BE1029805A1 - MULTI-INDICATOR BASED METHOD TO EVALUATE A PROCESSING POTENTIAL OF TUNGSTEN AND TIN IN GRANITE - Google Patents

Abstract

From the present invention, a multi-indicator based method for assessing a prospecting potential of tungsten and tin in granite is known. In the method, through an analysis of the whole rock and a microanalysis of minerals of the collected granite, three indicators are calculated, namely an oxygen volatility of magma, a degree of differentiation of magma and an intensity of hydrothermal transformation of granite of granite, with these three indicators the metallogenic potential of tungsten and tin in granite is efficiently evaluated, solving the problem of difficult assessment of a rock body forming tungsten-tin ore, and a new method and workflow for rapidly evaluating the metallogenic potential of tungsten and tin be created in granite in new prospects. The probability of finding a tungsten-tin deposit by this method is greater than 70%, which has important practical value.

Description

MULTI-INDICATOR BASED PROCEDURE FOR EVALUATION OF A

PROCESSING POTENTIAL OF TUNGSTEN AND TIN IN GRANITE

TECHNICAL AREA

The present invention is in the field of mineral exploration and evaluation and relates more particularly to a multi-indicator based method for evaluating a mineral

prospecting potential of tungsten and tin in granite.

STATE OF THE ART

Tungsten and tin are irreplaceable important metal elements with great utility and high

security of supply risk and are becoming cleaner in key high-tech areas

Widely used in energy, information industry, aerospace and national security.

In the comparison chart published by USGS (United States Geological Survey) for

Benefits and scarcity of key metals between China and the United States include

Tungsten and tin among the more than ten major metals with a foreign dependency of more than 70% in the United States. The innovation of prospecting methods for

Tungsten and tin ore is an urgent and important task and represents the key to changing the shortage of tungsten and tin resources and making breakthroughs in the

to achieve prospecting. The tungsten-tin deposit occurs in a contact zone between the inside and outside of the granite that protrudes at the top of the granite. Once an ore-forming rock body is found, a corresponding ore body can soon be identified. However, China is one of the countries with the most widespread in the world

Granites, of which few granites can form tungsten-tin deposits. Therefore, it is very important to have a simple and effective multi-indicator based method for

To assess prospecting potential of tungsten and tin in granite bodies.

Predecessors used cassiterite, Ar-Ar chronology and other methods to date the ore in the tungsten-tin deposit and determine the formation age of the deposit, after which U-Pb dating is performed on zircon in a rock body in the mining area , where by comparing the spatio-temporal relationship between

Rock body and ore body determines whether it is a metallogenic

rock body acts. However, this method is only applicable to areas where

Deposits are discovered, the ore mineral of the tungsten-tin deposit is cassiterite and the Ar-Ar age can be determined. And it can be used in the assessment of a metallogenic

potential of tungsten and tin in granite are not widely used and thus cannot fully meet the requirements of current prospecting.

Concerning the metallogenic potential of granite and the identification of ore forming ones

rock bodies, Li Huan et al. (2020) the properties, such as U-Pb dating and

Lu-Hf isotope ratios in granite bodies to assess the metallogenic potential of granite. Many deposits, such as W, Sn, Li, Be, U, Th, Fe, Cu, Pb, and Zn deposit, can be related to granites. And granites with different properties form different types of deposits. For example, copper mines are available with

Granites are related, usually associated with high magma

oxygen volatility. Therefore, when assessing whether a granite contains minerals, multiple solutions can be obtained simply by using the U-Pb dating of zircon and the

Lu-Hf isotope ratios are used.

Therefore, it is necessary to find a new and efficient method suitable for assessing a metallogenic potential of tungsten and tin in all granites

shortage of tungsten and tin resources and a breakthrough in the

to achieve prospecting.

CONTENT OF THE PRESENT INVENTION

Faced with the problems of high uncertainty, multiple solutions and low targeted

Searching for ore types in the prior art, the present invention proposes a multi-indicator based method for assessing a prospecting potential of

tungsten and tin in granite using bulk rock geochemistry and mineral microgeochemistry, the process exploiting the metallogenic potential of

Can quickly and accurately detect tungsten and tin in granite, has higher accuracy than the traditional method, and can greatly improve the efficiency of prospecting.

