Abstract

In connection with conversion from energy class K_R (K_R = log₁₀E _R, where E_R — seismic energy, J) to the universal magnitude estimation of the Tien Shan crustal earthquakes the development of the self-coordinated correlation of the magnitudes (m_b , M_L, Ms ) and K_R with the seismic moment M₀ as the base scale became necessary. To this purpose, the first attempt to develop functional correlations in the magnitude—seismic moment system subject to the previous studies has been done. It is assumed that in the expression M (m_b , M_L , Ms) = K_i + z_i log₁₀M₀ , the coefficients k_i  and z_i  are controlled by the parameters of ratio (where ; f₀ —corner frequency, Brune, 1970, 1971; M₀, N×m). According to the new theoretical predictions common functional correlation of the advanced magnitudes M_m (m_bm = m_b , M_Lm = M_L , M_Sm = M_S ) from log₁₀M_0,  log₁₀t₀  and the elastic properties (C_i) can be presented as , where , and , for the averaged elastic properties of the Earth’s crust for thembmthe coefficients C_i= –11.30 and d_i = 1.0, for M_Lm: C_i = –14.12, di = 7/6; for M_Sm : C_i = –16.95 and d_i = 4/3. For theTien Shan earthquakes (1960-2012 years) it was obtained that , and on the basis of the above expressions we received that M_Sm = 1.59m_bm – 3.06. According to the instrumental data the correlation M_s = 1.57m_b – 3.05 was determined. Some other examples of comparison of the calculated and observed magnitude - seismic moment ratios for earthquakes of California, the Kuril Islands, Japan, Sumatra and South America are presented.

Keywords

Magnitude; Seismic Moment; Energy Class; Earthquakes; Frequency

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1. Introduction

In world practice, seismological research in assessing the scale of earthquakes magnitude scale of Gutenberg and Richter [1-3] is fundamental. In the countries of the former Soviet Union has been used scale independent energy class K_R, defined as the logarithm of the seismic energy E_R, highlighted by an earthquake, measured in joules (K_R = log₁₀E_R, [4-6]).

For crustal earthquakes Tien Shan when considering the transition to magnitude scale was necessary to develop a self-consistent system of quantitative relationships that justify numerous empirical relationships bodywave magnitude m_b, local magnitude on surface waves M_L, surface wave magnitude for M_S and K_R from seismic moment M₀ (N∙m), as the reference scale. In connection with the above purpose is to study the quantitative relationships m_b, M_L, M_S and energy of seismic radiation E_S c M₀ based on the following findings:

1) proportional magnitudes and the maximum amplitude of seismic vibrations [1-3];

2) the statistical dependencies of the average magnitude of displacement along the fault u [7-12] and u functional relationship with the seismic moment, the shear modulus μ and the gap area S [13-14];

3) functional relationship corner period with M₀, the source radius r₀, speed S—wave v_S and static stress drop Δσ [15,16], as well as the similarity of the angular frequency f₀ with a fundamental frequency of the acoustic Debye [17] f_D, depending on the amount of source and the elastic properties of the geophysical medium [18].

Our further quantitative construction is based on the following empirical relationship Gutenberg and Richter [3,12]:

(1)

(2)

(3)

where E_GR—seismic energy according to Getenberg and Richter, J; t₀—fluctuations with a maximum duration of vibration speed А/Т in the near field (А—amplitude, Т— period), s.

Use the following generalization of Soviet seismologists, which were introduced scale energy class K_R [5], the magnitude of surface waves M_LH (IC device) and body waves m_PV on device SCM [4,9]:

(4)

(5)

(6)

(7)

where E_R—seismic energy according to [5], in J; K_R = log₁₀E_R; t_m—increase the maximum duration of the seismic intensity in the near field, in sec.

The basis of the theoretical constructs are the following functional relations [10,13,15,16,19]:

(8)

(9)

(10)

(11)

where r₀—radius of the source, in м; ∆σ—static seismic stress drop, in Pа; t_b—corner period, s; M_W—moment magnitude; (E_SK, in J; M₀, in N∙m; u in m; v_S in m/s); for the constructions made t₀ = t_b = t_m.

Many generalizations proved that for a wide range of changes log₁₀M₀ or M_W empirical correlations magnitude m_b, M_L and M_S from M₀ are non-linear, as in Equation (8), as a function of value of n varies from 3 to 6, and is increase Δσ [7,12,20-24].

However, for individual intervals M₀ or M_W communication between magnitudes relationships and dependencies of the magnitude log₁₀M₀ can be represented as linear relationships.

