influenced by a need to reduce and control systematic frequency shifts while maintaining the highest practical signal-to-noise performance. The linewidths of these standards were reduced by extending the length of the microwave cavity, which grew to 3.74 m for NBS-5. This increase in length was achieved at a cost of signal intensity. Furthermore, these long beam tubes, being horizontal, also suffered gravitational grav·i·ta·tion n. 1. Physics a. The natural phenomenon of attraction between physical objects with mass or energy. b. The act or process of moving under the influence of this attraction. 2. dispersion on the order of 1 cm (the slower atoms fall further than the faster ones, which spreads out the beam), thereby complicating com·pli·cate tr. & intr.v. com·pli·cat·ed, com·pli·cat·ing, com·pli·cates 1. To make or become complex or perplexing. 2. To twist or become twisted together. adj. 1. the dispersion associated with the magnetic focusing produced by the state-preparation magnet. Reduction of the uncertainty for these beam standards was achieved through a variety of incremental Additional or increased growth, bulk, quantity, number, or value; enlarged. Incremental cost is additional or increased cost of an item or service apart from its actual cost. developments, but a gradual improvement in the theory also contributed to improved ways of evaluating and controlling systematic frequency shifts. 2.2 NIST-7, An Optically Pumped Cesium-Beam Standard The use of optical pumping Optical pumping The process of causing strong deviations from thermal equilibrium populations of selected quantized states of different energy in atomic or molecular systems by the use of optical radiation (that is, light of wavelengths in or near the visible to replace state-selection magnets was first suggested by Kastler in 1950 [12], although it was not made practical until tunable lasers A laser that can change its frequency over a given range. In time, tunable lasers are expected to be capable of switching frequencies on a packet by packet basis. were developed. There are a number of ways in which to apply optical pumping to the cesium-beam standard, but even the simplest methods produce large benefits. Basically, optical state selection is achieved through the frequency selectivity selectivity /se·lec·tiv·i·ty/ (se-lek-tiv´i-te) in pharmacology, the degree to which a dose of a drug produces the desired effect in relation to adverse effects. selectivity 1. of the exciting light; this laser light is tuned so that atoms in a particular state efficiently absorb the light and are excited to higher electronic states. In relaxing back to the ground state, the excited atoms are restricted by quantum selection rules, so that they can in general relax to only a limited set of the various ground-state levels. Two types of situations in cesium are particularly interesting. For optical state preparation in NIST-7, atoms are excited from the F = 4 ground-state level to the F = 3 level of the [[blank].sup.2][P.sub.3/2] state from whence whence adv. 1. From where; from what place: Whence came this traveler? 2. From what origin or source: Whence comes this splendid feast? conj. they can relax to either the F = 3 or F =4 level of the ground state. Continued selective pumping from the ground-state F = 4 level thus depopulates that level and increases the population in the ground-state F = 3 level. Thus, rather than discarding atoms, as is done with the magnetic method, atoms are converted to the desired state. Done with the proper light polarization polarization Property of certain types of electromagnetic radiation in which the direction and magnitude of the vibrating electric field are related in a specified way. , this pumping leaves the atoms evenly distributed in population (and velocity) among the seven [m.sub.F] levels within the F = 3 ground state. While a variation on this method using two excitation laser frequencies can achieve conversion of all atoms to the desired [m.sub.F] = 0 ground-state level, this involves scattering of many more photons into the microwave interrogation region, increasing the light-induced fr equency shift commonly called the ac Stark shift. State detection can also be achieved using optical methods. This is done in NIST-7 by pumping from the F = 4 ground state to the F = 5 level of the [[blank].sup.2][P.sub.3/2] state, where quantum selection rules restrict their relaxation to only the F = 4 level of the ground state. This is called a cycling transition. Using such a transition, a single atom can be made to scatter scat·ter v. 1. To cause to separate and go in different directions. 2. To separate and go in different directions; disperse. 3. To deflect radiation or particles. n. a very large number of photons (to fluoresce fluo·resce intr.v. fluo·resced, fluo·resc·ing, fluo·resc·es To undergo, produce, or show fluorescence. [Back-formation from fluorescence. ), thus achieving 100 % detection efficiency. Such a state-detection scheme can readily achieve a detection noise limited by the atom shot noise; that is, the laser-detection process adds no additional noise. There are several advantages to these optical techniques. First, as just described, for a given flux of atoms, the signal-to-noise ratio The ratio of the power or volume (amplitude) of a signal to the amount of unwanted interference (the noise) that has mixed in with it. Measured in decibels, signal-to-noise ratio (SNR or S/N) measures the clarity of the signal in a circuit or a wired or wireless transmission channel. is substantially increased, thus decreasing the time needed to make a measurement. Second, the elimination of the state-selection and state-detection magnets removes the troublesome transverse To cross from side to side. dispersion of atoms associated with the fact that slow and fast atoms in the Maxwellian distribution of atom velocities take different paths through the magnetic optics of such systems. Finally, the asymmetries in the cesium spectrum arising in magnetic state preparation from the velocity selectivity of that process can be essentially eliminated by optical pumping. This means that pulling effects from a line on one side of the central fringe are balanced by an equal line pulling from the other side. These advantages, together with major improvements in the design of the microwave cavity (13) and the servo-control design, have resulted in the achievement of a combined uncertainty for NIST-7 of 4.4 X [10.sup.-15], a factor of 20 better than the uncertainty of NBS-6. The major sources of uncertainty in frequency biases in thermal-beam, cesium frequency standards are second-order Zeeman shift, second-order Doppler shift See Doppler effect. , end-to-end cavity phase shift and possibly cavity pulling, fluorescence fluorescence (fl  rĕs`əns), luminescence in which light of a visible color is emitted from a substance under stimulation or excitation by light or other forms of electromagnetic light shift, and line-overlap shift.
Because of their sizes, these effects must be considered variable on a
level significant to the overall accuracy of the standard. Therefore,
they must be evaluated often, and NIST-7 incorporates a number of
servo-control systems that allow major portions of this evaluation to be
automated. Furthermore, a measurement technique has been developed to
allow the very small effects of cavity pulling, line-overlap shift and
magnetic-field inhomogeneity in·ho·mo·ge·ne·i·ty n. pl. in·ho·mo·ge·ne·i·ties 1. Lack of homogeneity. 2. Something that is not homogeneous or uniform. Noun 1. to be measured quickly with low-precision measurements (14). This technique relies on the fact that the shift in the Rabi pedestal pedestal In Classical architecture, a support or base for a column, statue, vase, or obelisk. It may be square, octagonal, or circular. A single pedestal may also support a group of columns, or colonnade (see podium). part of the line shape is large compared to the shift in the Ramsey fringe part of the line shape. Because of this leverage, the offset between the Ramsey line and its Rabi pede stal must be measured to only about 0.1 Hz to obtain corrections of <1 X [10.sup.-15]. This requires fractional frequency measurements no better than 1 X [10.sup.-12]. Combining the digital servo-system and this new measurement technique, the major systematic errors can be evaluated in just a few days. The short-term stability of NIST-7 is typically [[sigma].sub.y], ([tau]) = 7 X [10.sup.-13] [[tau].sup.-1/2]. This means that frequency measurements with uncertainties near [10.sup.-15] (one standard deviation In statistics, the average amount a number varies from the average number in a series of numbers. (statistics) standard deviation - (SD) A measure of the range of values in a set of numbers. ) can be made in about 10 hours. Figure 2 shows the Ramsey pattern for the central spectral spectral /spec·tral/ (spek´tral) pertaining to a spectrum; performed by means of a spectrum. spec·tral adj. Of, relating to, or produced by a spectrum. feature (F = 3[left and right arrow]F = 4). The linewidth [DELTA]v is about 65Hz corresponding to Q [equivalent to] [v.sub.0]/[DELTA]v [approximately equal to] 1.5 X [10.sup.8]. To achieve an uncertainty of 5 X [10.sup.-15], the line center must be located with an uncertainty of <1 x [10.sup.-6], a difficult task. Furthermore, the very broad velocity distribution found in an optically pumped sta ndard leads to a relatively strong dependence of the frequency on microwave power and modulation parameters. To achieve confidence in measurements to such exacting accuracy, two or more independent techniques have been used to evaluate most of the error sources. 