In order to solve the above technical problem, the present invention uses the following technical solution:

A multi-indicator based method for assessing prospecting potential of

Tungsten and tin in granite is provided comprising the following steps: (1) Delineate a metallogenic domain: geological, geophysical and geochemical

Exploratory data will be collected according to a selected research area, with a metallogenic prospect being comprehensively analyzed and with a favorable metallogenic

area is demarcated;

(2) Sampling: samples will be taken from granites with a metallogenic potential in the favorable metallogenic range, with 4 to 5 samples taken from each granite with a metallogenic prospect; (3) Analyzing the samples: on the samples, a main and trace element analysis for the

performed bulk rock to obtain major and trace element data for bulk rock and microanalysis of zircon minerals to obtain

Zircon trace element data performed; a SiO2 content is determined, and under

Using granite whole rock data, a differentiation coefficient of

Fe2O3/FeO, Rb/Sr, K/Rb, Nb/Ta, Zr/Hf and TE1.3 calculated; using the

A concentration of U (ug/g) is determined from zircon trace element data, with parameters representing a europium anomaly of zircon (Eu/Eu*), a light rare earth (LREE), a heavy rare earth (Total REE), a temperature T (°C) at which the granite is formed, and

oxygen volatility (Ig(fO2)) can be calculated; (4) Identifying the metallogenic potential of tungsten and tin in granite: the SiOz content and a Fe2O3 to FeO ratio of the whole rock of granite and a

Relationship between temperature T and zircon oxygen volatility in granite are used to determine redox properties of magma and the degree of

to identify oxygen volatility of granite's magma; then the parameters of

Nb/Ta, Zr/Hf, TE1,3, Rb/Sr, K/Rb of the whole rock of the granite used to form a

to determine the degree of evolution of magma and to identify a degree of differentiation; finally, the U concentration and the Eu/Eu* of zircon, LREE, and Total REE are used to identify a degree of hydrothermal transformation of magma and an intensity of hydrothermal transformation of magma; depending on three indicators, namely the oxygen volatility of magma, the degree of differentiation of magma and the

Intensity of hydrothermal transformation of magma into granite, it can be judged whether granite has metallogenic potential of tungsten and tin.

According to the solution described above, in step (4), identifying the metallogenic potential of tungsten and tin in granite is done as follows:

D Identifying the oxygen volatility: the main and

Whole rock trace element data are processed, where if SiO» is between 66

wt% and 75 wt%, the ratio of Fe2O3 to FeO falls under a curve y = 2.6198 * 10-27 * e@0.8503x (SiO2 is plotted on the abscissa and Fe2O3/FeO on the ordinate ), where, if at 75% by weight < SiO2 < 80% by weight, the ratio of Fe2O3 to FeO is less than 10,

the granite is indicated as having potential to form a tungsten-tin deposit; the zirconium trace element data obtained in step (3) is processed, wherein when both the temperature T is between 600°C and 900°C and the

Oxygen volatility (lg(fO2)) falls under a curve y=0.0364x-35.909 (lg(fOz) is on the

plotted on abscissa and temperature on ordinate), indicating that the granite has a metallogenic potential of tungsten and tin; if the two mentioned

indicators are met, it indicates that the granite has low oxygen volatility and has a potential to form a tungsten-tin deposit; 2) Identifying the degree of differentiation: the main and

Whole rock trace element data will be processed, where if the parameters of the

Whole rocks satisfy the relationships Nb/Ta<7, Zr/Hf<35, TE1.3>1.05, Rb/Sr>2, K/Rb<150 indicates that this granite has a high degree of differentiation and metallogenic potential of tungsten and tin; @ Identifying the degree of hydrothermal transformation of magma: the zircon trace element data obtained in step (3) is processed, where if the zircon in this

Granite satisfies the relationships U>250 ug/g, Eu/Eu*<0.3, LREE>20 ug/g, Total REE>1050, indicating that the granite has undergone a strong hydrothermal transformation process

have experienced magma and exhibits a metallogenic potential of tungsten and tin; @ if the granite satisfies the above three identification conditions D 2) @ at the same time, it means that the granite has the properties of a low

Oxygen volatility, a high degree of differentiation and a high intensity of hydrothermal transformation of magma and thus has a very good metallogenic potential of tungsten and tin, this granite being classified as a tungsten-tin-forming ore

Rock bodies can be assessed (i.e. probability of finding tungsten and tin is >70%), delineating a target area within a certain radius depending on the exposed position of the granite; if a granite body is one of the three

Not meeting identification criteria, it is a non-oreiferous body of rock with a low probability of finding an ore with no target area defined.

