_{1}

^{*}

The purpose of this work is to prove that only by applying a theoretically sound information approach to developing a model for measuring the Boltzmann constant, one can justify and calculate the value of the required relative uncertainty. A dimensionless parameter (comparative uncertainty) was proposed as a universal metric for comparing experimental measurements of Boltzmann constant and simulated data. Examples are given of applying the proposed original method for calculating the relative uncertainty in measuring the Boltzmann constant using an acoustic gas thermometer, dielectric constant gas thermometer, Johnson noise thermometer, Doppler broadening thermometer. The proposed approach is theoretically justified and devoid of the shortcomings inherent in the CODATA concept: a statistically significant trend, a cumulative value of consensus or a statistical control. We tried to show how a mathematical-expert formalism can be replaced by a simple, theoretically grounded postulate on the use of information theory in measurements.

In 2018, for the first time in the history of modern science, a unique decision was taken: a modification of the International System of Units (SI). It is based on the redefinition of the four basic units of kilogram, ampere, kelvin and mole of the SI in terms of fundamental physical constants. The basic unit of thermodynamic temperature θ, kelvin, was based on a fixed numerical value of the Boltzmann constant k = 1.380649 × 10^{-23} J・K^{-1}. This became possible only due to the unique methods of measuring the Boltzmann constant. However, the numerical value of the Boltzmann constant is fixed only when special requirements are met for the relative uncertainty of measurement [^{−6}; the determination of k is based on at least two fundamentally different methods, of which at least one result for each shall have a relative standard uncertainty less than 3 × 10^{−6}. To calculate the value of relative uncertainty, modern statistical methods and supercomputers are used. Besides, at each stage of evaluating the results, an expert analysis of the obtained data is carried out. It means to use the specialist’s own intuition, knowledge and experience (one’s personal philosophical leanings [

In contradiction with CODATA (The Committee on Data for Science and Technology) statistics-expert techniques, the proposed method [

In this paper, we have focused on a very important application of the information-based method: analysis of the relative uncertainty in the measurements of the Boltzmann constant.

The approach, called the μ_{SI}-hypothesis, was formulated in [

ε = Δ u / S ≤ [ ( z ′ − β ′ ) / ( Ψ − ξ ) + ( z ″ − β ″ ) / ( z ′ − β ′ ) ] (1)

where Δu is the dimensionless uncertainty of the physical-mathematical model describing the measurement experiment:

(1) ξ is the number of base quantities with independent dimension; SI includes the following seven (ξ = 7) base quantities: L is the length, M is mass, Т is time, I is electric current, Θ is thermodynamic temperature, J is force of light, F is a number of substances. The dimension of any derived quantity q can only express a unique combination of dimensions of base quantities in different degrees [

q ⊃ L l ⋅ M m ⋅ T t ⋅ I i ⋅ Θ Θ ⋅ J j ⋅ F f . (2)

(2) l , m , ⋯ , f are exponents of quantities, the range of each has maximum and minimum values; according to^{8}, integers are the following:

− 3 ≤ l ≤ + 3 , − 1 ≤ m ≤ + 1 , − 4 ≤ t ≤ + 4 , − 2 ≤ i ≤ + 2 , − 4 ≤ Θ ≤ + 4 , − 1 ≤ j ≤ + 1 , − 1 ≤ f ≤ + 1 ; (3)

(3) The exponents of quantities take only integer values [_{k}, { l , m , ⋯ , f } according to (3) is the following:

е l = 7 ; е m = 3 ; е t = 9 ; е i = 5 ; е θ = 9 ; е j = 3 ; е f = 3 ; (4)

(4) The total number of dimension options of physical quantities equals Ψ ∗ = ∏ l f e i − 1

Ψ ∗ = е l ⋅ е m ⋅ е t ⋅ е i ⋅ е θ ⋅ е j ⋅ е f − 1 = 7 × 3 × 9 × 5 × 9 × 3 × 3 − 1 = 76544 , (5)

where “−1” corresponds to the situation when all exponents of base quantities in the formula (2) are treated as zero dimension; П is a product of е_{k};

(5) The value Ψ ∗ includes both required, and inverse quantities (for example, L¹―length, L^{−}^{1}―running length). That is why the object can be judged knowing only one of its symmetrical parts, while others structurally duplicating this part may be regarded as information empty [

Ψ = Ψ ∗ / 2 = 38272 ; (6)

(6) z ′ is the total number of dimensional physical quantities in the chosen class of phenomena (CoP); in SI frames, every researcher selects a particular CoP to study a material object. CoP is a set of physical phenomena and processes described by a finite number of primary and secondary quantities that characterize certain features of a material object from the view of qualitative and quantitative aspects [_{SI} ≡ LMТθF and CoP_{SI} ≡ LMТθI;

(7) β ′ is the number of base physical quantities in the chosen CoP.

