Resistivity Log

(PETE 663 — Formation Evaluation Evaluation and the Analysis Analysis of Reservoir Reservoir Performance (Fall 2003))

Module for :

Resistivity Theory  (adapted/modified from lectures in PETE 321 (Jensen/Ayers))

J. L. Jensen W.B. Ayers T.A. Blasingame Department of Petroleum Engineering Texas A&M University College Station, TX 77843-3116

Open Openho hole le Well Well Log Log Eva Evalu luat atio ion n Most abundant data for formation evaluation and determination of fluid saturations Well Log SP

Resistivity

Idealized Well Log Set

R=4 = 0.30 R = 0.4

R=8

= 0.07

Shale

Sand

R = 0.3

= 0.35

Four Components of Sandstone (Schematic Diagram) Geologist’s Classification

1.Framework 2.Matrix 3.Cement 4.Pores

Engineering "matrix"

Note different use of "matrix" by geologists and engineers

PORE CEMENT

FRAMEWORK (QUARTZ)

MATRIX

FRAMEWORK (FELDSPAR)

0.25 mm

Fluid Saturations Grain and matrix

Water Gas

Oil



Initially, water fills pores and wets the rock surface



Hydrocarbons migrate into the reservoir rock, displacing some water 



Hydrocarbon distribution determined by gravity and capillary forces, and by wettability Modified from NExT, 1999

Resi Resist stiv ivit ity y of Rock Rocks s Contai Containin ning g Fluid Fluid

Resi Resist stiv ivit ity y – Defi Defini niti tion on of of the the Ohm Ohm-M -Me eter  ter 

Resistivity Resistivity  The voltage required to cause one amp to pass through a cube having a face area of  one square meter   Units are ohm-m 2 /m; usually ohm-m ( .m)

Resistivit y

1 Conductivi ty

Resi Resist stiv ivit ity y Meas Measur urem emen entt



Resistivity V   R(ohm − meters)

=

 I 

2

(ohms) A( m )  L( m)

Resi Resist stiv ivit ity y of Eart Earth h Mat Mater eria ials ls Resistivity

1 Conductivity

(1) Rock (2) Gas     y     g      t       i     n       i     v     s      i     a      t     s     e      i     r     s     c     e     n      R       I

(3) Oil (4) Fresh Water  (5) Salt Water 

 C   o n  d   u  c  t    i     v i      t      y

I     n  c r    e  a  s i     n   g

Factors Affecting Resistivity 

Resistivity of water 



Porosity of the formation,



Pore Pore geo geome metr try y - tort tortuo uosi sity ty



Lithology of the formation



Degree of cementation, and



Type and amount of clay in the rock

From J. Jensen, PETE 321 Lecture Notes

Electricity And Earth Materials



Electrical conduction is by ions in water 



Na+ and Cl- are very common



Othe Otherr mon monov oval alen entt ions ions:: K+ and OH-



Common bivalent ions: Ca++, Mg++

Resisti Resistivity vity Multipli Multipliers ers for Various Various Material Materials s 

Water resistivity controlled by: 

Ion concentrations.



Type of ions.



Temperature.



Chart GEN-4 to convert to NaCl equivalent.



Chart GEN-5 for  temperature/resist for NaCl.

From Schlumberger 

Resistivity of NaCl Solutions  ____  Chart GEN-5H or  GEN-9S

From Schlumberger 

Chart GEN-8 TDS = 20,850 ppm

0.81 0.45 Ca = 460 ppm S04 = 1,400 Na + Cl = 19,000 TDS = 20,860

(460)(0.81)+(1,400)(0.45)+(1)(19,000) = 20,000 ppm

T = 75 deg. F

75 deg. F

Chart GEN-9

Arp's Formula 

For constant solution  – R1(T1 + 7) = R2(T2 + 7) (T in deg F)  – R1(T1 + 21.5) = R2(T2 + 21.5) (T in deg C)



Example  – Rm = 0.32 0.32 ohm-m ohm-m @ surface surface (25 (25 deg C/77 deg F)  – What What is Rm Rm at 145 145 deg deg C (293 (293 deg F)? F)?  – R2 = R1(T1 + 21.5)/(T2 + 21.5)  – R2 = 0.32(25+21.5)/(145+21.5) = 0.089 ohm-m  – Check this on the chart!

Arch Archie ie's 's Firs Firstt Equat Equatio ion n (for Por Poros osit ity) y) 

Relates rock resistivity to Rw R o = F R w  R o = Resi Resist stiv ivit ity y of a roc rock k tha thatt is is 100 100% % saturated with formation water, -m R w  = Resi Resist stiv ivit ity y of of for forma mati tion on water ater,, -m F  = Formation factor 







As the salt water content increases, the formation resistivity will decrease. A rock containing oil or gas will have a higher  resistivity than the same rock completely saturated with salt water. As the shale content increases, the rock matrix will become more conductive.

Rock containing pores saturated with water water and hydrocarb hydrocarbons ons Non-shaly rock, 100% saturated with water having resistivity, R w 

R t 

Cube of water  having resistivity, R w 

φ= 20% Sw = 20% SHC =80%

R o φ= 20% Sw = 100%

R e s  si i   s  st  t  i i  v    i i   t  v t y   

R w  φ= 100% Sw = 100%

    y     g      t       i     n       i     v     s      i     a      t     s     e      i     r     s     c     e     n      R       I

(1) Rock (2) Gas (3) Oil (4) Fresh Water  (5) Salt Water 

 C   o n  d   u  c  t    i     v i      t      y

I     n  c r    e  a  s i     n   g

 F  =  Ro

 Rw

=

a

φ m

Formation Factor  The The form format atio ion n fact factor or (F ) depends on: 

Porosity of the formation.