2.2.1 Apparatus The general layout of this standard is similar to that of the conventional, magnetic-selection standard shown in Fig. 1, except that the state-preparation and state-detection magnets are replaced with laser systems, and the atom detector is replaced with a fluorescence detector. NIST-7 is described in greater detail elsewhere (15,16). Briefly, it has a Ramsey cavity 1.55 m long and an atomic beam diameter of 3 mm. An axial axial /ax·i·al/ (ak´se-al) of or pertaining to the axis of a structure or part. ax·i·al adj. 1. Relating to or characterized by an axis; axile. 2. C field is employed for field uniformity and control of the Rabipedestal shape. The cavity ends are designed so that the Poynting vector In physics, the Poynting vector can be thought of as representing the energy flux (W/m2) of an electromagnetic field. It is named after its inventor John Henry Poynting. Oliver Heaviside independently co-discovered the Poynting vector. vanishes at the center of the atomic-beam window (13), thus minimizing distributed-cavity phase-shift effects. The laser system uses two distributed-Bragg-reflection (DBR DBR Drum-Buffer-Rope DBR Distributed Bragg Reflector dBr Decibel (reference value) DBR Deterministic Bit Rate DBR Daily Business Review DBR Dual Band Radar DBR Disclosure-Based Regulation ) lasers. One is frequency-referenced to the F = 4 [right arrow] F' = 5 (F refers to a level in the [[blank].sup.2][S.sub.1/2] state and F' refers to a level in the [[blank].sup.2][P.sub.3/2] state) saturated absorption feature in an evacuated e·vac·u·ate v. e·vac·u·at·ed, e·vac·u·at·ing, e·vac·u·ates v.tr. 1. a. To empty or remove the contents of. b. To create a vacuum in. 2. cesium cell. The second laser is frequency-referenced to the F = 4 [right arrow] F' = 3 transition. The digital servo An electromechanical device that uses feedback to provide precise starts and stops for such functions as the motors on a tape drive or the moving of an access arm on a disk. system for locating and locking to the center of the resonance uses a microwave synthesis scheme that involves the addition of a 10.7 MHZ offset near the top of the multiplication multiplication, fundamental operation in arithmetic and algebra. Multiplication by a whole number can be interpreted as successive addition. For example, a number N multiplied by 3 is N + N + N. chain. This frequency comes from a computer-controlled direct-digital synthesizer synthesizer Machine that electronically generates and modifies sounds, frequently with the use of a digital computer, for use in the composition of electronic music and in live performance. (DDS (1) (Digital Data Storage) See DAT. (2) (Data Dictionary System) See QuickBuild and OpenDDS. (3) (Dataphone Digital S ). The entire system is frequency referenced to an active hydrogen maser maser (mā`zər), device for creation, amplification, and transmission of an intense, highly focused beam of high-frequency radio waves. and the output is in the form of a table of offset values sent to the DDS. This system uses slow, square-wave frequency modulation frequency modulation: see modulation; radio. (1) An earlier magnetic disk encoding method that places clock bits onto the medium along with the data bits. It was superseded by MFM and RLL. (=0.5 Hz) with blanking during the signal transients (17). Its advantage is its extreme frequency agility that allows interrogation of a number of features in the cesium spectrum. 2.2.2 Magnetic-Field Effects The C field is operated under closed-loop servo control. This low-duty-cycle (1 %) servo maintains the frequency of the first field-dependent transition within 10 mHZ of a preselected value. This contributes an uncertainty in the second-order Zeeman shift on the clock transition of <1 X [10.sup.-16]. Field measurements made during assembly (16) showed a fractional field variation at the position of one Ramsey cavity of 5 X [10.sup.-4] relative to the mean field. This nonuniformity produces a shift of <1 X [10.sup.-17] at all microwave power levels. Measurements of the offsets of the field-dependent Ramsey lines from the centers of their corresponding Rabi pedestals confirm the size of the inhomogeneity shift (14). 2.2.3 Second-Order Doppler Effect Doppler effect, change in the wavelength (or frequency) of energy in the form of waves, e.g., sound or light, as a result of motion of either the source or the receiver of the waves; the effect is named for the Austrian scientist Christian Doppler, who demonstrated The second-order Doppler shift is of order 3 X [10.sup.-13]. To achieve the accuracy goal requires a measurement of the effective, ensemble-averaged velocity with an uncertainty of<1 %. This has been done using both a Ramsey lineshape-inversion technique (18) and a pulsed optical pumping technique (19). The second-order Doppler correction was computed for several microwave power levels using the two methods. While the corrections varied by nearly 2 X [10.sup.-13] over the 7.5 dB power range, the shifts computed from the two methods were in excellent agreement (within 2 X [10.sup.-15]). To maintain stability of the second-order Doppler shift to this level requires control of the microwave power experienced by the atoms to much less than 0.1 dB. This is achieved using a power-level servo system with a precision power splitter and a stable power meter. The computer determines the optimum power level through measurement of the signal intensity as a function of microwave power. The Ramsey-inversion program used to measure the velocity profile also returns a measure of the absolute power. The value returned by the Ramsey-inversion program and that determined by the power-level servo system are in excellent agreement. 2.2.4 Cavity-Related Errors The end-to-end cavity phase shift is measured y reversing the beam direction. The fractional frequency shift on beam reversal is [approximately equal to]1.2x [10.sup.-12], with an uncertainty of 7 x [10.sup.-16]. The distributed-cavity phase shift is expected to be small in this machine due to the use of the improved Ramsey cavity (13). Measurements in both beam directions using beam masks to cover portions of cavity apertures indicate a bias of -1.3 x [10.sup.-15] that is corrected to an uncertainty of 4 X [10.sup.-16]. Cavity pulling has been investigated by a number of techniques, the most sensitive of which is the measurement of the offset of the Ramsey lines from the centers of their respective Rabi pedestals (14). The shift under normal operation is -6 x [10.sup.-15], and this is corrected to an uncertainty of 5 X [10.sup.-16]. 2.2.5 Line-Overlap Shift Because of the symmetry of the spectrum, as well as the very smooth Rabi line wings produced in this standard by the use of an H-plane cavity, Rabi pulling is extremely small. The offset of the Ramsey structures from their corresponding Rabi lines shows that Rabi pulling is <1 X [10.sup.-16] for normal operation at a C-field value of 5.4 [mu]T (14). 2.2.6 AC Stark Shift The ac stark shift caused by the black-body radiation Noun 1. black-body radiation - the electromagnetic radiation that would be radiated from an ideal black body; the distribution of energy in the radiated spectrum of a black body depends only on temperature and is determined by Planck's radiation law at 39 [degrees]C (the operating temperature of the beam tube) is calculated to be 2.0 X [10.sup.-14] (20). It is too small to be measured by actual temperature change in the standard but must be accounted for in the evaluation. The uncertainty in this value is <5 X [10.sup.-16]. An ac stark shift is also possible from the near resonant resonant giving an intense, rich sound on percussion; exhibiting resonance. light that is a byproduct by·prod·uct or by-prod·uct n. 1. Something produced in the making of something else. 2. A secondary result; a side effect. Noun 1. of the optical pumping process (fluorescence). Theoretical analysis of this effect in the geometry of NIST-7 shows it to be negligible at the [10.sup.-15] level (21). Measurement of this effect shows it to be small, but the uncertainty in this measurement is 3 X [10.sup.-15], making it the largest systematic error for the standard. Further improvements in the measurement method should reduce this uncertainty. 2.2.7 Microwave Leakage This effect arises from stray microwave radiation in the vicinity of the Ramsey cavity. It has the same effect as end-to-end phase shift, and would be accounted for in a beam reversal if it were stable in both phase and amplitude at every point in space and time. Leakage from microwave structures outside the beam tube that finds its way into the standard is not stable in phase and amplitude because it travels over uncontrolled and varying pathways. It contributes to both frequency errors and long-term instability in the standard. A heterodyne het·er·o·dyne adj. Having alternating currents of two different frequencies that are combined to produce two new frequencies, the sum and difference of the original frequencies, either of which may be used in radio or television receivers by proper detector was used to locate the sources of this external leakage and an antenna was used to probe the points where the radiation couples to the standard (22). Measures were taken to substantially reduce both the sources and the coupling. The shift produced by this external radiation is now <1 x [10.sup.-16]. 