Taking into account the π-theorem [

μ SI = Ψ – ξ = 38265 . (7)

Equation (1) quantifies Δu/S caused by the limited number of quantities taken into account in the theoretical or experimental analysis of the researched quantity. On the other hand, it also sets a limit on the expedient increasing of the measurement accuracy in conducting experimental studies. In turn, Δu/S is not a purely mathematical abstraction. It has a physical meaning, consisting in the observation that in nature there is a fundamental limit to the accuracy of displaying any observed material object, which cannot be surpassed by any improvement of instruments and methods of measurement. The reality of the environment is the obvious a priori condition for the modelling of the investigated material object. By allocating the interested process or phenomenon, the unknown relationships between the content of the object and the environment are “broken”. In this context, it is obvious that an overall uncertainty of the model including inaccurate input data, physical assumptions, the approximate solution of the integral-differential equations, etc., will be larger than Δu. Thus, Δu is only one lowest component of a possible mismatch of the real object and its modelling results.

In fact, Equation (1) can be regarded as the conformity principle (uncertainty relation) for the process of model development. No model can produce results that contradict relation (1). That is, any change in the level of the detailed description of the observed object ( z ″ − β ″ ; z ′ − β ′ ) causes a change in the minimum comparative uncertainty value Δu/S of the model of a specific CoP and in the achieved accuracy of each main quantity, characterizing the internal structure of the object. In other words, the conformity principle fundamentally establishes the accuracy limit (for a given class of phenomena) of simultaneously defining a pair of quantities, observed by a conscious researcher, particularly, the absolute uncertainty in the measurement of the investigated quantity and the interval of its changes.

Equating the derivative of Δu/S (1) with respect to z ′ − β ′ , to zero, we obtain the condition for achieving the minimum comparative uncertainty for a particular CoP:

( z ′ − β ′ ) 2 / ( Ψ − ξ ) = ( z ″ − β ″ ) (8)

Let us apply the information approach for analysing measurement results of the Boltzmann constant by the use of four different methods.

For these purposes, the reader needs to remember that if the range of observation S is not defined, the information obtained during the observation/measurement cannot be determined, and the entropic price becomes infinitely large [

CoP_{SI} | Comparative uncertainty | Number of criteria |
---|---|---|

LMТ | 0.0048 | 0.2 < 1 |

LMТF | 0.0146 | ≅ 2 |

LMТI | 0.0245 | ≅ 6 |

LMТθ | 0.0442 | ≅ 19 |

LMТIF | 0.0738 | ≅ 52 |

LMТθF | 0.1331 | ≅ 169 |

LMТθI | 0.2220 | ≅ 471 |

LMТθFI | 0.6665 | ≅ 4249 |

of metrology [

That is why, taking into account Brillouin’s suggestions, there are two options for applying the conformity principle to analyse the measurement data of the fundamental physical constants.

First, this principle dictates, factually, analysing the data of the magnitude of the achievable relative uncertainty at the moment taking into account the latest results of measurements. The extended range of changes in the quantity under study S indicates an imperfection of the measuring devices, which leads to a large value of the relative uncertainty. The development of measuring technology, the increase in the accuracy of measuring instruments, and the improvement in the existing and newly created measurement methods together lead to an increase in the knowledge of the object under study and, consequently, the magnitude of the achievable relative uncertainty decreases. However, this process is not infinite and is limited by the conformity principle. The reader should bear in mind that this conformity principle is not a shortcoming of the measurement equipment or engineering device but of the way the human brains work. When predicting the behaviour of any physical process, physicists are, in fact, predicting the perceivable output of instrumentation. It is true that, according to the µ-hypothesis, observation is not a measurement but a process that creates a unique physical world with respect to each particular observer. Thus, in this case, the range of observation (possible interval of placing) of the fundamental physical constant S is chosen as the difference between the maximum and minimum values of the physical constant measured by different scientific groups during a certain period of recent years. Only in the presence of the results of various experiments can one speak about the possible appearance of a measured value in a certain range. Thus, using the smallest attainable comparative uncertainty inherent in the selected class of phenomena during measuring the fundamental constant, it is possible to calculate the recommended minimum relative uncertainty that is compared with the relative uncertainty of each published study. In what follows, this method is denoted as IARU and includes the following steps:

1) From the published data of each experiment, the value z, relative uncertainty r_{z} and standard uncertainty u_{z} (possible interval of u placing) of the fundamental physical constant are chosen;