2. Justification Relations Magnitude—Seismic Moment

Based on the original definition of magnitude on Richter [25], under which the numerical value of the earthquake magnitude is proportional to the logarithm of the maximum oscillation decimal в_m, expressed in microns (10⁻⁶м), it is assumed that an upgraded body-wave magnitude m_bm (equivalent m_b, m_PV ) is (considering doubling в_m on the ground at the focus):

(12)

If in (8) on the basis Equations (9) and (10) and Equation (12) value m_bm equal (M₀, N∙m; t_в, s; µ, Pa; v_s, m/s):

(13)

where, value С₁ determines the springiness of the geophysical environment at m_bm.

Based on generalizations Christensen [26,27] for the crust taken: average density

ρ = 2830 kg/m³, v_S = 3600 m/s and in what follows, these quantities ρ, v_s and μ taken as the standard.

When these elastic parameters of the geophysical medium expression Equation (13) is transformed to the following form:

(14)

Seismic energy radiation E_SK by Kanamori [19], based on Equations (8) and (9) and Equation (13) is:

(15)

where.

Taken for the elastic parameters and subject [19]. obtain: Δσ = 3.67 MPa and 36.7 bar and the expression Equation (8) can be rewritten in a simple form log₁₀t₀ = 1/3log₁₀M₀ – 5.43, then Equation (15) simplifies to:

(16)

On the basis of Equations (13)-(16), reflecting the functional relationship of E_SK from M₀, t₀, m_bm and μ at E_GR = E_SK introduced upgraded the magnitude of surface waves M_Sm (equivalent of M_S, M_W), while maintaining that the formula Equation (1) Gutenberg and Richter [2,3], with Equation (9), Equations (15) and (16) will be:

(17)

where.

Taken for ρ and v_S C_S value in Equation (17) is equal to C_S = –16.95, and for the special case of Δσ = 3.67 MPa = const and E_SK/M₀ = 5 × 10^–5 equality: M_Sm = M_W.

We also introduce a modernized local magnitude on surface waves M_Lm—equivalent M_L [18,28], functionally interconnected with log₁₀M₀, logt₀, K_SK, m_bm and M_Sm:

(18)

where C_L = 0.5 (C₁ + C_S): for standard values ρ and v_S value C_L is equal: C_L = –14.12.

Accepted values for ρ and v_S by Equation (8) and Equation (9) the following relationship:

(19)

With the standard values ρ, v_S and Δσ = 3.67 MPa, based on Equation (14) and Equation (17) we obtain the following theoretical relation:

(20)

which is within the accuracy of the definitions of the same magnitude satisfactory empirical relation refined body wave magnitude of M_W for large earthquakes [19,29] (m_b ≥ 6):

(21)

which were used to calculate the true maximum oscillation amplitude A_g, taken from seismograms;.

Here it should be emphasized that at a constant value of Δσ Equation (12) and Equation (14) the value of the maximum amplitude в_m is proportional to or , that closely coincides with on [19,29].

In the sequel will be shown.

Equation (20) agrees satisfactorily with other empirical relationship [9]

(m_PV = m_b + 0.18):

(22)

The above quantitative ratios indicate that between modernized magnitudes M_m (m_bm, M_Lm, M_Sm) and log₁₀M₀ may exist linear functional relationship of the form:

(23)

in which the coefficients k_i and z_i at the control parameter a_t and в_t in the ratio:

(24)

where ∆σ = const = 3.67 МPa в_t = 1/3 = const and a_t = –5.43, but for other cases в_t  is not a constant.

In view of Equations (23) and (24) correlations Equations (14), (17) and Equation (18) for m_bm, M_Sm and M_Lm (standard values ρ and v_S) can be written as follows:

(25)

(26)

(27)

which provide a self-consistent system of semi empirical inter magnitude dependencies. For example, the dependence of m_вm from M_Sm based on Equations (25) and (26) can be expressed as:

(28)

which is в_t = 0.33 and a_t = −5.43 ransformed into simple formula Equation (20).

3. Discussion of Empirical and Theoretical Relations Magnitude—Seismic Moment

Local magnitude—seismic moment. Since the value of the local magnitude is directly related to the maximum oscillation amplitude of the surface waves and the first inter magnitude connections [2,3] have been developed for California earthquakes, relations M_L –consider according to Thatcher and Hanks [30] in this region (2 ≤ M_L ≤ 6.8).