2.2.8 Electronics The digital servo system is susceptible to errors from modulation distortion and integrator offsets. The servo can also have subtle errors from switching transients, round-off errors A round-off error, also called rounding error, is the difference between the calculated approximation of a number and its exact mathematical value. Numerical analysis specifically tries to estimate this error when using approximation equations and/or algorithms, especially and aliasing In computer graphics, the stair-stepped appearance of diagonal lines when there are not enough pixels in the image or on screen to represent them realistically. Also called "stair-stepping" and "jaggies." See anti-aliasing. . These can be affected by if spectral purity and phase noise. Rather than use the frequency of the standard as a diagnostic tool to study these effects, a painfully slow process, quick and sensitive electronic tests have been used. Models for the sensitivity to all superpositions of amplitude modulation amplitude modulation: see modulation; radio. Varying the voltage of a carrier or a direct current in order to transmit analog or digital data. Amplitude modulation (AM) is the oldest method of transmitting human voice electronically. (AM) and phase modulation phase modulation: see modulation. Varying the angle of a wave in a carrier in order to transmit analog or digital data. For digital signals, phase modulation (PM) is widely used in conjunction with amplitude modulation (AM). (PM) noise and methods for measuring these effects have been developed (17). The total error found to arise in these electronic systems is <1 X [10.sup.-15]. 2.2.9 Summary of Performance of NIST-7 The sources of major frequency bias are independently evaluated with just a few days of measurements. Complete evaluation of all other small effects takes much longer, but such effects are stable at the [10.sup.-15] level and their infrequent evaluation does not detract from detract from verb 1. lessen, reduce, diminish, lower, take away from, derogate, devaluate << OPPOSITE enhance verb 2. the uncertainty of the standard. Table 1 lists all known frequency shifts and the uncertainties associated with their correction. The combined uncertainty of the standard is taken to be the square root of the sum of the squares of these uncertainties. For the most recent evaluation represented by this table, the combined uncertainty is 4.4 X [10.sup.-15]. 3. Cesium-Fountain Frequency Standard The fountain concept for extending atom observation time was introduced by Zacharias in 1954 (23). Laser cooling Laser cooling Reducing the thermal motion of atoms with the force exerted by a laser beam. Typically, such cooling is used to reduce the temperature of a gas of atoms, or the velocity spread of atoms in an atomic beam. of atoms was unknown at the time, but Zacharias believed that it might be possible to direct a thermal beam of atoms upward and then depend on finding that a small number of slower atoms in the Maxwellian velocity distribution would reach apogee apogee (ăp`əjē), point farthest from the earth in the orbit of a body about the earth. See apsis. The farthest point. within the device and return to the source. While there would be a dramatic loss of signal, the time of flight for atoms going up 1 m and returning would be on the order of 1 s, resulting in a large reduction in resonance linewidth. Furthermore, atoms could traverse the same microwave cavity twice (once on the way up and once on the way down), and this would provide for Ramsey interrogation (temporally separated rather than spatially separated regions) without the end-to-end cavity phase shift found in beam standards. The experiment was attempted shortly after the proposal was made, but no return signal was observed. It was later found that scattering proce sses within the beam have the effect of removing the slowest of atoms, so it is clear now that the original experiment was doomed to failure. The concept was not to be proven until 35 years later, after laser cooling techniques were developed. The first demonstration of the fountain concept was at Stanford University Stanford University, at Stanford, Calif.; coeducational; chartered 1885, opened 1891 as Leland Stanford Junior Univ. (still the legal name). The original campus was designed by Frederick Law Olmsted. David Starr Jordan was its first president. (24) in 1989 and the first primary standard based on the fountain concept was developed shortly thereafter by a group at the Laboratoire Primaire du Temps et Frequences (LPTF LPTF Low-Power Test Facility ) (25). The laser-cooled fountain concept is shown in Fig. 3. The atom ball in the LPTF cesium fountain is formed either using a magneto-optical trap A magneto-optical trap (abbreviated MOT) is a device that cools down non-charged atoms to temperatures near absolute zero and traps them at a certain place using magnetic fields and circularly polarised laser light. (MOT) or optical-molasses (26). The NIST fountain collects atoms only in optical molasses molasses, sugar byproduct, the brownish liquid residue left after heat crystallization of sucrose (commercial sugar) in the process of refining. Molasses contains chiefly the uncrystallizable sugars as well as some remnant sucrose. . The MOT can achieve higher atom density, but the ball of atoms is typically converted to optical molasses prior to launching. For fountain frequency standards the transverse temperature of the atoms is a key parameter. During flight of the atoms through the devices, a large fraction (of order 90%) of the atoms with higher transverse velocities are lost before they return to the detection region. Additional transverse cooling would allow increased utilization of source atoms, and a better tradeoff between signal strength and spi n-exchange shift. 3.1 Description of NIST-F1 The NIST cesium fountain is described in greater detail elsewhere (27) and only a short overview is given here. The NIST-F1 optical-molasses source gathers approximately [10.sup.7] cesium atoms at <2 [mu]K in about 0.4 s. The ball of atoms is then launched by differential detuning of the two vertical laser beams to make a moving optical molasses. After the atoms have been accelerated to their launch velocity the molasses laser beams are all detuned to the red in frequency while simultaneously reducing the optical intensity to further cool the launched atom sample. The atoms travel from the optical molasses source region through a region that is used to detect atoms later in the process, and into the magnetically shielded C-field section of the fountain. All of the launched atoms at this point are in the F = 4 state and approximately evenly distributed over all possible [m.sub.F]-state values. The atoms first encounter a microwave state-preparation cavity, which moves the \4,0> atoms to the \3,0> state using a [pi]-pulse at 9.192 GHz. Any remaining F = 4 atoms are then removed from the sample with an optical pulse. The remaining atoms in the \3,0> state next encounter the Ramsey microwave cavity, where the microwave field prepares the atoms in a superposition su·per·po·si·tion n. 1. The act of superposing or the state of being superposed: "Yet another technique in the forensic specialist's repertoire is photo superposition" state of \4,0> and \3,0>. The Ramsey cavity, a [TE.sub.011] OFHC OFHC Oxygen-Free High Conductivity (refers to copper for electrical use) OFHC Oxygen Free Hard Copper copper cavity, has been previously described [28]. After the Ramsey cavity the atoms drift upward in the flight-tube, achieve apogee, then move downward under the influence of gravity, and re-enter re·en·ter also re-en·ter v. re·en·tered, re·en·ter·ing, re·en·ters v.tr. 1. To enter or come in to again. 2. To record again on a list or ledger. v.intr. the Ramsey cavity where the Ramsey-interrogation process is completed. After leaving the Ramsey cavity the atoms next fall through the state-preparation cavity, in which the microwave drive has been both detuned by 12 MHZ and attenuated Attenuated Alive but weakened; an attenuated microorganism can no longer produce disease. Mentioned in: Tuberculin Skin Test attenuated having undergone a process of attenuation. by more than 100 dB, to prevent unwanted interactions with this field. Finally, upon exiting the C-field regions, the atoms enter the detection regions. Here atoms in the \4,0> state are first detected by fluorescence in an optical standing wave and then removed from the atomic sample by an optical traveling wave. The sample then traverses an optical re-pump beam which transfers \3,0> atoms to the \4,0> state. These \4,0> atoms (formerly \3,0> atoms) are then detected by optical fluorescence in a standing wave similar to the one described above. The point of detecting both the \4,0> and \3,0> atoms is to form the sum of the two, a number which is proportional to the number of atoms launched. This sum can be used to normalize normalize to convert a set of data by, for example, converting them to logarithms or reciprocals so that their previous non-normal distribution is converted to a normal one. the number of atoms in each ball, thus removing noise that would arise from toss-to-toss, atom-number fluctuations. Figure 4 shows the Ramsey pattern for NIST-F1. The upper portion of the figure shows the envelope of the pattern and the lower portion shows an expanded section around the central Ramsey fringe. The large number of fringes is a consequence of the narrower velocity distribution. The linewidth of the central fringe is [approximately equal to]1 Hz corresponding to a Q [equivalent to] [v.sub.0]/[DELTA]v [approximately equal to] [10.sup.10]. One side of the Ramsey fringe is probed in a cycle involving the launch of a ball of atoms, microwave interrogation, and the optical detection. The microwave synthesizer is then tuned to the other side of the fringe and the cycle is repeated. A single measurement of the cesium clock frequency consists of two measurement cycles, one on each side of the Ramsey fringe. The servo-control systems acts to equalize e·qual·ize v. e·qual·ized, e·qual·iz·ing, e·qual·iz·es v.tr. 1. To make equal: equalized the responsibilities of the staff members. 