2) The experimental absolute uncertainty Δ_{z} is calculated by multiplying the fundamental physical constant value z and its relative uncertainty r_{z} attained during the experiment, Δ_{z} = z・r_{z};

3) The maximum z_{max} and minimum z_{min} values of the measured physical constant are selected from the list of measured values z_{i} of the fundamental physical constant obtained in different studies;

4) As a possible interval for placing the observed fundamental constant S_{z}, the difference between the maximum and minimum values is calculated, S_{z} = z_{max} − z_{min};

5) The selected comparative uncertainty ε_{T} (_{z} to obtain the absolute experimental uncertainty value Δ_{IARU} in accordance with the IARU, Δ_{IARU} = ε_{T}・S_{z};

6) To calculate the relative uncertainty r_{IARU} in accordance with the IARU, this absolute uncertainty Δ_{IARU} is divided by the arithmetic mean of the selected maximum and minimum values, r I A R U = Δ I A R U / ( ( z max + z min ) / 2 ) ;

7) The relative uncertainty obtained r_{IARU} is compared with the experimental relative uncertainties r_{i} achieved in various studies;

8) According to IARU, a comparative experimental uncertainty of each study, ε_{IARUi} is calculated by dividing the experimental absolute uncertainty of each study Δ_{z} by the difference between the maximum and minimum values of the measured fundamental constant S_{z}, ε_{IARUi} = Δ_{z}/S_{z}. These calculated comparative uncertainties are also compared with the selected comparative uncertainty ε_{T} (

Second, S is determined by the limits of the measuring devices used [

1) From the published data of each experiment, the value z, relative uncertainty r_{z} and standard uncertainty u_{z} (possible interval of placing) of the fundamental physical constant are chosen;

2) The experimental absolute uncertainty Δ_{z} is calculated by multiplying the fundamental physical constant value z and its relative uncertainty r_{z} attained during the experiment, Δ_{z} = z・r_{z};

3) The achieved experimental comparative uncertainty of each published research ε_{IACUi} is calculated by dividing the experimental absolute uncertainty Δ_{z} by the standard uncertainty u_{z}, ε_{IACUi} = Δ_{z}/u_{z};

4) The experimental calculated comparative uncertainty ε_{IACUi} is compared with the selected comparative uncertainty ε_{T} (

First, confirm that you have the correct template for your paper size. This template has Acoustic gas thermometry (AGT) relates the speed of sound in a gas of known composition to the thermodynamic temperature. A detailed description of the design of the experimental method of measurement of the Boltzmann constant by the AGT method is presented in [_{SI} ≡ LMТΘF [

Following the IARU method, one can discuss the order of the desired value of the relative uncertainty belonging to CoP_{SI} ≡ LMТQF. An estimated observation interval of k is chosen as the difference in its values obtained from the experimental results of two projects: k_{max} = 1.3806508 × 10^{−23} m^{2}・kg・s^{−2}・K^{−1} [_{min} = 1.3806484 × 10^{−23} m^{2}・kg・s^{−2}・K^{−1} [_{k} of k placing is equal to:

S k = k max − k min = 2.4 × 10 − 29 m 2 ⋅ kg / ( s 2 ⋅ K ) (9)

For this purpose, taking into account (4) and (8), one can arrive at the lowest comparative uncertainty ε_{LMTθF} using the following conditions:

( z ′ − β ′ ) L M T θ F = ( е l ⋅ е m ⋅ е t ⋅ е θ ⋅ е f − 1 ) / 2 − 5 = ( 7 × 3 × 9 × 9 × 3 − 1 ) / 2 − 5 = 2546 (10)

( z ″ − β ″ ) L M T θ F = ( z ′ − β ′ ) 2 / μ S I = 2546 2 / 38265 ≈ 169 (11)

where “−1” corresponds to the case where all the base quantities exponents are zero in formula (1); 5 corresponds to the five base quantities L, M, T, Θ and F; and division by 2 indicates that there are direct and inverse quantities, e.g., L^{1} is the length and L^{−1} is the run length. The object can be judged based on the knowledge of only one of its symmetrical parts, while the other parts that structurally duplicate this one may be regarded as information empty. Therefore, the number of options of dimensions may be reduced by a factor of two.