Elements or compounds involved in steps (3) and (4) constitute a

represents its mass percent of the corresponding elements or compounds. For example, in step (4), SiO2 represents its mass percent of the major and trace elements for the total rock.

This applies to similar situations unless otherwise noted.

It is preferably provided that when a granite body meets the three identification conditions

D 2) @ at the same time, it has a metallogenic potential of tungsten and tin and is assessed as a tungsten-tin ore forming rock body, delineating a target area within a certain radius depending on the exposed position of the granite; and that if a granite body does not meet any of the three identification conditions, it is a non-oreiferous rock body with a low probability of finding an ore and no target area is delineated.

According to the solution described above, in step (3) the differentiation coefficient of TE1,3 is calculated as: TE1,3= [((2*Cen/(Lan+Prn))*(2*Pru/(Cen+Ndn))* 0.5)*((2*Tbn/Gdu+Dyn))*(2*Dyn/(Tbu+Hon))*0.5] (Irber, 1999). where N is the normalized value of chondrites.

According to the solution described above, it is provided that in step (3) under

Using the zircon trace element data in combination with a comprehensive

Analysis software Geo-fO2 for oxygen volatility and a Geokit software parameters covering the zircon europium anomaly (Eu/Eu*=2*Eun/(SMn+Gdn})), the light rare earth (LREE), the heavy rare earth (Total REE), the temperature T (°C) at which the granite is formed and the oxygen volatility (lg(fOz)) can be calculated.

According to the solution described above, step (3) comprises:

Major and trace element analysis for the whole rock: samples of the granite are pulverized to pass through a 200 mesh sieve, after which the major elements are measured using an X-ray fluorescence spectrometer (XRF) and a potassium dichromate method to determine the content of SiO2, TiO2, Al203, FeO, Fe203, MnO, MgO, CaO, Na20, K20,

P205, after which the trace elements of the samples of the granite by a

ICP-MS analysis are analyzed so that the content of Li, Be, Sc, V, Cr, Co, Ni, Cu, Zn, Ga, Rb, Sr,

Y,Zr,Nb,Sn,Cs,Ba,La,Ce,Pr,Nd,Sm,Eu,Gd,Tb,Dy,Ho,Er,Tm,Yb,Lu,Hf,Ta;

Microanalysis and testing of minerals: part of the samples taken in step (2) are used to select zircon, after which the properties of the corresponding zircon are observed under a microscope and a cathodoluminescence image, indicating the type of

zircon is recorded in detail and in situ micro-area elemental analysis for inductively coupled plasma mass spectrometry is performed by laser ablation to obtain trace element data for each test point.

According to the solution described above, it is envisaged that in step (4), criteria for identifying oxygen volatility, identifying degree of differentiation and identifying degree of hydrothermal transformation of magma are specifically obtained as follows:

Step 1: at least five samples each are taken from an ore-forming rock body and a non-ore-forming rock body;

Step 2: the sample is subjected to major and trace element analysis for whole rock to obtain major and trace element data for whole rock and microanalysis of zircon minerals to obtain zircon trace element data; using granite whole rock data, a

Calculated differentiation coefficient of Fe2O3/FeO, Rb/Sr, K/Rb, Nb/Ta, Zr/Hf and TE1.3; using the zircon trace element data, parameters that a

Zircon europium anomaly (Eu/Eu*), one light rare earth (LREE), one heavy rare

earth (Total REE), a temperature T (°C) at which the granite is formed, and a

include oxygen volatility (lg(fO2)), calculated;

Step 3: the criteria for identifying oxygen volatility, identifying the

degree of differentiation and identifying the degree of hydrothermal conversion of

Magma are determined where:

D Identification of the oxygen volatility: the data obtained in step 2 are processed using the content of SiO2 as the abscissa and the ratio of Fe2O3 to

FeO as the ordinate, a graph is created using the following criteria: if a

SiO» is between 66 wt% and 75 wt%, the ratio of Fe2O3 to FeO falls below one

Curve y = 2.6198 * 1027 * 208505 where when a relationship 75 wt% < SiO2 < 80 wt% holds and the ratio of Fe2O3 to FeO is less than 10, it indicates that the granite may have a potential to form a tungsten-tin deposit; under

Using the temperature T as the abscissa and the oxygen volatility (lg(fO2)) as the ordinate, a graph is constructed, determining the following criteria: if both the

temperature T is between 600 °C and 900 °C and the oxygen volatility (lg(fO2)) falls under a curve y=0.0364x-35.909, indicating that the granite has a low

exhibits oxygen volatility and has a potential to form a tungsten-tin deposit; 2) Identifying the level of differentiation: the main and

Whole rock trace element data are processed using

TE1,3 as the abscissa and Nb/Ta as the ordinate, a graph is constructed using

TE1,3 as the abscissa and Zr/Hf as the ordinate, a graph is constructed using

Zr/Hf as the abscissa and Nb/Ta as the ordinate is graphed using

K/Rb as the abscissa and Rb/Sr as the ordinate is graphed based on these

Graphs following criteria is obtained: if the parameters of the whole rock the

relationships Nb/Ta<7, Zr/Hf<35, TE1.3>1.05, Rb/Sr>2, K/Rb<150, it is indicated that this granite has a high degree of differentiation and a potential to form a

has tungsten-tin deposit; @ Identifying the degree of hydrothermal transformation of magma: the zircon trace element data obtained in Step 2 is processed, using

A graph is constructed of Eu/Eu* as the abscissa and U as the ordinate, where using

A graph is constructed of Eu/Eu* as the abscissa and Hf as the ordinate, where using

Total REE as abscissa and LREE as ordinate, a graph is prepared using Total REE as abscissa and Eu/Eu* as ordinate, from which graphs the following criteria are obtained: if the zircon in this granite is the

Relations U>250ug/g, Eu/Eu*<0.3, LREE>20ug/g, Total REE>1050 are met, indicating that the granite has undergone a strong hydrothermal transformation process of magma and has a potential to form a Has tungsten-tin deposit.

A granitic magma that forms tungsten and tin has the following three characteristics: low oxygen volatility, high degree of differentiation, and high intensity of hydrothermal transformation of magma. The geochemistry of the whole rock and the

Geochemistry of the trace elements of minerals (e.g. zircon) can reflect these three properties well. For example, the redox properties of magma can be determined by considering the Fe2O3/FeO ratio of the whole rock and the oxygen volatility of the magma

Minerals "Zircon" in granite are calculated, using the parameters Nb/Ta, Zr/Hf, TE1.3,

Rb/Sr, K/Rb of the whole rock of the granite determines the degree of evolution of magma, where U, Eu/Eu*, LREE and Total REE of zircon can reflect the degree of hydrothermal transformation of magma. By distinguishing ore-bearing and non-ore-bearing granites in the above three aspects, a way is provided to identify a metallogenic potential of tungsten and tin in granite.

The present invention relates to a multi-indicator based method for assessing prospecting potential of tungsten and tin in granite using bulk rock geochemistry and mineral microgeochemistry. First the

SiO2 content and the ratio of Fe2O3 to FeO of the whole rock of granite used to

determine redox properties of magma; then the parameters of Nb/Ta, Zr/Hf,

TE1,3, Rb/Sr, K/Rb of the whole rock of the granite used to give a degree of evolution of

to determine magma; finally, the U concentration and the Eu/Eu* of zircon, LREE as well as Total REE are used to determine a degree of hydrothermal transformation of magma; Finally, it is assessed whether the granite is a rock body forming tungsten-tin ore. With this procedure, the changes in the

Composition of the total rock and the mineral micro-area closely related to the

identification of the potential to form a tungsten-tin deposit, thereby overcoming the difficulties of low efficiency, long cycle time and high cost of conventional methods for assessing metallogenic potential. The

The probability of finding tungsten-tin deposits with this method is over 70%. This method is a very eligible method for assessing the metallogenic potential of tungsten and tin in granite. The method proposes by means of

Total rock geochemistry and mineral microgeochemistry the metallogenic

To assess the potential of tungsten and tin in granite, which represents an original innovation, provides a theoretical basis for further reducing the scope of the target area in a mineral-concentrated or mineral-bearing area, and improves ore prospecting efficiencies.