2. To make uniform. the signal measured on each side of the fringe, thus assuring that line center is at the midpoint of the two frequencies. 3.2 Systematic Frequency Biases Because of the symmetry of the fountain geometry, the low velocities of the atoms, and the narrow linewidth, many frequency shifts are much smaller than those found in thermal-beam standards. A number of systematic effects have been shown to have a worst-case frequency bias [DELTA]v/[v.sub.0] of [10.sup.-16] or less in this fountain. These effects, which will not be discussed further, are cavity pulling, distributed-cavity phase shift (first-order Doppler shift), Rabi pulling, Ramsey pulling, second-order Doppler shift, dc Stark shift, and the Bloch-Siegert shift. 3.2.1 Second-Order Zeeman Shift The C field used in NIST-F1 is about 0.1 [mu]T (1 mG) and causes a 5 X [10.sup.-14] fractional frequency shift due to the second-order Zeeman effect. This shift is evaluated by measuring the frequency of the \4,1>[right arrow]\3,1> magnetic-field-sensitive transition and using the frequency of that transition to correct for the shift in the \4,0>[right arrow]\3,0> transition. To sufficient accuracy the fractional Zeeman correction is then given by [delta][v.sub.z]/[v.sub.0] = 8 [delta][v.sup.2.sub.1,0]/[v.sup.2.sub.0], (2) where [delta][v.sub.1,0] is the measured difference frequency between the \4,0>[right arrow]\3,0> and the \4,1>[right arrow]\3,1> transitions. Several things mush (MultiUser Shared Hallucination) See MUD. 1. (games) MUSH - Multi-User Shared Hallucination. 2. (messaging) MUSH - Mail Users' Shell. be considered to achieve accuracy in the evaluation of this shift. Due to the large number of Ramsey fringes, there is an uncertainty in identifying the central fringe on the magnetically sensitive transitions. A magnetic-field inhomogeneity will shift the Ramsey fringes with respect to the underlying Rabi pedestal. The central fringe is identified in tow ways. First, a magnetic-field map is constructed by launching the atoms to various heights and applying a Rabi pulse on a magnetically sensitive transition at apogee using an antenna in the drift region. This technique is described by the LPTF group [25]. A better method uses repeated measurements of the Ramsey fringe pattern around the central fringe for the [m.sub.F] = 1 transition while launching to various heights. The peaks of the Ramsey fringes constructively interfere on the central fringe and lose coherence away from it. A mis-assignment of even 1 full fringe (considered unlikely) would produce a fractional frequency error of only about 3 X [10.sup.-16]. The stability of NIST-F1 when locked to the \4,1>[right arrow]\3,1> line shows a flicker-noise floor at [[sigma].sub.y]([tau]) = [10.sup.-12], which indicates that magnetic-field fluctuations of about [10.sup.-12] T are present inside the C-field region. Field fluctuations of this size cause a frequency shift in the [m.sub.F] = 0 clock transition of order [10.sup.-18] and are ignored here. Measurement of the \4,1>[right arrow]3,1> transition determines the temporal average of the magnetic field B over the flight time. However, the temporal average of [B.sup.2] is needed to correct the second-order Zeeman shift. If the magnetic field is modeled as seen by the atoms as H(t) = [H.sub.0][1-[epsilon]f(t) where f(t) is a function with [absolute value of f(t)] [less than or equal] 1, and [epsilon] is a scaling factor, then the difference between the mean square and the square of the mean leads to a frequency shift given by [DELTA]v/[v.sub.0] = (427 X [10.sup.8] [H.sup.2.sub.0]) [[epsilon].sup.2]/[v.sub.0] [[<f(t)>.sup.2]-<f[(t).sup.2]>] (3) From the magnetic field model, [epsilon] can be shown to be of order 0.1, and from consideration of atom ballistics ballistics (bəlĭs`tĭks), science of projectiles. Interior ballistics deals with the propulsion and the motion of a projectile within a gun or firing device. , [<f(t)>.sup.2]]-<f[(t).sup.2]> is found to be [less than or equal to]0.01 The maximum inhomogeneity frequency shift is then less than [DELTA]v/[v.sub.0] = [10.sup.-17]. The uncertainty associated with the quadratic quadratic, mathematical expression of the second degree in one or more unknowns (see polynomial). The general quadratic in one unknown has the form ax2+bx+c, where a, b, and c are constants and x is the variable. Zeeman shift is therefore dominated by problem associated with location of the central fringe and conservatively assigned a value equivalent to the mis-assignment of one whole fringe in the [m.sub.F] = 1 manifold manifold In mathematics, a topological space (see topology) with a family of local coordinate systems related to each other by certain classes of coordinate transformations. Manifolds occur in algebraic geometry, differential equations, and classical dynamics. , that is, 3X [10.sup.-16]. 3.2.2 Spin-Exchange Frequency Shift The evaluation of the spin-exchange frequency shift requires a measurement of the atomic density, which is determined using several methods. This involves carefully calibrating the entire detection system including the size of the detection beams and their intensity, the solid angle for collection of photons from the atomic sample, and finally a calibration of the photodiode A light sensor (photodetector) that allows current to flow in one direction from one side to the other when it absorbs photons (light). The more light, the more the current. Used to detect light pulses in optical fibers and other light-sensitive applications, it works the opposite of a and its associated amplifier. The average density is determined from a measurement of the number of atoms launched by using the detection region to measure the number of atoms in the cloud Refers to the operation taking place within a network. See cloud. on the way up and again on the way down. Assuming Maxwellian thermal distributions and extracting the physical dimensions of the launched atom ball from the data, the atomic density can be determined as a function of time. This density is then used, along with a spin-exchange frequency-shift coefficient for the [m.sub.F] = 0 state as measured by the LPTF group [29] and the Stanford group [30] to determine the total spin-exchange frequency shift. The pro cess is complicated by the use of a pure molasses source, since the initial cloud size is uncertain and this propagates into the final result both directly and as an uncertainty in the atom temperature. The atomic density derived above is next used to predict the total spin-exchange frequency shift as [DELTA]v/[v.sub.0] = (-2X[10.sup.-21]) [(ht/T) ([[rho].sub.1] + [[rho].sub.3]/2 - [[rho].sub.2])+ [[rho].sub.2]] (4) where h is a factor of order unity and depends on the excitation power, t is the Rabi time, T is the Ramsey time, [[rho].sub.1] and [[rho].sub.3] are the atomic density on the first and second pass through the microwave cavity, respectively, and [[rho].sub.2] is the average density over the entire Ramsey time. This formula, originally derived by Shirley [31] for Zeeman shifts over the length of a beam tube, has been modified for the case at hand. As a consistency check the frequency of the fountain with state selection is compared to the frequency with no state selection. Without state selection the density is much higher, although the spin-exchange cross section is smaller by a factor of two. No spin-exchange frequency shift is seen at 3 X [10.sup.-15] (limited by the random uncertainty of the measurement) when this test is made. The total calculated spin-exchange shift in the fountain is typically 5 X [10.sup.16] and as a result of the difficulties associated with the density determination mentioned above, a conservative uncertainty of 5 X [10.sup.-16] is assigned. A rigorous analytic solution to the density as a function of time is needed. This will allow further improvement in evaluation of the spin-exchange uncertainty. 3.2.3 Blackbody Radiation blackbody radiation The electromagnetic radiation that a perfect blackbody would give off at a given temperature. A warm blackbody would emit radiation with a higher average frequency than a cooler one. Noun 1. Shift The next significant systematic frequency bias is the blackbody radiation shift. This radiation shift is the same as that described for NIST-7, but it is somewhat more significant, because the overall uncertainty for this standard is lower. The cavity and drift tube region of the fountain are temperature controlled at a temperature of 41 [degrees]C. Sensors on the microwave cavities and the drift tube of the fountain monitor the temperature. The largest temperature differential noted from these sensors is 0.2 [degrees]C. A temperature error of 1 [degrees]C is taken to be the worst possible error and this leads to an uncertainty of less than 3 x [10.sup.-16]. 3.2.4 Gravitational Redshift In physics, light or other forms of electromagnetic radiation of a certain wavelength originating from a source placed in a region of stronger gravitational field (and which could be said to have climbed "uphill" out of a gravity well) will be found to be of longer wavelength when The gravitational frequency shift (redshift redshift Displacement of the spectrum of an astronomical object toward longer wavelengths (visible light shifts toward the red end of the spectrum). In 1929 Edwin Hubble reported that distant galaxies had redshifts proportionate to their distances (see ) in Boulder is large, about-1.8 X [10.sup.-13]. The gravitational potential in Boulder Colorado relative to the geoid ge·oid n. The hypothetical surface of the earth that coincides everywhere with mean sea level. [German, from Greek geoeid has been reevaluated using an Earth potential model and the resulting claimed uncertainty on the frequency correction is less than 5 X [10.sup.16]. 3.2.5 Summary of Uncertainty The present values of the most-significant systematic frequency biases in NIST-Fi are given in Table 2. The overall Type B uncertainty (systematic effects) is 0.8 X [10.sup.15], dominated by the spin-exchange shift. The Type A (statistical) uncertainty is 1.3 X [10.sup.-15], resulting in a combined uncertainty of 1.5 X [10.sup.15]. This represents the present status of the standard. Work during the next year should reduce the combined uncertainty to <1 X [10.sup.-15]. However, because of the spin-exchange shift, it will be difficult to achieve an uncertainty much below 5 X [10.sup.-16]. 4. Stored-Ion Frequency Standards The key advantage of using stored ions for frequency standards is that they can be stored for long periods (hours to days and even weeks are common) with, in some cases, exceedingly small systematic frequency shifts. This allows for an arbitrarily large In mathematics, the phrase arbitrarily large is used in statements such as:
See also: Inversely to the time interval between the pulses. The end-to-end cavity phase shift of cesium-beam standards is absent, and there is no first-order Doppler shift. The first stored-ion frequency standard that exhibited a reasonably small uncertainty (1 X [10.sup.-13]) was a [Be.sup.+] ion standard operating at 303 MHz (32). While this standard used a modest ion cloud ([approximately equal to][10.sup.4] ions), the standards described below use only a few ions. Despite the small number of ions in these standards, very competitive stabilities have been achieved for the microwave-frequency standard, and the short-term stability achieved in experiments on the optical-frequency standard is exceptionally high. Storage methods (33) include both radio-frequency traps (called Paul traps), which use a combination of static and ac electric fields to achieve confinement, and Penning traps Penning traps are devices for the storage of charged particles using a constant static magnetic field and a spatially inhomogeneous static electric field. This kind of trap is particularly well suited to precision measurements of properties of ions and stable subatomic particles , which confine ions using a combination of static electric and magnetic fields magnetic fields, n.pl the spaces in which magnetic forces are detectable; created by magnetostrictive ultrasonic scalers to cause the tips of instruments such as ultrasonic scalers to vibrate. . There are a variety of ions and trap configurations that have been used, but this discussion is limited to work done at NIST on [[blank].sup.199][Hg.sup.+] ions stored in a linear rf trap to produce a microwave frequency standard and in a similar linear trap to produce an optical frequency standard. [[blank].sup.199][Hg.sup.+] offers a microwave clock transition at 40.5 GHz and an optical clock transition at 1.06 X [10.sup.15] Hz. (see Fig. 5). To first order, both transitions are insensitive to uniform magnetic fields. Using a linear trap, uncertainties in all systematic frequency shifts of the 40.5 GHz transition are expected to be less than 1 X [10.sup.-16]. Using a single ion, the relative uncertainty is expected to be <1 X [10.sup.-17] for the optical transition. If fluctuations of the atomic signal are due only to quantum statistics Quantum statistics The statistical description of particles or systems of particles whose behavior must be described by quantum mechanics rather than by classical mechanics. , then the stability of a frequency source servoed to the atomic transition is given by (34) [[sigma].sub.y]([tau]) = 2[pi]/[v.sub.0] [square root of ([NT.sub.R])] [[tau].sup.-1/2], (5) where [v.sub.0] is the frequency of the atomic transition, N is the number of ions, [T.sub.R] is the Ramsey interrogation time, and [tau] is the averaging time of the measurement. For the ground-state hyperfine transition, [v.sub.0] = 40.5 GHz. It appears feasible to use N = 100 ions and [T.sub.R] = 100s, which gives [[sigma].sub.y]([tau]) [approximately equal to] 4 X [10.sup.-14] [[tau].sup.-1/2]. For the 282 nm [[blank].sup.2][S.sub.1/2] [right arrow] [[blank].sup.2][D.sub.5/2] electric quadrupole A quadrupole is one of a sequence of configurations of electric charge or gravitational mass that can exist in ideal form, but it is usually just part of a multipole expansion of a more complex structure reflecting various orders of complexity. transition, [v.sub.0] [approximately equal to] [10.sup.15] Hz, so that using N = 1 and [T.sub.R] = 25 ms gives [[sigma].sub.y] ([tau]) [approximately equal to] [10.sup.-15] [[tau].sup.-1/2]. 4.1 Cryogenic cryogenic /cry·o·gen·ic/ (-jen´ik) producing low temperatures. cry·o·gen·ic adj. 1. Relating to or producing low temperatures. 2. Linear RF Trap Figure 6 shows the linear if trap (35) used in the 40.5 GHz microwave frequency standard. Two diagonally opposite rods are grounded, while the potential of the other two rods is [V.sub.0] cos([OMEGA 1. (programming) Omega - A prototype-based object-oriented language from Austria. ["Type-Safe Object-Oriented Programming with Prototypes - The Concept of Omega", G. Blaschek, Structured Programming 12:217-225, 1991]. 2. ]t), where nominally [V.sub.0] [approximately equal to] 150 V and [OMEGA]/2[pi] = 8.6 MHZ. The resulting pseudopotential confines con·fine v. con·fined, con·fin·ing, con·fines v.tr. 1. To keep within bounds; restrict: Please confine your remarks to the issues at hand. See Synonyms at limit. the ions radially in a well with a secular frequency [v.sub.r] [approximately equal to] 230 kHz. To reduce patch fields and remove electrical charge that otherwise leaves the rods slowly in the cryogenic environment, resistive resistive /re·sis·tive/ (re-zis´tiv) pertaining to or characterized by resistance. wires are threaded through the rods to heat them during and after loading the trap. Two cylindrical cyl·in·dri·cal adj. Of, relating to, or having the shape of a cylinder, especially of a circular cylinder. sections at either end of the trap are held at a potential of approximately +10 V, confining con·fine v. con·fined, con·fin·ing, con·fines v.tr. 1. To keep within bounds; restrict: Please confine your remarks to the issues at hand. See Synonyms at limit. the ions axially ax·i·al adj. 1. Relating to, characterized by, or forming an axis. 2. Located on, around, or in the direction of an axis. ax . The ions are laser-cooled using the 194 nm [[blank].sup.2][S.sub.1/2] [right arrow] [[blank].sup.2][P.sub.1/2] electricdipole transitions shown in Fig. 5. Typically, a string of approximately ten ions is confined con·fine v. con·fined, con·fin·ing, con·fines v.tr. 1. To keep within bounds; restrict: Please confine your remarks to the issues at hand. See Synonyms at limit. near the trap axis. By minimizing the ion micro motion in all three dimensions, the laser-cooled ions are made to lie along the rf nodal line in a vibrating plate or cord, that line or point which remains at rest while the other parts of the body are in a state of vibration. See also: Nodal (36). Here, parametric heating is essentially eliminated, so the cooling-laser radiation, which perturbs the clock states, can be removed during the long probe periods of the clock transition. The trap is placed in a liquid-helium (4 K) cryogenic environment in which Hg and most background gases are cryopumped onto the walls of the chamber. This essentially eliminated ion loss due to collision with the background gas. In addition, collision shifts should be negligible. Operation at 4 K also reduces the frequency shifts due to blackbody radiation of the [[blank].sup.199][Hg.sup.+] ground-state hyperfine transition. At T = 4 K, the fractional blackbody blackbody Theoretical surface that absorbs all radiant energy that falls on it, and radiates electromagnetic energy at all frequencies, from radio waves to gamma rays, with an intensity distribution dependent on its temperature. Zeeman shift is -2 X [10.sup.-21], and the fractional blackbody Stark shift is -3 X [10.sup.-24] (20). 4.1.2 Laser-Atom Interactions Laser beams at 194 nm (37) are used for cooling, state preparation, and determining the internal states of the ions. To cool the ions, the frequency of a primary laser is tuned slightly below resonance with transition p (see Fig. 5). Although this is a cycling transition, the laser can off-resonantly excite an ion into the [[blank].sup.2][P.sub.1/2], F = 1 level, from which the ion can decay into the [[blank].sup.2][S.sub.1/2], F = 0 level. To maintain fluorescence, a repumping laser beam, resonant with transition r in Fig. 5, is overlapped collinearly with the primary laser beam. To prevent optical pumping into the dark states of the ground state F = 1 level, the 194 nm radiation (containing both r and p components) is split into two beams that are made to propagate prop·a·gate v. 1. To cause an organism to multiply or breed. 2. To breed offspring. 3. To transmit characteristics from one generation to another. 4. through the trap at an angle of 40[degrees] relative to each other ([+ or -]20[degrees] relative to the trap axis as shown in Fig. 6). The polarization of one beam is in the plane of the 194 nm beams, while the polarization of the other 194 nm beam is continuously modulated mod·u·late v. mod·u·lat·ed, mod·u·lat·ing, mod·u·lates v.tr. 1. To adjust or adapt to a certain proportion; regulate or temper. 