According to (8), (10) and (11):

ε L M T θ F = ( Δ u / S ) L M T θ F = 2546 / 38265 + 169.4 / 2546 = 0.1331 (12)

Then, the lowest possible absolute uncertainty for CoP_{SI} ≡ LMТΘF is given by the following:

Δ L M T θ F = ε L M T θ F ⋅ S k = 0.1331 × 2.4 × 10 − 29 = 3.2 × 10 − 30 m 2 ⋅ kg / ( s 2 ⋅ K ) (13)

In this case, the lowest possible relative uncertainty (r_{min})_{LMTθF} for CoP_{SI} ≡ LMТΘF is the following:

r L M T θ F = Δ L M T θ F / ( ( k max + k min ) / 2 ) = 3.2 × 10 − 30 / 1.38064961 × 10 − 23 = 2.3 × 10 − 7 (14)

This value agrees well with [^{−7} cited in [

Guided by the IACU and IARU methods, one can calculate the achieved comparative uncertainty in each experiment (_{LMТθF} = 0.1331 and the experimental magnitudes achieved during measuring k. The difference may be explained by the following. AGT is based on the definition of an ideal gas behaviour in spite that the interaction between the gas particles is not sufficiently known. In addition, it is impossible to measure the molar concentration of gas per unit volume and volume itself with a competitive degree of accuracy. Moreover, the latter includes the volume of connecting pipes to pressure gauges. Thus, there are significant unrecorded uncertainties associated both with the formulation of the model of the experiment and with the achievable accuracy of the quantities taken into account in the calculation. It must be noted that the proximity of the acoustic mode to the shell resonance perturbs the data for this mode to an unacceptably large degree. In addition, experimenters take into account a very contrasting number of quantities in comparison to the recommendations (see

In the DCGT, the gas dielectric constant ε_{r}(p) is measured as a function of pressure to determine the temperature. To verify the Boltzmann constant, measurements are performed at a known temperature, the triple point of water (TTPW = 273.16 K), and a k value extracted from the Clausius-Mossotti ratio modified by the corresponding virial terms. The principle is quite simple: the capacitance C(p) of a capacitor in a gas and its value in vacuum C(0) are measured. Then, their ratio is calculated to extract the value of ε_{r}. The value of k is then derived from ε_{r} using the known molar polarizability, the density and dielectric virial coefficients [

The measurement data are summarized in _{SI} ≡ LMТΘI [

Year | CoP | Boltzmann’s constant | Achieved relative uncertainty | Absolute uncertainty | k_{b} possible interval of placing* | Calculated comparative uncertainty | Calculated comparative uncertainty | Ref. | |
---|---|---|---|---|---|---|---|---|---|

k・10^{23} | r_{k}・10^{6} | Δ_{k}・10^{29} | u_{k}・10^{29} | Ε_{k}' = Δ_{k}/u_{k} IACU | ε_{k}'' = Δ_{k}/S_{k} IARU | ||||

m^{2} kg/(s^{2} K) | m^{2} kg/(s^{2} K) | m^{2} kg/(s^{2} K) | |||||||

2009 | LMТQ F | 1.3806495 | 2.7 | 3.73 | 7.4 | 0.5038 | 1.1393 | [ | |

2010 | 1.3806496 | 3.1 | 4.28 | 8.8 | 0.4864 | 1.3081 | [ | ||

2015 | 1.3806487 | 2.0 | 2.76 | 2.7 | 1.0227 | 0.8439 | [ | ||

2015 | 1.3806508 | 1.1 | 1.52 | 2.9 | 0.5237 | 0.4642 | [ | ||

2017 | 1.3806488 | 0.6 | 0.83 | 1.6 | 0.5177 | 0.2532 | [ | ||

2017 | 1.3806486 | 0.7 | 0.97 | 2.0 | 0.4832 | 0.2954 | [ | ||

2017 | 1.3806484 | 2.0 | 2.76 | 5.5 | 0.5020 | 0.8439 | [ | ||

* Data are introduced in [

Year | CoP | Boltzmann’s constant | Achieved relative uncertainty | Absolute uncertainty | k_{b} possible interval of placing* | Calculated comparative uncertainty | Calculated comparative uncertainty | Ref. | |
---|---|---|---|---|---|---|---|---|---|

k・10^{23} | r_{k}・10^{6} | Δ_{k}・10^{29} | u_{k}・10^{29} | ε_{k}' = Δ_{k}/u_{k} IACU | ε_{k}'' = Δ_{k}/S_{k} IARU | ||||