The present invention has the following advantageous effects: 1. The present invention provides a multi-indicator based method

Assessing a prospecting potential of tungsten and tin in granite using the geochemistry of the

Whole rock and mineral microgeochemistry, with analysis of the

Total rock and a microanalysis of minerals of the collected granite three

Indicators, namely, an oxygen volatility of magma, a degree of differentiation of

Magma and an intensity of the hydrothermal alteration of magma of the granite, with the changes in the composition of the whole rock as well as the mineral microscale closely related to the identification of the potential for the formation of a

Tungsten-Tin Deposit can be combined, using these three indicators to efficiently assess the metallogenic potential of tungsten and tin in granite, thereby providing the

The challenge of assessing a tungsten-tin ore forming rock body is solved and a new method and workflow is created to rapidly assess the metallogenic potential of tungsten and tin in granite in new prospects.

2. The present invention represents an economical, environmentally friendly and efficient new prospecting method. By collecting a large amount of data, it was found that the probability of tungsten-tin deposition by this

Finding method is greater than 70%, which has important practical value.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 shows a relation diagram between the Fe2O3/FeO ratio and the SiO2 content in the whole rock of granite in figure (a) and a in figure (b).

Relation diagram between lg(fOz) of zircon in granite and temperature according to a first embodiment (the data are from tungsten-tin bearing granites and tungsten-tin-free granites in the South China and Gangdise metallogenic belts).

Fig. 2 shows a relational diagram between the Nb/Ta ratio and at panel (a).

TE1,3, in figure (b), a relationship diagram between the Nb/Ta ratio and the

Zr/Hf ratio, in figure (c) a relationship diagram between the Nb/Ta ratio and the Zr/Hf ratio, and in figure (d) a relationship diagram between the

Rb/Sr ratio and the K/Rb ratio in the whole rock of the granite according to the first

Working example (the data are from tiniferous granite in the metallogenic belts of southern China and Gangdise).

Fig. 3 shows in figure (a) a relational diagram between the U concentration and the

Eu/Eu* ratio, in figure (b) a relationship diagram between Hf and the

Eu/Eu* Ratio, in figure (c) a relationship diagram between LREE, Total REE and the

Eu/Eu* ratio and in figure (d) a relationship diagram between the

Eu/Eu* Ratio and Total REE of Zircon in Granite According to the First Embodiment (data are from tungsten-tin bearing granites and tungsten-tin-free granites in the South China and Gangdise Metallogenic Belts).

DETAILED DESCRIPTION

The present invention is described in detail below with reference to the exemplary embodiments and the accompanying drawings. However, it is understood that the

Exemplary embodiments and the attached drawings serve only to describe the present invention by way of example and do not represent any limitation of the protective scope of the present invention. All meaningful transformations and combinations in the

Scope of the inventive concept of the present invention are included in the

Scope of the present invention.

First embodiment:

A criterion for evaluating a metallogenic potential of tungsten and tin in granite is provided, comprising the steps of: (1) Gathering, in accordance with a selected research area, prospect geological, geophysical and geochemical data, comprehensively analyzing a metallogenic prospect, and defining a favorable one metallogenic range in metallogenic

Belts of South China and Gangdise; (2) Sampling: Samples will be taken from ore-bearing and non-ore-bearing granites in the favorable metallogenic zone in the southern China and China metallogenic belts

gangdise taking a representative set of samples from each granite with metallogenic prospects; (3) Major and trace element analysis for the whole rock: the granite samples are pulverized to pass through a 200 mesh sieve, after which the major elements (SiO2, TiO2, Al2O3, FeO, Fe2O3, MnO, MgO, CaO, Na:O, K2O, P2Os) using a