For this region, the authors have taken ρ = 2700 kg/m³ and v_S = 3200 m/s, and by (13) and (17) a constant values will be: С₁= −11.09, С_S = −16.5, С_L = −13.72. With known ρ, v_s, Δσ/2μ = 5 × 10⁻⁵ between log₁₀t₀ and log₁₀M₀ would expect the following relationship:, but the instrumental data obtained (Figure 1, N—the number of data, r—correlation coefficient):

(29)

i.e. in accordance with (19) with increasing values of M₀log₁₀Δσ increases:

. Therefore, for the considered data characteristic dependence, said Nuttli [12] for mid-plate earthquakes.

If true theoretical Equations (13), (17) and (18), then

Equation (29) and the relationship between M_Lm and log₁₀t₀ is given by:

(30)

which is in good agreement with the expression (3) Gutenberg and Richter [2] and Equation (5) Soviet seismologists [31] which allows to consider t₀ = t_в = t_m.

In Figure 2 shows the correlation log₁₀t₀ and M_L according to Thatcher [30], which also shows the relationship Equation (3) and Equation (30). The presented data show that the semi-empirical formula Equation (30) is in good agreement with generalizations instrumental data (Figure 2). It should also be noted that the M_L = M_Lm based on Equation (3) Gutenberg and Richter [2], and Equation (18) can be obtained

(31)

which is in satisfactory agreement with the expression (29).

In Figure 3 in the range of 0.5 ≤ M_L ≤ 6.8 shows the correlation ratio M_Lm of M_L for Southern California earthquakes [30], South-West Germany [32] and Central Japan [33]. In calculations M_Lm by Equation (18) for the earthquakes in these regions were considered elastic parameters of the geophysical medium according to these authors. The statistical data confirm the validity of our assumptions on the possible equality M_L and M_Lm (Figure 3).

From numerous publications on nonlinear relations log₁₀M₀ – M_L acceptability of new assumptions considered on the basis of Hasegawa [34] for earthquakes in Eastern Canada. In the range 0 < M_L ≤ 6.3 are two of the interval 0 < M_L ≤ 3.9 and 3.9 ≤ M_L ≤ 6.3, which have different dependencies on log₁₀t₀ of M_L and log₁₀M₀ from M_L [34].

For the first group of small earthquakes characterized by the following relationship (10⁵ < ∆σ < 10⁶ Pа):, but for another group (10⁶ ≤ ∆σ < 5 × 10⁶ Pа):.

On the basis of these empirical formulas for Equation (18) and Equation (24) with C_L = −14.21 (ρ = 2800 kg/m³ and v_s = 3800 m/s) Figures 4 and 5 shows the calculated dependences of log₁₀t₀ from M_Lm and log₁₀M₀ from M_Lm, which in satisfactory agreement with the relations log₁₀t₀ − M_L and log₁₀M₀ − M_L (Figures 4 and 5) by Hasegawa [34].

Finally, for the Southern California Earthquake Equation (18) and Equation (29) we can obtain the following relationship:, which coincides with the ratio of [30]:

(32)

According to Equations (23) and (24) and Equation (27) if в_t = 0.25 we get, which indicates the acceptability of the proposed relations.

From Equation (32) it follows that b_t = 0.25 in Equation (24) the values of M_L and M_Lm magnitude M_W corresponds to Equation (11). Probably, the presence of the form Equation (29) between log₁₀t₀ and log₁₀M₀ explains equality M_L = M_W for earthquakes with M_W ≤ 7.0 NorthWest Europe [35], New Zealand [36], western Canada [37] and about Taiwan [38].

3.1. Ratio m_b − log₁₀M₀: Design and Data Tools

As in the case of search based M_L − log₁₀M₀, for bodywave magnitude m_b consider empirical relationships According to Zapolsky [31], Gutenberg [1], specifically examining the relationship between the energy of focal radiation and earthquake magnitude according to

the observations in the epicentral area, showed that the duration t₀, determine the energy of the oscillations with the maximum intensity depends strongly on the magnitude and 2.5-fold increases with increasing magnitude of m_b on unit [31].

(33)

A little-known empirical formula Equation (32) Gutenberg [1] is a key for further generalizations of our constructions on relations m_b − log₁₀M_0, and m_b − M_S.  

On the basis of (13) and (29) with С₁ = −11.09, we can get:

(34)

Substitution in Equation (31) into (13) leads to the following formula:

(35)

which is in good agreement with (33) provided m_b = m_bm.