m^{2} kg/(s^{2} K) | m^{2} kg/ (s^{2} K) | m^{2} kg/ (s^{2} K) | |||||||

2012 | LMТQ I | 1.38066509 | 7.9 | 1.09 | 6.7 | 1.6279 | 4.5983 | [ | |

2013 | 1.38066509 | 4.3 | 5.94 | 1.2 | 4.9473 | 2.5029 | [ | ||

2015 | 1.38066509 | 4.0 | 5.52 | 11.0 | 0.5020 | 2.3282 | [ | ||

2017 | 1.3806482 | 1.9 | 2.62 | 5.2 | 0.5044 | 1.1059 | [ | ||

2018 | 1.38064904 | 0.37 | 0.51 | 1.0 | 0.5184 | 0.2154 | [ | ||

2018 | 1.3806490 | 0.37 | 0.51 | 1.0 | 0.5184 | 0.2154 | [ | ||

* Data are introduced in [

Following the method IARU, one can discuss the order of the desired value of the relative uncertainty belonging to CoP_{SI} ≡ LMТΘI. An estimated observation interval of k is chosen as the difference in its values obtained from the experimental results of two projects: k_{max} = 1.38066509 × 10^{−23} m^{2}・kg・s^{−2}・K^{−1} [_{min} = 1.3806482 × 10^{−23} m^{2}・kg・s^{−2}・K^{−1} [_{k} of k placing is equal to:

S k = k max − k min = 2.7 × 10 − 29 m 2 ⋅ kg / ( s 2 ⋅ K ) (15)

For this purpose, taking into account (4) and (8), one can arrive at the lowest comparative uncertainty ε_{LMTθI} using the following conditions:

( z ′ − β ′ ) L M T θ I = ( е l ⋅ е m ⋅ е t ⋅ е θ ⋅ е i − 1 ) / 2 − 5 = ( 7 × 3 × 9 × 9 × 5 − 1 ) / 2 − 5 = 4247 (16)

( z ″ − β ″ ) L M T θ I = ( z ′ − β ′ ) 2 / μ S I = 4247 2 / 38265 ≈ 471 (17)

where “−1” corresponds to the case where all the base quantities exponents are zero in formula (1); 5 corresponds to the five base quantities L, M, T, Θ and I; and division by 2 indicates that there are direct and inverse quantities, e.g., L^{1} is the length and L^{−1} is the run length. The object can be judged based on the knowledge of only one of its symmetrical parts, while the other parts that structurally duplicate this one may be regarded as information empty. Therefore, the number of options of dimensions may be reduced by a factor of two.

According to (16) and (17):

ε L M T θ I = ( Δ u / S ) L M T θ I = 4247 / 38265 + 471 / 4247 = 0.222 (18)

Taking into account (18), the lowest possible absolute uncertainty for DCGT (CoP_{SI} ≡ LMТΘI) is given by the following:

Δ L M T θ I = ε L M T θ I ⋅ S k = 0.222 × 2.7 × 10 − 29 = 6.0 × 10 − 30 m 2 ⋅ kg / ( s 2 ⋅ K ) (19)

In this case, the lowest possible relative uncertainty (r_{min})_{LMTθI} for DCGT and the achieved mentioned results is the following:

r L M T θ I = Δ L M T θ I / ( ( k max + k min ) / 2 ) = 6.0 × 10 − 30 / 1.38064955 × 10 − 23 = 4.3 × 10 − 7 (20)

This value is in a strong contradiction with the recommendation of 3.7 × 10^{−7} cited in [_{SI} ≡ LMТΘI), i.e. 4.3 × 10^{−7}. In other words, there are unrecorded uncertainties in [

Guided by the IACU and IARU methods, one can calculate the achieved comparative uncertainty in each experiment (_{LMТθI} = 0.222 and the experimental magnitudes achieved during measuring k by DCGT. At the same time, progress to achieving a higher accuracy is obvious during the last four years.

Significant differences in the values of the comparative uncertainties achieved in the experiments and calculated in accordance with the IACU can be explained as follows. Within the framework of the information approach, the concept of comparative uncertainty assumes an equally probable account of various quantities, regardless of their specific choice by scientists when formulating a model for measuring k. Based on their experience, intuition and knowledge, the researchers build a model containing a small number of quantities, and which, in their opinion, reflects the fundamental essence of the process under investigation. In this case, many phenomena, perhaps not significant, secondary, which are characterized by specific quantities, are not taken into account.

For example, in DCGT, the measuring gas (helium) has very low polarizability, which prevents absolute measurements of a dielectric constant ε. It is calculated from the relative change in capacitance of a capacitor. Because of the necessary hydrostatic correction, pressure measurement is a limiting factor, besides dielectric virial corrections and compressibility problems. During the measurement, pairs of values of the pressure p and of the dielectric constant ε are recorded at a temperature which must be constant, however, very small fluctuations exists. k is determined from the function ε(p), a component of which must be linearly approximated. In addition, the applied high gas pressures cause a deformation of the measuring capacitors. Thus, there are significant unrecorded uncertainties associated both with the formulation of the model of the experiment and with the achievable accuracy of the quantities taken into account in the calculation. Besides, experimenters take into account a very contrasting number of quantities in comparison to the recommendations (see