X-ray fluorescence spectrometer (XRF) and a potassium dichromate method, with the samples being processed for XRF analysis as follows: D A sample which can pass through a 200 mesh sieve is heated for 12 hours in an oven with a

temperature of 105°C; 2) a dried sample of up to 1.0 g is weighed and placed in a ceramic constant-weight crucible, placed in a

muffle furnace fired at 1000°C for 2 hours and then taken out, after the sample is cooled to room temperature, it is weighed again to calculate a loss on ignition; @ A flux (Li2B4O7 : LiBO2 : LiF = 9:2:1) of 6.0 g, a sample of 0.6 g and an oxidizing agent (NH4NO3) of 0.3 g are weighed and poured out into a crucible

Platinum is added, and then are melted in a melting furnace with a temperature of 1150°C for 14 minutes, after which the crucible is taken out and placed on a refractory brick to cool, after which the glass piece is taken out for the XRF test. After that, the analysis of trace elements (Li, Be, Sc, V, Cr, Co, Ni,

Cu, Zn, Ga, Rb, Sr, Y, Zr, Nb, Sn, Cs, Ba, La, Ce, Pr, Nd, Sm , Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, Lu, HF,

Ta) samples of the granite were performed by inductively coupled plasma mass spectrometry (ICP-MS), the samples being processed for ICP-MS analysis as follows: D a 200-mesh sieve-passable sample is used placed in an oven at a temperature of 105°C for 12 hours; 2) a powdered sample of exactly 50 mg is weighed and then placed in a Teflon dissolution bomb; @ a 1ml high-purity HNO3 and a 1ml high-purity HF are successively slowly added; @ the

Teflon dissolution bomb is placed in a steel sleeve, which is then tightened, and then placed in an oven with a temperature of 190℃ and heated there for more than 24 hours; ©) after the dissolution bomb has cooled down, the lid of the

dissolution bomb opened, after which the dissolution bomb is placed on an electric hot plate of 140°C and then evaporated to dryness, after which HNO:3 of 1 ml is added and again evaporated to dryness; ©) a high-purity ENT; of 1 ml, a MQ water of 1 ml and an internal standard In of 1 ml (with a concentration of 1 ppm) are added, after which the Teflon dissolution bomb is put back in the steel sleeve, which is then tightened and then in a placed in an oven with a temperature of 190°C and heated there for more than 12 hours; 2 The solution is placed in a polyethylene bottle and diluted to 100 g with a 2% HNO3 solution for ICP-MS tests. (4) Microanalysis and testing of minerals: part of the samples taken in step (2) are used to select zircon, after which the properties of the corresponding

Zircons are observed under a microscope and a cathodoluminescence image, the

Type of zircon is recorded in detail, and where a

In situ micro-array elemental analysis for mass spectrometry with inductively coupled

Plasma is performed by laser ablation, using the laser ablation system

GeolasPro consists of an excimer laser "COMPexPro 102 ArF 193 nm" and an optical one

System "MicroLas" where the ICP-MS model is Agilent 7700e. during the

Laser ablation process uses helium as the carrier gas and argon as the compensation gas

Sensitivity setting used. The helium and argon are mixed through a T-junction before entering the ICP. And the laser ablation system is with a

signal smoothing device (Hu et al, 2015). The laser beam spot or the

frequency is 32 or 44 µm or 5 Hz. Then the software ICPMSDataCal is used to complete the trace element data of each test point; (5) Calculating various parameters of granite formation: the differentiation coefficients of Rb/Sr, K/Rb, Nb/Ta, Zr/Hf and TE1.3 are calculated using whole rock data of granite, with TE1.3= [(((2* Cen/(Lan+Prn))*(2*Prn/(Cen+Ndn))*0.5)*((2*Tbn/Gdu+Dyn))*(2*Dyn/(Tbw+Hon))* 0.5] (Irber, 1999), where N is the normalized value of chondrites

Zircon trace element data is combined with comprehensive analysis software

Geo-f0, for oxygen volatility and a Geokit software will be the

Zircon (Eu/Eu*) europium anomaly, the light rare earth (LREE), the heavy rare

earth (Total REE), the temperature T (°C) at which the granite is formed, and the

Oxygen volatility (lg(fO2) and other parameters calculated.