2. between left and right circular. 4.1.3 Operation of the 40.5 GHz Microwave Clock The ions are prepared in the [[blank].sup.2][S.sub.1/2], F = 0 state by turning the repumping beam off. The atomic state after the clock radiation is applied is determined by pulsing on only the primary beam p for a time comparable to the time necessary to pump the ions from the [[blank].sup.2][S.sub.1/2], F = 1 to the [[blank].sup.2][S.sub.1/2], F = 0 level (typically 10 ms). If the ion is found in the [[blank].sup.2][S.sub.1/2], F = 1 level, it will scatter about [10.sup.4] photons before it optically pumps into the [[blank].sup.2][S.sub.1/2], F = 0 level. Approximately 150 of these photons are detected and counted. If the ion is found in the [[blank].sup.2][S.sub.1/2], F = 0 level, it will scatter only a few photons. For the first part of the measurement cycle, the ions are cooled by pulsing on both the primary and repumping 194 nm laser beams for 300 ms. Next, the repumping beam is turned off for about 60 ms, so that essentially all of the ions are optically pumped into the [[blank].sup.2][S.sub.1/2], F = 0 level. The clock transition is probed using the Ramsey technique of separated oscillatory fields (11). Both beams are blocked during the Ramsey microwave interrogation period, which consists of two 250 ms microwave pulses separated by the free precession period [T.sub.R]. [T.sub.R] is varied from 2 s to 200 s. Finally, the primary beam is turned on for 10 ms to 20 ms while counting the number of detected photons. This determines the ensemble average In statistical mechanics, the ensemble average is defined as the mean of a quantity that is a function of the micro-state of a system (the ensemble of possible states), according to the distribution of the system on its micro-states in this ensemble. of the atomic state population and completes one measurement cycle. The microwave frequency is derived from a synthesizer locked to a hydrogen maser. Stepping the synthesizer frequency between measurement cycles produces a set of Ramsey fringes. A digital servo locks the average synthesizer frequency to the central fringe. For seven trapped ions and [T.sub.R] = 100 s, the fractional frequency stability of the servoed oscillator is [[sigma].sub.y]([tau])=3 x [10.sup.-13][[tau].sup.1/2] for [tau] [less than or equal to] 2 h. Consistently, the measured [[sigma].sub.y]([tau]) is about twice the value expected from Eq. (1), primarily because of laser intensity fluctuations at the site of the ions. The stability of the ion standard is comparable to the stabilities of NIST-7 and NIST-F1. 4.1.4 Measurement Uncertainties Table 3 shows the most important corrections made to the average frequency for each run (38). The fractional Zeeman shift due to the static magnetic flux density magnetic flux density n. Symbol B The amount of magnetic flux through a unit area taken perpendicular to the direction of the magnetic flux. Also called magnetic induction. is +0.24 [B.sub.static.sup.2], where [B.sub.static] is in tesla tesla (tĕs`lə), unit of magnetic flux density: see under weber. . The measured Zeeman splitting of the ground state transitions gives [B.sub.static] [approximately equal to] 3 X [10.sup.-7] T, with fluctuations of 1 X [10.sup.-8] T. Thus the fractional uncertainty in this Zeeman shift is 1.4 X [10.sup.-15]. A correction is also made for the ac Zeeman shift that depends linearly on the rf power delivered to the trap. This shift is caused by magnetic fields due to asymmetric A difference between two opposing modes. It typically refers to a speed disparity. For example, in asymmetric operations, it takes longer to compress and encrypt data than to decompress and decrypt it. Contrast with symmetric. See asymmetric compression and public key cryptography. currents at frequency [OMEGA]/2[pi] in the trap electrodes Electrodes Tiny wires in adhesive pads that are applied to the body for ECG measurement. Mentioned in: Electrocardiography . These currents are caused by capacitance between the electrodes and stray capacitance to the ground plane. Considering the possibility that the current distribution may vary from load to load, the average transition frequency versus rf power is measured for each ion crystal, and in each case this is extrapolated to zero shift to give the unshifted frequency [v.sub.0]. An average was taken over five different ion crystals and [v.sub.0] was found to be independent of time within the uncertainty of the measurement. The uncertainty in the extrapolated frequency averaged over the five different crystals used in the frequency measurement is 3.2 X [10.sup.-15]. The magnitudes of several frequency shifts scale with the free precession time as 1/[T.sub.R]. These include shifts due to the phase chirp of the microwaves as they are switched on and off, any leakage microwaves as they are switched on and off, any leakage microwave field present during the free precession time [T.sub.R], and asymmetries in the microwave spectrum Noun 1. microwave spectrum - the part of the electromagnetic spectrum corresponding to microwaves spectrum - an ordered array of the components of an emission or wave electromagnetic spectrum - the entire frequency range of electromagnetic waves . By varying [T.sub.R], the fractional shift from these combined effects is measured to be -3(3) X [10.sup.-14]/[T.sub.R] (where [T.sub.R] is in s). The parenthetical 3 is the uncertainty of this measurement. The frequency of the reference maser is determined by comparing it to the frequency of International Atomic Time (time, standard) International Atomic Time - (TAI) An international standard measurement of time based on the comparison of many atomic clocks. TAI is maintained by the Bureau International des Poids et Mesures (BIPM), the world's governing body for civil atomic time measurement. (TAT TAT abbr. Thematic Apperception Test TAT 1. tube agglutination test. 2. tetanus antitoxin. TAT ). This determines the average frequency of the [Hg.sup.+] standard to be [v.sub.0] = 40 507 347 996.841 59(14)(41) Hz. Here, the first uncertainty is due to the systematic shifts shown in Table 3. The second uncertainty is due to the quoted uncertainty in the frequency of TAI. The Type B (systematic) uncertainty 3.4 X [10.sup.-15] is roughly comparable to the results obtained with cesium-beam and cesium-fountain frequency standards. The main uncertainties will certainly be reduced in future work. Better magnetic shielding will reduce fluctuations in the static magnetic field. The magnetic field at frequency [OMEGA]/2[pi] can be reduced by lowering [[omega].sub.r] and the trap dimensions. Finally, by monitoring each ion individually, the internal states can be determined with negligible uncertainty, which will eliminate noise due to frequency and intensity fluctuations of the detection laser. 4.2 Optical Frequency Standard A frequency standard based on the [[blank].sup.199][Hg.sup.+], 282 nm electric quadrupole transition ([[blank].sup.2][S.sub.1/2][left and right arrow][[blank].sup.2][D.sub.5/2] transition shown in Fig. 5), which has a natural linewidth of 1/(2[pi][[tau].sub.D]) = 1.7 Hz (where [[tau].sub.D] = 90 ms is the lifetime of the [[blank].sup.2][D.sub.5/2] state), is now being investigated (39). Since the clock transition [v.sub.0] is in the optical region ([v.sub.0] = 1.06 X [10.sup.-15] Hz), the fractional frequency stability can be very high as seen from Eq. (5). For example, for a single ion probed using the Ramsey technique with a free precession time of 25 ms, the fractional frequency stability is about 1 X [10.sup.-15] [[tau].sup.-1/2], two orders of magnitude lower than that of the [Hg.sup.+] microwave standard describe above. The frequency of a stabilized laser at 563 nm has been doubled and then locked to this transition in a single ion confined near the Lamb-Dicke limit in a linear Paul trap (40). The laser linewidth probing this transition has been independently measured to be as low as 0.22 Hz for a measurement time of 20 s (41). Figure 7 shows the linewidth of the transition for various lengths of the excitation pulse. The narrowest Fourier-transform-limited linewidth [DELTA]v of 6.7 Hz is obtained for a pulse time of 120 ms (33 % longer than the D-state lifetime!). This corresponds to Q [equivalent to] [v.sub.0]/[DELTA]v [approximately equal to] 1.6 X [10.sup.14], the largest Q ever achieved for optical spectroscopy spectroscopy Branch of analysis devoted to identifying elements and compounds and elucidating atomic and molecular structure by measuring the radiant energy absorbed or emitted by a substance at characteristic wavelengths of the electromagnetic spectrum (including gamma ray, . This high Q, combined with the relative freedom from environmental perturbation perturbation (pŭr'tərbā`shən), in astronomy and physics, small force or other influence that modifies the otherwise simple motion of some object. The term is also used for the effect produced by the perturbation, e.g. afforded by ion trapping trapping, most broadly, the use of mechanical or deceptive devices to capture, kill, or injure animals. It may be applied to the practice of using birdlime to capture birds, lobster pots to trap lobsters, and seines to catch fish. , suggest that trapped-ion optical-frequency standard should have significant advantages over present microwave frequency standards. These experiments used a cryogenically cooled, linear quadrupole trap similar to that used for the microwave standard described in the previous section. A single ion can be trapped and contained for an arbitrary period this trap (a single ion was held for several months until it was deliberately removed). The background gas pressure in the cryogenic trap is low, and there appear to be no observable ob·serv·a·ble adj. 1. Possible to observe: observable phenomena; an observable change in demeanor. See Synonyms at noticeable. 