In the JNT technique a well-characterized noble gas and pressure measurements are used at the frontier of accuracy, as well as primary level electrical metrology to measure minute changes in tiny capacitances (≈10 pF). Thermodynamic temperature is derived from the statistical movement of electrons in an ohmic resistor, generating a noise voltage (white noise). JNT determines the temperature from the mean square of the noise voltage by means of the Nyquist formula [

The measurement data are summarized in _{SI} ≡ LMТΘI [

Following the method IARU, one can discuss the order of the desired value of the relative uncertainty belonging to CoP_{SI} ≡ LMТΘI. An estimated observation

Year | CoP | Boltzmann’s constant | Achieved relative uncertainty | Absolute uncertainty | Calculated comparative uncertainty* | Ref. | |
---|---|---|---|---|---|---|---|

k・10^{23} | r_{k}・10^{6} | Δ_{k}・10^{29} | ε_{k}'' = Δ_{k}/S_{k} IARU | ||||

m^{2} kg/(s^{2} K) | m^{2} kg/(s^{2} K) | ||||||

2011 | LMТQ I | 1.38065200 | 12.0 | 16.7 | 7.0430 | [ | |

2015 | 1.38065160 | 3.9 | 5.4 | 2.2700 | [ | ||

2015 | 1.38064974 | 71.0 | 98.0 | 41.326 | [ | ||

2017 | 1.38064974 | 2.7 | 3.7 | 1.5716 | [ | ||

2017 | 1.38064300 | 5.0 | 6.9 | 2.9103 | [ | ||

2017 | 1.38064360 | 10.0 | 14.1 | 5.9370 | [ | ||

* No summarized data about a value of the standard uncertainty required for calculation of the comparative uncertainty by IACU.

interval of k is chosen as the difference in its values obtained from the experimental results of two projects: k_{max} = 1.38065200 × 10^{−23} m^{2}・kg・s^{−2}・K^{−1} [_{min} = 1.38064300 × 10^{−23} m^{2}・kg・s^{−2}・K^{−1} [_{k} of k placing is equal to:

S k = k max − k min = 9.0 × 10 − 29 m 2 ⋅ kg / ( s 2 ⋅ K ) (21)

According to (16) and (17):

ε L M T θ I = ( Δ u / S ) L M T θ I = 4247 / 38265 + 471 / 4247 = 0.222 (22)

Taking into account (23), the lowest possible absolute uncertainty for JNT (CoP_{SI} ≡ LMТΘI) is given by the following:

Δ L M T θ I = ε L M T θ I ⋅ S k = 0.222 × 9.0 × 10 − 29 = 2.0 × 10 − 29 m 2 ⋅ kg / ( s 2 ⋅ K ) (23)

In this case, the lowest possible relative uncertainty (r_{min})_{LMTθI} for JNT and the achieved mentioned results is the following:

r L M T θ I = Δ L M T θ I / ( ( k max + k min ) / 2 ) = 2.0 × 10 − 29 / 1.3806475 × 10 − 23 = 1.4 × 10 − 6 (24)

This value agrees well with [_{LMТθI} = 0.222 and the experimental magnitudes achieved during measuring k by JNT. Unfortunately, there has been no progress to achieve higher accuracy during the last eight years.

There are obvious problems that can apparently be solved: a long measurement time required for low uncertainty. To achieve a relative uncertainty in the range of 1 × 10^{−5} with a normal detection bandwidth of 20 kHz, a measurement time of about 5 weeks is required, during which unpredictable voltage surges in the network are possible. In addition, because of the inconsistency between the transfer lines of the thermal resistor and of the reference noise source, the experimental ratio spectrum varies with frequency. Therefore, the power spectral density ratio of the noise of the resistor to the noise of the quantum voltage must be simulated, causing another significant source of error. Progress in reducing the uncertainty of these factors suggests that a high potential of this method is possible when measuring the Boltzmann constant.

The DBT method uses the measurement of the Doppler width of the spectral line in a gas at a known temperature to determine the value of the Boltzmann constant. All experiments consist in measuring the Doppler width for a sample maintained at a temperature very close to TTPW. In principle, many different atoms or molecules can be used for the Doppler method of thermometry. Small, simple, non-polar, seemingly the best choice: the lighter the mass, the greater the Doppler width at a given temperature; in addition, lighter molecules have more widely separated vibrational transitions than heavy molecules. Non-polar molecules (O_{2}, CO_{2}, C_{2}H_{2}) have lower collisional self-expansion than polar ones. Ultimately, the choices made by groups measuring the Boltzmann constant were often based on history, previous knowledge of the molecular structure, and equipment developed at the appropriate wavelength [