Graphic expressions Equations (33)-(35) are shown in Figure 6, from which it can be assumed about the close convergence of these relations and the possible equality m_b = m_bm (Figure 6). At equality m_b = m_bm—based Equations (13) and (33) for the standard ρ and v_S can obtain the expression:

(36)

which is in good agreement with Equations (29) and (31), which may indicate the consistency of our constructions relating m_b, m_bm, M_L, M_Lm and log₁₀t₀ with log₁₀M₀ for earthquakes in California, despite the fact that the conclusions are based on statistical formulas in which the correlation coefficients are not equal to unity (r = 0.75 - 0.90)

If we use the Equation (36), on the basis of Equation (24) with в_t = 0.22 and Equations (25) and (26) for the

standard values ρ and v_S, M_Sm dependence on m_bm can be expressed as:

(37)

which almost corresponds to the classical formula Equation (2) Gutenberg and Richter (1956в) and for which the equality M_Sm = m_bm complied with M_sm = 5.40, which coincides closely with generalizations Chen [7], Gusev [9], Nuttli [12] and Utsu [24].

In Figure 7 shows the correlation of log₁₀t₀ from log₁₀M₀ for earthquakes in the world (1981-1991) by the Catalogue Choy [39], for which the value of t₀ was taken from the Global CMT Catalogue. The ratio of log₁₀t₀ from log₁₀M₀ for these data is given by (Figure 7):

(38)

for which the range 17 ≤ log₁₀M₀ ≤ 21 value of log₁₀Δσ by Equation (19) increases from 6.60 to 7.10.

Substituting (38) in (13) leads to (С₁ = –11.30):

(39)

which agrees closely with the empirical formula:

(40)

shown on Figure 8.

Equation (39) is in good agreement with the dependence on m_b from log₁₀M₀ for Sumatra island earthquake (φ = –10˚ + 10˚, λ = +90˚ + 100˚) for 1993-2012 (Figure 9).

Table 1 shows a comparison of the magnitude obtained by the true maximum amplitude [19,29,40] and the calculated value m_bm (Table 1) for a number of large earthquakes in 1960-1984. The presented data suggest that for most of the earthquakes characterized by the following inequality:.

When log₁₀Δσ ≥ 7.1 value of is close to the m_bm same as for Great Chilean earthquake and m_bm = 7.71, for Tangshan (1976) and m_bm = 6.92, Yanyuan (1976)., m_bm = 6.18, and if 6.36 ≤ log₁₀∆σ < 7.0 value of more then m_bm (Table 1).

Table 2 presents a comparison of calculated m_bm and (21) for 80 major earthquakes of the world for 2000- 2012 for calculations m_bm, and M_Sm used data from Global CMT Catalogue (Table 2). When comparing log₁₀Δσ from Table 1 to Table 2 shows that with increasing log₁₀M₀ from 19.15 to 22.72 for the 2000-2012 earthquakes log₁₀Δσ value ranges from 6.75 - 7.58 with an average of 7.16, that is, much higher than for earthquakes 1960-1984 (Tables 1 and 2) and higher than the standard logΔσ = 6.56.

For such high values Δσ values m_bm closely coincide with the design, and for values M_Sm characterized by inequality: M_Sm > M_W (Table 2) confirmed that conclusion is the relation m_bm −—for earthquakes in Japan and the Kuril Islands (φ = 30˚ + 40˚, λ = 140˚ + 150˚) for the 1993-2012 shown in Figure 10.

Thus for large earthquakes 1960-1984 and 1993-2012 at logΔσ > 7.1 m_bm values coincide closely with the magnitude calculated from the true maximum amplitude (A_g) of seismic vibrations, the magnitude of which is proportional to the seismic moment: to Houston [29] and Kanamori [19]. Consequently, the m_bm

value is proportional to the log₁₀А_g.

The ratio of M_S – log₁₀M₀. In Mamyrov’s papers [18], [28] have shown that in the range of 16 ≤ log₁₀M₀ < 21.0 if log₁₀Δσ ≤ 7.0 at the rated M_Sm closely coincides with M_S and M_W, and for high Δσ ≥ 10⁷ Pa following inequality M_Sm > M_S, as shown in Table 2.

In Figure 11 shows the correlation of M_S from log₁₀M₀ for earthquakes of the world for 1981-1991 according to the Catalog Chou et al. [39]:

(41)

which is in satisfactory agreement with the dependence (Figure 11, dashed line), derived from Equations (38) and (26). These relations with M_S = M_Sm with log₁₀M₀ are in good agreement with the generalization of Perez [41] for crustal earthquakes of the world for the years 1950-1997: .