Pore geometry.



Lithology of the formation.



Degree of cementation.



Type and amount of clay in the rock.

Formation Factor Correlation with Porosity 

For a clean clean formation formation (no shale), shale), the the formati formation on factor can usually be empirically correlated with porosity.

 F 



=

a

m

φ 

a

= constant

1.0 (most formations).

m

= cementation fa factor  2 (most formations).

Common values  – F = F = 0.8/  – F = F = 0.8/

2

(Tixier) or 0.62/ 2 for carbonates.

2.15

(Humble) for sandstones.

Archie Relation for Formation Factor 

Formation Factor  Ideal Considerations

Formation Factor  Experiments with Unconsolidated and Artificially Consolidated Materials

Formation Factor  Generalized Correlation (Schlumberger)

Formation Factor  Type Curve Solution (Blasingame/Unpublished) (Blasingame/Unpublished)

Formation Factor  Effect of Clay/Shale 

The formation factor (F  (F ) is constant for a clean sand; F decreases F decreases for shaly sand as value of R  of R w  increases.

How Archie's Formation Factor Equation Works 

Archie's equation is based on the following ing rela relati tion onsh ship ips s 1000 Rock type 1 100       R

      F

10

Rock type 2

1 .01

.1

1.0

Saturation 

Amount of water per unit volume =



Amount of hydrocarbon per unit volume =

(1-Sw) Sw

S w 

Hydrocarbon

Water  Matrix

(1 - S w )

Archie Archie's 's Second Second Equati Equation on (For Satur Saturati ation) on) 

Relates S w  to R t .



If R  If R t  = R o, then the formation is 100 percent saturated with formation water. However, if R  if R t  > R o, then the formation contains oil or gas.



General formula: n S w

 

=

 Ro  Rt 

=  F 

 Rw  Rt 

=

a  Rw m  R φ  t 

For clean sands, n = 2 is common. Like a and m, n is measured in the lab.

Archie Relation for S  for S w 

Visualization of R  of R  /R   / t  R o versus S w 

Hydr Hydroc ocar arbon bon Resi Resist stiv ivit ity y Inde Index x (I  (I =R  /R   / t  R o) Effects of Clay and Pyrite

Hydr Hydroc ocar arbo bon n Res Resis istiv tivity ity Inde Index x (I  (I =R  /R   / t  R o) Effects of Wettability

Hydr Hydroc ocar arbon bon Resi Resist stiv ivit ity y Inde Index x (I  (I =R  /R   / t  R o)

Type Curve Curve Solution Solution - No Shale Case Case (Blasingam (Blasingame/Unp e/Unpublish ublished) ed)

Hydr Hydroc ocar arbon bon Resi Resist stiv ivit ity y Inde Index x (I  (I =R  /R   / t  R o) Type Type Curve Curve Solutio Solution n - Shale, Shale, n=1.2 (Blasingame/Unpublished)

Hydr Hydroc ocar arbon bon Resi Resist stiv ivit ity y Inde Index x (I  (I =R  /R   / t  R o) Type Type Curve Curve Solutio Solution n - Shale, Shale, n=2.0 (Blasingame/Unpublished)

Drilling Disturbs Formation Drilling and rock crushing



Damage Zone



Mud systems and invasion



Oil-based Mud



— Small conductivity mud

Mudcake Damaged zone

— Shallow invasion — Thin cake

Water-based Mud



— Moderate to very conductive mud — Shallow to deep invasion — Thin to thick cake

Invading filtrate

Effects of Drilling Mud and Mud Filtrate Invasion

Mud Filtrate Invasion Uninvaded Zone (Rt) Invaded Zone (Rxo)

Wellbore Mud (Rm)

Uninvaded Zone (Rt)

 o  n   i   i o   t   i   n s  a   T  r   n e  o   Z

Mud Cake (Rmc)

Resistivity of zone Resistivity of the water in the zone Water saturation in the zone Mud

Symbols used in Log Interpretation

Rm

Adjacent bed Rs

hmc Rmc dh

(Bed thickness)

Mudcake

h

Flushed zone Zone of  transition or  annulus Rxd

Uninvaded zone R1 R w Sw

R m1 Sxo

Rs

di d j

Adjacent bed

(Invasion diameters) ∆r   j

dh Hole diameter  From NExT, 1999, after Schlumberger 

Common Terminology Borehole R m: Borehole mud resistivity R mc : Mud Mud cak cake e res resis isti tivi vity ty Invaded zone R mf : Mud Mud filt filtra rate te resi resist stiv ivit ity y R  xo: Inva Invade ded d zon zone e res resiistiv stivit ity y S  xo: Inva Invade ded d zon zone e wat water er sat satur urat atio ion n Unin Uninv vaded aded zone zone R w :

Inte Inters rsti titi tial al water ater resi resis stivi tivity ty R t : Uninvaded zone resistivity S w : Uninvaded zone water sa saturation

Summ Summar ary y — Res Resisti istivi vity ty Resistivity is a very important property  Resist Resistivit ivity y inver inversel sely y propor proportio tional nal to ion volumes present in water   Water resistivity depends on: 

Concentration  Temperature  Ion species 

Archie's Archie's First Law relates relates rock rock resistivity resistivity to R w  Archie's e's Second Second Law relate relates s S w  to R t   Archi 

(PETE 663 — Formation Evaluation Evaluation and the Analysis Analysis of Reservoir Reservoir Performance (Fall 2003))

Module for :

Resistivity Theory  (adapted/modified from lectures in PETE 321 (Jensen/Ayers))

End of Presentation J. L. Jensen W.B. Ayers T.A. Blasingame Department of Petroleum Engineering Texas A&M University College Station, TX 77843-3116