Following the method IARU, one can discuss the order of the desired value of the relative uncertainty belonging to CoP_{SI} ≡ LMТΘF. An estimated observation interval of k is chosen as the difference in its values obtained from the experimental results of two projects: k_{max} = 1.380802 × 10^{−23} m^{2}・kg・s^{−2}・K^{−1} [_{min} = 1.3805813 × 10^{−23} m^{2}・kg・s^{−2}・K^{−1} [_{k} of k placing is equal to:

S k = k max − k min = 2.2 × 10 − 27 m 2 ⋅ kg / ( s 2 ⋅ K ) (25)

Taking into account (25), the lowest possible absolute uncertainty for DBT (CoP_{SI} ≡ LMТΘF) is given by the following:

Δ L M T θ F = ε L M T θ F ⋅ S k = 0.222 × 2.2 × 10 − 27 = 2.9 × 10 − 28 m 2 ⋅ kg / ( s 2 ⋅ K ) (26)

In this case, the lowest possible relative uncertainty (r_{min})_{LMTθI} for DBT and the achieved mentioned result is the following:

r L M T θ F = Δ L M T θ I / ( ( k max + k min ) / 2 ) = 2.9 × 10 − 28 / 1.38069165 × 10 − 23 = 2.1 × 10 − 5 (27)

This value agrees well with [_{LMТθI} = 0.222 and the experimental values achieved by measuring k with the DBT method. However, sufficient progress to achieve higher accuracy in the last eight years is obvious. To improve the accuracy of measurements, it is necessary to solve the following problems.

Year | CoP | Boltzmann’s constant | Achieved relative uncertainty | Absolute uncertainty | Calculated comparative uncertainty* | Ref. | |
---|---|---|---|---|---|---|---|

k・10^{23} | r_{k}・10^{5} | Δ_{k}・10^{28} | ε_{k}'' =Δ_{k}/S_{k} IARU | ||||

m^{2} kg/(s^{2} K) | m^{2} kg/(s^{2} K) | ||||||

2007 | LMТQ F | 1.38065260 | 19.0 | 26.2 | 110.59 | [ | |

2008 | 1.38066952 | 3.8 | 5.2 | 22.119 | [ | ||

2009 | 1.38080200 | 14.0 | 19.9 | 83.826 | [ | ||

2011 | 1.38058130 | 16.0 | 22.1 | 93.125 | [ | ||

2014 | 1.38066120 | 8.7 | 12.0 | 50.640 | [ | ||

2015 | 1.38066313 | 2.4 | 3.3 | 13.969 | [ | ||

* No summarized data about a value of the standard uncertainty required for calculation of the comparative uncertainty by IACU.

In DBT, the shape of the absorption line is not a purely Gaussian profile due to collisional broadening (the natural width of the line due to spontaneous emission is usually negligible). For polyatomic molecules, such as water and ammonia, used to measure k, the pressure-dependent broadening coefficients cannot be calculated at the beginning. In addition, line shapes are analysed using more or less complex models, none of which describe ideally the interaction of light and matter. The validity of such models is a stumbling block for higher accuracy. In this respect, atomic helium has non-ideal properties. Although its collision broadening coefficients can be calculated with slight uncertainty, helium resonance lines lie in the vacuum ultraviolet range, where there are no sources of continuous laser waves yet. Even in this case, besides fragile window cells and detectors, photoionization of excited particles will undoubtedly complicate the analysis of the line shape [

The reality is not so simple. Estimates and measurements always have uncertainties. This concept is absolutely important for scientific research: what you know is far less important than how well you know it. The real main idea of any scientific discussion is to delve into uncertainties and how they are evaluated.

As mentioned above, to estimate the accuracy achieved in various natural and technological processes, including measurements of fundamental physical constants, the concept of relative uncertainty is used. This method of determining the measurement accuracy does not indicate the direction in which the true value of the fundamental physical constant can be found. In addition, it includes an element of subjective judgement [

Under the proposed approach, for each mathematical model of a physical law there is an uncertainty, which initially, before the full-scale experimental studies, or computer simulations, describes its proximity to the examined physical phenomenon or process. This value is called the comparative uncertainty. It depends only on the number of selected quantities and the observation interval of the selected primary quantity. One of the interesting features of the proposed hypothesis is that the minimum achievable comparative uncertainty is not constant and varies depending on the class of phenomena choice. Moreover, theory can predict its value. In particular, this means that when switching from a mechanistic model (LMТ) to CoP_{SI} with a larger number of the base quantities, this uncertainty grows. This change is due to the potential effects of the interaction between the increased number of quantities that can be taken into account or not taken into account by the researcher. That is why, within the framework of the information approach, in contradiction with the concept approved by CODATA, it is not recommended to determine and declare only one value of relative uncertainty when measuring the Boltzmann constant by different methods.