2. frequency shifts associated with any residual background-gas interactions. The present system is not magnetically shielded, and both magnetic-field shifts and electric-field shifts arising from patch potentials have been identified and evaluated at a level of 1 X [10.sup.-15]. It should be possible to reduce the uncertainties associated with all such effects to values approaching 1 X [10.sup.-18], particularly if the linear quadrupole trap is replaced by a spherical spher·i·cal adj. Having the shape of or approximating a sphere; globular. rf quadrupole trap that does not rely on static electric potentials for confinement. While this optical electric-quadrupole transition in [[blank].sup.199][Hg.sup.+] ion shows significant promise as a frequency standard, still narrower linewidth and lower uncertainty might be more easily achieved using other transitions (such as electric-dipole transitions) in other elements. Optical frequency standards, which enjoy a large advantage because of their very high Q, have not previously been favored as primary standards, since most applications of frequency standards are in the rf/microwave region of the spectrum, and it was difficult to accurately relate optical and microwave frequencies. However, recently developed methods for accurately measuring optical frequencies (42, 43) appear promising, and optical frequency standards should start to challenge their microwave counterparts in the next few years. 5. Summary and Discussion Figure 8 compares the uncertainties of a number of primary frequency standards, including NIST-7 and NIST-F1, for a period of more than 1000 days. This comparison involves evaluating the fractional frequency offset between a stable (but not accurate) frequency reference, AT1E, and six of the world's best primary frequency standards over a period of more than 1000 days. AT1E is a post-processed ensemble of five hydrogen masers at NIST and has a stability better than 1 X [10.sup.-15] for time intervals up to 100 days (44). This comparison could also have been made using International Atomic Time (TAI), except that the short-term stability of TAI is not as good as that of AT1E due to the noise of the time-transfer process involved in generating TAI. Some of the NIST-F1 measurements were made over short time intervals (on the order of a few days) and the noise of TAI would have dominated. In addition to NIST-F1 and NIST-7, Fig. 8 also shows data for two standards from Physikalisch-Technische Bundesanstalt The Physikalisch-Technische Bundesanstalt (PTB) is based in Braunschweig and Berlin. It is the national institute for natural and engineering sciences and the highest technical authority for metrology and physical safety engineering in Germany. (PTB PTB Physikalisch Technische Bundesanstalt (Germany) PTB Partido Trabalhista Brasileiro (Brazilian Labor Party) PTB Phosphotyrosine-Binding PTB Powers That Be PTB Power Tab ) in Germany and two from LPTF in France. The PTB standards are both magnetically state-selected thermal-beam standards, while the LPTF standards are a fountain standard (LPTF-F01) and an optically pumped thermal-beam standard (LPTF-JPO). Representative uncertainties for each standard are shown by the uncertainty bars. The fitted lines are calculated by the linear least-squares method and help to illustrate the long-term trends. AT1E exhibits a slow downward frequency drift In electrical engineering, and particularly in telecommunications, frequency drift is an unintended and generally arbitrary offset of an oscillator from its nominal frequency. , but the relative frequency offsets and frequency drifts of the standards are real. Though there are a few points that are outside the uncertainty bars, the agreement among the various standards has generally been very good. The NIST cesium-beam primary frequency standard has been engineered to run routinely. Substantially less engineering development has been done on the cesium-fountain frequency standard, which went into service only recently, and very little has been done to engineer a stored-ion frequency standard that can run routinely, primarily because the concepts for ion frequency standards have been evolving so rapidly. However, because of the narrow linewidths that can be realized and the very small values for systematic frequency shifts, the performance of the stored-ion standards likely will surpass those of the neutral-atom devices. Optical transitions in [[blank].sup.199][Hg.sup.+] or other ions are particularly interesting, because the relative line width (1/Q) is exceedingly small, systematic frequency shifts appear to be substantially smaller than those of neutral atom standards, and very high stability can be readily achieved. The recent demonstration of relatively simple optical combs that allow an accurate connection be tween tween n. A child between middle childhood and adolesence, usually between 8 and 12 years old. [Blend of teen1 and between.] the microwave and visible regions has removed a significant barrier to the use of optical transitions for primary frequency standards, and should speed progress toward the development of an optical frequency and time standard. It is interesting to consider the steady progress in improving frequency standards over the last fifty years. The historical record of the uncertainties of NBS/NIST atomic frequency standards is shown in Fig. 9. The roughly linear fit through these points indicates a reduction in uncertainty of better than one order of magnitude A change in quantity or volume as measured by the decimal point. For example, from tens to hundreds is one order of magnitude. Tens to thousands is two orders of magnitude; tens to millions is three orders of magnitude, etc. per decade. The development of primary frequency standards has been greatly stimulated by the new laser-cooling and state-control methods. In conclusion, it is worth noting that the first cooling below ambient temperature Outside temperature at any given altitude, preferably expressed in degrees centigrade. of any atomic species was done at NIST in 1978 (45) and the first neutral-atom laser cooling was also demonstrated at NIST in 1982 (46). These methods were developed just as the cesium-beam frequency standards were reaching their natural limits of evolution. Further improvement in these standards would have been small and difficult to achieve, since the key systematic frequency shifts limiting their performance were directly related to the larger (thermal) velocities of the atoms. For the moment it appears that the new methods can provide improvements of perhaps another two orders of magnitude or more, but many practical problems must be addressed in the process. About the authors: All authors are physicists or electrical engineers This is a list of electrical engineers, people who made contributions to electrical engineering or computer engineering.
6. References (1.) Documents concerning the new definition of the metre, Metrologia 19, 163-177 (1984). (2.) C. A. Hamilton, Josephson voltage standards, Rev. Sci. Instrum., to be published. (3.) J. H. Dellinger, Reducing the guesswork in tuning, Radio Broadcast 3, 137-149 (1923). (4.) E. L. Hall, V. E. Heaton and E. G. Lapham, The national primary standard of radio frequency, J. Res. Natl. Bur. Stand. (U.S.) 14, 85-98 (1935). (5.) H. Lyons, The atomic clock, Instruments 22, 133-135 (1949). (6.) R. E. Beehler, A historical review of atomic frequency standards, Proc. IEEE (Institute of Electrical and Electronics Engineers, New York, www.ieee.org) A membership organization that includes engineers, scientists and students in electronics and allied fields. 55, 792-805 (1967). (7.) N. F. Ramsey, History of atomic clocks, J. Res. Nat. Bur. Stand. (U.S.) 88, 301-320 (1983). (8.) W. F. Snyder and C. L. Bragaw, Achievement in Radio, NBS Spec. Publ. 555 (1986). (9.) E. Passaglia, A Unique Institution: The National Bureau of Standards, 1950-1969, NIST Spec. Publ. 925 (1999). (10.) I. I. Rabi, S. Millman, P. Kusch, and J. R. Zacharias, The molecular beam resonance method for measuring nuclear magnetic moments The nuclear magnetic moment is the magnetic moment of an atomic nucleus and arises from the spin of the protons and neutrons. It is mainly a magnetic dipole moment; the quadrupole moment does cause some small shifts in the hyperfine structure as well. , Phys. Rev. 55, 526-535 (1939). for a general discussion of the method, see N. F. Ramsey, Molecular Beams, Clarendon Press, Oxford (1956). (11.) N. F. Ramsey, The method of successive oscillatory fields, Phys. Today 33, 25-30 (1980). (12.) A. Kastler, Some suggestions concerning the production and detection by optical means of inequalities in the population levels of spatial quantization in atoms: application to the Stern and Gerlach and magnetic resonance magnetic resonance, in physics and chemistry, phenomenon produced by simultaneously applying a steady magnetic field and electromagnetic radiation (usually radio waves) to a sample of atoms and then adjusting the frequency of the radiation and the strength of the experiments, J. Phys. Rad. 11, 255-265 (1950). (13.) Andrea DeMarchi, Jon Shirley Jon Shirley is the former president of Microsoft and currently one of its directors. External links