In Figure 12 shows the correlation M_S with log₁₀M₀ (solid line) for the earthquakes in Japan and the Kuril Islands in 1993-2012:

, here, we show the same relationship M_Sm from log₁₀M₀ (Figure 12, dashed line):

, obtained with (N = 521, r = 0.99):

(42)

From the data that the value M_Sm an average of 0.5 more than the M_S, because according to the relation log₁₀t₀ with log₁₀M₀ (from 42) with growth log₁₀M₀ from 16 to 22 on the basis of (19), the value increases from 7.19 logΔσ to 7.43 (Figure 12), and using equation (38) in the same size ranges of log₁₀M₀  the value of log₁₀∆σ increases from 6.5 to 7.10. It is likely that for most crustal earthquakes before 1993 was characterized by the above limits to growth log₁₀∆σ < 7.10.

Ratio m_b – M_S и m_bm – M_Sm. In Figure 13 shows the correlation ratio m_b – M_S for crustal earthquakes of the Kuril Islands and Japan for 1993-2011:

(43)

which is in good agreement with the expression:

(44)

derived from (42) and (28) for в_t = 0.32 и a_t = −5,43 (Figure 13).

Figure 14 shows the correlation ratio m_b – M_S  for crustal earthquakes in South America for the years 1993- 2012, (φ = −40˚ − 0˚, λ = −85˚ − 65˚) by Global CMT Catalogue:

(45)

for this region was obtained (N = 576, r = 0.99):

(46)

the substitution of which in (26), в_t = 0.32 and a_t = −5.48 leads to the formula

(47)

Equations (43)-(46) are in good agreement with Equations (21) and (22).

Figure 15 shows the correlation log₁₀t₀ of log₁₀M₀ for earthquakes of the Tien Shan (φ = 38.5˚ − 45˚, λ = 63˚ − 96˚) for 1960-2012 in interval 13.0 ≤ log₁₀M₀ ≤ 21.5 (N = 684, r = 0.85):

(48)

which closely coincides with Equations (29), (31) and (36) typical for earthquakes in California (Figures 1 and 15).

Therefore, we can expect that the relationship between magnitudes m_b – M_S for earthquakes of the two regions may be similar in this range of seismic moment. Indeed, the data in Figure 16 confirmed these assumptions and empirical relationship of M_S from m_b for Tien Shan’s earthquakes is expressed by the following relation (N = 1183, r = 0.95, Figure 16):

(49)

Calculated dependence of M_Sm from m_bm based on Equations (25), (26) and (47) for the elastic parameters of the standard as follows:

(50)

which is in good agreement with Equations (2), (37) and (49).

Therefore, we have adopted model of the relationship of linear relations between M (m_b, M_L, M_S) and log₁₀t₀ with log₁₀M₀ explains many existing empirical formulas. For a wide range 6 ≤ log₁₀M₀ ≤ 23 changing log₁₀t₀, to a first approximation, can be described by a nonlinear dependence of (A₀ = log₁₀M₀):

(51)

in which the first two terms describes the linear growth log₁₀t₀ in the range 6 ≤ A₀ ≤ 15. On the basis of Equations (25)-(27) and (51) in Figure 17 shows estimates nonlinear dependence m_bm, M_Lm and M_Sm from M_W to (11) for crustal earthquakes. From Figure 17 shows that in the

interval 4 ≤ M_W ≤ 6,5 numerical values of magnitudes m_bm » m_b, M_Lm » M_L, M_Sm » M_S and M_W within the accuracy of these parameters are close. In accordance with Equations (19) and (51) in the interval 6.0 < A ≤ 23.0 log₁₀∆σ value increases from 1.75 to 7.53, and the most intense increase in this parameter is in the range 6.0 ≤ A₀ ≤ 15.0.

4. Conclusions

1) A broad range of local Richter magnitude M_L, m_b, and M_S crustal earthquakes in different regions shows a possible functional relationship with the seismic moment magnitude, corner frequency, voltage and depressurized seismic elastic parameters of the geophysical environment. These links justify numerous empirical relationships with magnitudes of seismic moment.

2) It is assumed that an upgraded body-wave magnitude m_bm for large earthquakes is proportional to the logarithm of the average displacement along the fault log₁₀u, , the true magnitude and the maximum amplitude of seismic vibrations A_g; magnitude M_Sm is proportional to the logarithm of the square average displacement along the fault (2log₁₀u) and local magnitude proportional 1.5log₁₀u.

3) Control parameters of the quantitative relations with seismic moment magnitudes are coefficients depending on the change in corner period of seismic stress drop or discharged from the seismic moment, which provide a self-consistent system of equations between the main source parameters of crustal earthquakes.

Conflicts of Interest

The authors declare no conflicts of interest.

References