In addition to the comments made in Section 3 regarding the analysis of the measurement results of the Boltzmann constant based on four different methods using IACU and IARU (summarized in

The greatest success in achieving high accuracy in measuring k was achieved using DCGT, given the significant difference in the magnitude of the comparative uncertainties between CoP_{SI} ≡ LMТΘF (AGT − 0.1331) and CoP_{SI} ≡ LMТΘI (DCGT − 0.2220). However, experimenters involved in DCGT will have to carefully check all sources of error. This is due to the requirement of the information method, according to which the experimental relative uncertainty is always greater than the relative uncertainty, theoretically calculated.

At the moment, the DBT method seems to be very limited (in terms of its physical acceptability for measuring k) in the possibility of achieving higher accuracy. This is explained by the fact that the values of relative uncertainty, calculated according to CoP_{SI} ≡ LMТΘF and achieved in the experiment, are very close (2.1 × 10^{−5} and 2.4 × 10^{−5}).

Variable | AGT | DCGT | JNT | DBT |
---|---|---|---|---|

CoP | LMТθF | LMТθI | LMТθI | LMТθF |

Comparative uncertainty according to CoP_{SI} | 0.1331 | 0.2220 | 0.2220 | 0.1331 |

S_{k} = k_{max} − k_{min}, m^{2} kg/(s^{2} K) | 2.4 × 10^{−}^{29} | 2.7 × 10^{−}^{29} | 9.2 × 10^{−}^{29} | 2.2 × 10^{−}^{27} |

Relative uncertainty according to CoP_{SI} | 2.3 × 10^{−}^{7} | 4.3 × 10^{−}^{7} | 1.4 × 10^{−}^{6} | 2.1 × 10^{−}^{5} |

Achieved experimental lowest relative uncertainty | 6.0 × 10^{−}^{7} | 3.7 × 10^{−}^{7} | 2.7 × 10^{−}^{6} | 2.4 × 10^{−}^{5} |

The data on the JNT method, when compared with the DCGT method, make it possible to assert the possibility of achieving higher measurement accuracy k, given the large gap between the relative uncertainty calculated according to CoP_{SI} ≡ LMТθI (1.4 × 10^{−6}) and experimentally achieved (2.7 × 10^{−6}).

It would seem that the significant difference between the theoretical value of the relative uncertainty for AGT (2.3 × 10^{−7}) and the achieved (6.0 × 10^{−7}) allows hope for its constantly decreasing value when using this method. However, given the fact that the interval of possible placement of k for the AGT method (2.4 × 10^{−}^{29} m^{2}・kg/(s^{2}・K)) is the smallest compared with other methods, it is difficult to expect any achievements in increasing its accuracy.

In addition to analysing the relative uncertainty, the introduced approach may allow a new methodology that will help further monitor the accuracy of the Boltzmann constant measurement. The use of the μ_{SI}-hypothesis only limits the scope of the theory of measurements for uncertainties that are much larger than the model uncertainty due to its finiteness.

The μ_{SI}-hypothesis might be applicable to experimental verification. In general, it is available when the researcher has all the information about the uncertainty interval of the main quantity.

Because the proposed method is not associated with a specific structure of the model, which may change, it is more common, easy and leads to the solution of specific problems, without requiring detailed information about the set of quantities. However, it does not disclose the internal mechanism of phenomena.

Equation (1) clearly indicates that it is impossible to develop an experimental device that would allow achieving the exact value of the chosen comparative uncertainty for a given measurement result. The μ_{SI}-hypothesis, given in equation (1), makes the lower limit of the entropy change of the selected model inaccessible from theoretical considerations. This trend is reflected in the gap between the value of the calculated experimental comparative uncertainty and its theoretical lower limit, the value of which depends on the selected class of phenomena.

The information-oriented approach, in particular IARU, allows calculation of the relative uncertainty, which is in good agreement with the CODATA recommendations. The principal difference between this method and the existing statistical and expert CODATA methodology is the fact that the information method is theoretically justified. Thus, the presented method can serve as a practical tool for ascertaining the preferences, advantages and disadvantages of various methods of measuring the Boltzmann constant.

The author is grateful to engineer B. A. Alexandrov for his advice, fruitful discussions and who took the time to comment on previous drafts of this article.

The author declares no conflicts of interest regarding the publication of this paper.

Menin, B. (2019) The Boltzmann Constant: Evaluation of Measurement Relative Uncertainty Using the Information Approach. Journal of Applied Mathematics and Physics, 7, 486-504. https://doi.org/10.4236/jamp.2019.73035