glaze, translucent layer that coats pottery to give the surface a finish or afford a ground for decorative painting. Glazes—transparent, white, or colored—are fired on the clay. , and Robert Drullinger, A new cavity configuration for cesium beam primary frequency standards, IEEE Trans. Instrum. Meas. 37, 185-190 (1988). (14.) Jon H. Shirley, W. D. Lee, G. D. Rovera, and R. E. Drullinger, Rabi pedestal shifts as a diagnostic tool in primary frequency standards, IEEE Trans. Instrum. Meas. IM-46, 117-121 (1995). (15.) Robert E. Drullinger, David J. Glaze, J. P. Lowe, and Jon H. Shirley, The NIST optically pumped cesium frequency standard, IEEE Trans. Instrum. Meas. 40, 162-164 (1991). (16.) Robert E. Drullinger, Jon H. Shirley, J. P. Lowe, and David J. Glaze, Error analysis of the NIST optically pumped primary frequency standard, IEEE Trans. Instrum. Meas. 42, 453-456 (1993). (17.) W. D. Lee, J. H. Shirley, F. L. Walls, and R. E. Drullinger, Systematic errors in cesium beam frequency standards introduced by digital control of the microwave excitation, in Proc. 1995 IEEE lot. Symp. Freq. Control, IEEE Catalogue No. 95CH35752, 113-117 (1995). (18.) J. H. Shirley, Velocity distributions from the Fourier transforms Fourier transform In mathematical analysis, an integral transform useful in solving certain types of partial differential equations. A function's Fourier transform is derived by integrating the product of the function and a kernel function (an exponential function raised to of Ramsey line shapes, in Proc. 43rd Ann. Symp. Freq. Control, IEEE Cat. No. 89CH2690-6, 162-167 (1989). (19.) W. D. Lee, J. H. Shirley, and R. E. Drullinger, Velocity distributions of atomic beams Atomic beams Unidirectional streams of neutral atoms passing through a vacuum. These atoms are virtually free from the influence of neighboring atoms but may be subjected to electric and magnetic fields so that their properties may be studied. by gated optical pumping, in Proc. 1994 IEEE Inst. Symp. Freq. Control, IEEE Catalogue No. 94CH3446-2, 658-661 (1994). (20.) Wayne M. Itano, L.L. Lewis, and D.J. Wineland, Shift of 2S1/2 hyperfine splittings due to blackbody radiation, Phys. Rev. A 25, 1233-1235 (1982). (21.) J. Shirley, Fluorescent light shift in optically pumped cesium standards, Proc. 39th Ann. Symp. Freq. Control, IEEE Cat. No. 85CH2186-5, 22-23 (1985). (22.) W.D. Lee, John P. Lowe, Jon H. Shirley, and R.E. Drullinger, Microwave leakage as a source of frequency error and long-term instability in cesium atomic-beam frequency standards, Proc. 8th Eur. Freq. and Time Forum, Weihenstephan, Germany, 513-516 (1994). (23.) J. R. Zacharias, Precision measurements with molecular beams, Phys. Rev. 94, 751-751 (1954). (24.) M. Kasevich, E. Riis, S. Chu, and R. De Voe, rf spectroscopy in an atomic fountain, Phys. Rev. Lett. 63, 612-615 (1989). (25.) A. Clairon, S. Ghezali, G. Santarelli, Ph. Laurent, S. N. Lea, M. Bahoura, E. Simon, S. Weyers, and K. Szymaniec, Preliminary accuracy evaluation of a cesium fountain frequency standard, in Proc. Fifth Symp. on Freq. Standards and Metrology, J. C. Bergquist, editor, World Scientific, London (1996) pp. 49-59. (26.) For a discussion of MOT's and optical molasses see for example H. Metcalf and P. van der Straten, Cooling and trapping of neutral atoms, in Phys. Reports 244, 203-286 (1994). (27.) S. R. Jefferts, D. M. Meekhof, J. H. Shirley, T. E. Parker, and F. Levi, Preliminary accuracy evaluation of a cesium fountain primary frequency standard at NIST, in Proc. Joint Meeting of EFTF EFTF European Frequency and Time Forum EFTF Educational Facilities Task Force EFTF Ethernet Flow Termination Function and IEEE FCS FCS - Frame Check Sequence , IEEE Cat. No. 99CH36313, 12-15 (1999). (28.) S. R. Jefferts, R. E. Drullinger, and A. DeMarchi, NIST cesium fountain microwave cavities, in Proc. 1998 IEEE Int. Symp. Freq. Control, IEEE Cat. No. 98CH36165, 6-8 (1998). (29.) S. Ghezali, Ph. Laurent, S. N. Lea, and A. Clairon, An experimental study of the spin-exchange frequency shift in a laser-cooled cesium fountain frequency standard, Europhys. Lett. 36, 25-30 (1996). (30.) K. Gibble and S. Chu, Future slow-atom frequency standards, Metrologia 29, 201-212 (1992). (31.) J. H. Shirley, Some causes of resonant frequency resonant frequency, n the specific frequency at which an object vibrates. shifts in atomic beam machines, J. Appl. Phys. 34, 783-791 (1963). (32.) J. J. Bollinger, D. J. Heinzen, W. M. Itano, S. L. Gilbert and D. J. Wineland, A 303 MHZ frequency standard based on trapped [Be.sup.+] ions, IEEE Trans. Instrum. Meas. 40, 126-128 (1991). (33.) See for example, P. K. Ghosh, Ion Traps ion trap n. A device, such as a magnet, used to prevent ions in an electron beam from striking other apparatus. ion trap , Clarendon Press, Oxford (1995). (34.) W. M. Itano, J. C. Bergquist, J. J. Bollinger, J. M. Gilligan, D. J. Heinzen, F. L. Moore, M. G. Raizen, and D. J. Wineland, Quantum projection noise: population fluctuations in two-level systems, Phys. Rev. A 47, 3554-3557 (1993). (35.) M. E. Poitzsch, J. C. Bergquist, W. M. Itano, and D. J. Wineland, Cryogenic linear ion trap for accurate spectroscopy, Rev. Sci. Instrum. 67, 129-134 (1996). (36.) D. J. Berkeland, J. D. Miller, J. C. Bergquist, W. M. Itano, and D. J. Wineland, Minimization of ion micromotion in a Paul trap, J. Appl. Phys. 83, 5025-5033 (1998). (37.) D. J. Berkeland, F. C. Cruz, and J. C. Bergquist, Sum-frequency generation of continuous-wave light at 194 nm, Appl. Opt. 2006, 4159-4162 (1997). (38.) D. J. Berkeland, J. D. Miller, J. C. Bergquist, W M. Itano and D. J. Wineland, Laser-cooled mercury ion frequency standard, Phys. Rev. Lett. 80, 2089-2092 (1998). (39.) R. J. Rafac, B. C. Young, J. A. Beall, W. M. Itano, D. J. Wineland, and J. C. Bergquist, Sub-dekahertz ultraviolet spectroscopy of (199.) [Hg.sup.+] Phys. Rev. Lett., to be published. (40.) R. H. Dicke, The effect of collisions upon the Doppler width of spectral lines spectral line n. An isolated bright or dark line in a spectrum produced by emission or absorption of light of a single wavelength. spectral line , Phys. Rev. 89, 472-473 (1953). (41.) B. C. Young, R. J. Rafac, J. A. Beall, F. C. Cruz, W. M. Itano, D. J. Wineland, and J. C. Bergquist, [Hg.sup.+] optical frequency standard: recent progress, in Laser Spectroscopy Laser spectroscopy Spectroscopy with laser light or, more generally, studies of the interaction between laser radiation and matter. Lasers have led to a rejuvenescence of classical spectroscopy, because laser light can far surpass the light from other sources : XIV International Conference, R. Blatt, J. Eschner, D. Leibfried and F. Schmidt-Kaler, editors, World Scientific, London (1999) pp. 61-70. (42.) Th. Udem, J. Reichert, R. Holzwarth, and T. W. H[lambda]nsch, Accurate measurement of large optical frequency differences with a mode-locked laser, Opt. Lett. 24, 881-883 (1999). (43.) S. A. Diddams, D. J. Jones, Jun Ye, S. T. Cundiff, J. L. Hall, J. K. Ranka, R. S. Windeler, R. Holzwarth, T. Udem, and T. W. H[lambda]nsch, Direct link between microwave and optical frequencies with a 300 THz femtosecond laser comb comb 1. a vascular, red cutaneous structure attached in a sagittal plane to the dorsum of the skull of domestic fowl. It consists of a base attached to the skull, a central mass called the body, a backward projecting blade and upward projecting points. 2. , Phys. Rev. Lett. 84, 5102-5105 (2000). (44.) T. E. Parker, Hydrogen maser ensemble performance and characterization of frequency standards, Proc. Joint Meeting of EFTF and IEEE FCS, IEEE Cat. No. 99CH36313, 173-176 (1999). (45.) D. J. Wineland, R. E. Drullinger, and F. L. Walls, Radiation-pressure cooling of bound resonant absorbers, Phys. Rev. Lett. 40, 1639-1642 (1978). (46.) W. D. Phillips and H. J. Metcalf, Laser deceleration deceleration /de·cel·er·a·tion/ (de-sel?er-a´shun) decrease in rate or speed. early deceleration of an atomic beam, Phys. Rev. Lett. 48, 596-600 (1982). [Figure 2 omitted] [Figure 4 omitted] [Figure 5 omitted] [Figure 7 omitted] [Figure 9 omitted]
Table 1
Summary of frequency shifts and their Type B uncertainintes in NIST-7.
The total Type B uncertaininty is 4.1 X [10.sup.-15]
Physical effect Bias Type B uncertainty
(X [10.sup.-15]) (X [10.sup.-15])
Second-order Doppler
West-to-east -288 1
East-to-west -287
Second-order Zeeman +147 676.0 0.1
Cavity pulling -6.0 0.5
Rabi pulling < -0.1 0.1
Cavity phase (end-to-end)
West-to-east +717 0.1
East-to-west -617
Cavity phase (distributed) -1.3 0.4
Flouroescence light -0.01 3
Blackbody -20.4 0.5
Gravitation +179.9 0.1
Electronics
rf spectral purity 0 0.1
Integrator offset 0 1
AM on rf or laser 0 1
Microwave leakage 0 0.1
PLL and optical transients -1.5 2
Table 2.
Summary of the largest systematic frequency shifts in NIST-F1. The
uncertainties for all items not listed are <[10.sup.-16]. The total type
B uncertainty is 0.8 X [10.sup.-15]
Physical effect Bias Type B
(X [10.sup.-15]) uncertainty
(X [10.sup.-15])
Second-order Zeeman +45.0 0.3
Spin exchange -0.9 0.5
Blackbody -20.6 0.3
Gravitation +180.54 0.1
Microwave leakage 0 0.2
Table 3.
Largest systematic shifts of the average mercury-ion-clock transition
frequency. Typical values are for an rf power of 20 mW, a Ramsey
interrogation time T = 100 s, and a static magnetic flux density
[B.sub.static] = 3 x [10.sup.-7] T. Here, B is the flux-density
component at frequency [OMEGA]/2[pi]
Physical effect Scaling Bias
(X [10.sup.-15])
Quadratic Zeeman (static) +([B.sub.static.sup.2]) 20
Quadratic Zeeman ([OMEGA]) +([B.sup.2]) 5
Microwave chirp, leakage,
and spectrum asymmetries 1/[T.sub.R] 3
Physical effect Type B
uncertainty
(X [10.sup.-15])
Quadratic Zeeman (static) 1.4
Quadratic Zeeman ([OMEGA]) 3.2
Microwave chirp, leakage,
and spectrum asymmetries 0.8
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is non-negative for arbitrarily large 
.
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