Step (6): the criteria for identifying oxygen volatility, identifying the

degree of differentiation and identifying the degree of hydrothermal conversion of

Magma are determined where:

D Identification of the oxygen volatility: the data obtained in step 5 are processed using the content of SiO2 as the abscissa and the ratio of Fe2O3 to

FeO as the ordinate, a graph is drawn as in Fig. 14, determining the following criteria: when a SiO2 is between 66% and 75% by weight, the ratio of Fe2O3 to FeO falls under a curve y= 2.6198 * 1077 * 298505 where, when a relationship 75% by weight <

SiO2 < 80% by weight and the ratio of Fe2O3 to FeO is less than 10, it indicates that the granite may have potential to form a tungsten-tin deposit; using temperature T as abscissa and oxygen volatility (lg(fOz)) as

ordinate a graph, as in Fig. 1b, is created, with the following criteria being determined: if both the temperature T is between 600° C. and 900° C. and the

Oxygen volatility (lg(fO2)) falls under a curve y=0.0364x-35.909 (lg(fO2) as ordinate and

temperature as abscissa), indicating that the granite has low oxygen volatility and has a potential to form a tungsten-tin deposit; 2) Identifying the level of differentiation: the main and

Whole rock trace element data are processed using

TE1,3 as abscissa and Nb/Ta as ordinate is graphed (as shown in Fig. 2a), wherein using TE1,3 as abscissa and Zr/Hf as ordinate is graphed (as in

2b) wherein using Zr/Hf as the abscissa and Nb/Ta as the ordinate

graph is constructed (as shown in Figure 2c) using K/Rb as the abscissa and

Rb/Sr as the ordinate, a graph is constructed (as shown in Fig. 2d) using these

Graphs following criteria is obtained: if the parameters of the whole rock the

relationships Nb/Ta<7, Zr/Hf<35, TE1.3>1.05, Rb/Sr>2, K/Rb<150, it is indicated that this granite has a high degree of differentiation and a potential to form a

has tungsten-tin deposit;

@ Identifying the degree of hydrothermal transformation of magma: the zircon trace element data obtained in step 5 is processed, using

Eu/Eu* as the abscissa and U as the ordinate is graphed (as shown in Fig. 3a), wherein a graph is made using Eu/Eu* as the abscissa and Hf as the ordinate (as in

3b) wherein using Total REE as abscissa and LREE as ordinate

Graph is constructed (as shown in Fig. 3c), using Total REE as abscissa and Eu/Eu* as ordinate, a graph is constructed (as shown in Fig. 3d), from which graphs the following criteria are obtained: if the zircon in this granite die

Relations U>250ug/g, Eu/Eu*<0.3, LREE>20ug/g, Total REE>1050 are met, indicating that the granite has undergone a strong hydrothermal transformation process of magma and has a potential to form a Has tungsten-tin deposit.

If the granite satisfies the above three identification conditions D 2) @ at the same time, it means that the granite has the characteristics of low oxygen volatility, high degree of differentiation and high intensity of hydrothermal

alteration of magma and thus has a very good metallogenic potential of tungsten and tin, this granite can be evaluated as a tungsten-tin ore forming rock body, with a target area defined within a certain radius depending on the exposed position of the granite; if a granite body is one of the three

Not meeting identification criteria, it is a non-oreiferous body of rock with a low probability of finding an ore with no target area defined.

Second embodiment: Identifying a metallogenic potential of W-Sn granite in the southern China metallogenic belt (1) Collecting, according to a selected research area, comprehensive geological, geophysical and geochemical prospecting data

Analyzing a metallogenic prospect, and delineating a favorable metallogenic

range in metallogenic belts of southern China; (2) Sampling: Samples will be taken from granites with a metallogenic potential in the favorable metallogenic zone in the Metallogenic Belts of South China, with a series of representative samples collected from each granite with a metallogenic prospect; (3) Data Analysis and Calculation Referring to steps (3) to (5) in the first

embodiment;

(4) Identify, according to step (6) in the first embodiment, one

oxygen volatility, a degree of differentiation and a degree of hydrothermal

Conversion of magma from Xihuashan samples from southern China. The following applies here:

D Identifying oxygen volatility: for a granite from southern China, SIOz ranges from 71 wt% to 79 wt% with the ratio of Fe2O3 to FeO ranging from 0.03 to 11, with most samples falling within the shaded area ( when SiO2 is between 66 wt% and 75 wt% and the ratio of Fe20:3 to FeO falls under a curve y = 2.6198 * 1077 * e%850% when the relationship 75 wt% < SiO2 < 80 wt .-% applies and the ratio of

Fe2O3 to FeO is less than 10) as shown in Fig. 1a and the temperature (550°C to 900°C) and oxygen volatility (Ig(fOz)) (-24 to -3) data in Fig. 1b are plotted, where when these data fall below the curve y=0.0364x - 35.909, indicating that the

Granite has a metallogenic potential of tungsten and tin and the oxygen volatility in southern China meets the metallogenic conditions. 2) Identifying the degree of differentiation: using the all-rock data from

Granite from southern China will have a differentiation coefficient of Rb/Sr (from 3.1 to 420), K/Rb (from 45 to 140), Nb/Ta (from 0.5 to 7.5), Zr/Hf (from 5, 1 to 34.5) as well as TE1.3 (from 0.95 to 1.26) (see Fig. 2), where most sample parameters have the relationships Nb/Ta < 7, Zr/Hf < 35, TE1.3 > 1.05, Rb/Sr > 2, K/Rb < 150, indicating that this granite has a high

Degree of differentiation and potential to form a tungsten-tin deposit. @ Identify the degree of hydrothermal transformation of magma: the granite out

Southern China has U concentration from 200ug/g to 40000ug/g, Eu/Eu* from 0 to 0.37, LREE from 9.00ug/g to 10000ug/g, Total REE from 500ug/g to 26000 µg/g (see Fig. 3), having the properties that igneous zircon is converted into hydrothermal zircon and the relationships U>250 µg/g, Eu/Eu*<0.3, LREE>20 µg /g, Total REE>1050 ug/g are met, indicating that this granite has a strong hydrothermal

have undergone the transformation process of magma and have a potential to form a

Has tungsten-tin deposit. In summary, these granites meet the conditions for the formation of a tungsten-tin deposit in terms of oxygen volatility, the

Degree of differentiation and the degree of hydrothermal transformation of magma. Later investigations also found Xihuashan tungsten-tin ore in this area.

Third Embodiment: Identifying a Metallogenic Potential of W-Sn Granite in

Hahaigang and Jiagang in the Gangdise Metallogenic Belt

(1) Collecting, according to a selected research area, prospective geological, geophysical and geochemical data, comprehensively analyzing a metallogenic prospect, and delineating a favorable metallogenic area within metallogenic ones

Girdles of Gangdise; (2) Sampling: Samples will be taken from Hahaigang and Jiagang W-Sn granites with a metallogenic potential in the favorable metallogenic range in the metallogenic

Belts of South China Gangdise, with a representative array of samples taken from each granite with a metallogenic outlook; (3) Data Analysis and Calculation Referring to steps (3) to (5) in the first

embodiment; (4) Identify, according to step (6) in the first embodiment, one

oxygen volatility, a degree of differentiation and a degree of hydrothermal

Conversion of magma from Hahaigang and Jiagang samples derived from the metallogenic

belts were taken from Gangdise. The following applies here:

D Identifying the oxygen volatility: a granite from the above area has SiO2 between 70.5 wt% and 78 wt% with the ratio of Fe2O3 to FeO between 0.05 and 2, with most samples in fall within the shaded area (if

SiO2 is between 66% and 75% by weight and the ratio of Fe20O3 to FeO is below one

curve y = 2.6198 * 1077 * e0.8503x falls; when the relationship 75 wt% < SiO2 < 80 wt% and the ratio of Fe2 O3 to FeO is less than 10), as shown in Fig. 1a, and wherein the

Temperature (550°C to 800°C) and oxygen volatility (lg(fO2)) (-25 to -12) in. data

1b, when this data falls below the y=0.0364x-35.909 curve, it indicates that the granite has a metallogenic potential of tungsten and tin. 2) Identifying the degree of differentiation: using the all-rock data from

Granite from southern China has a coefficient of differentiation of Rb/Sr (from 0.9 to 90), K/Rb (from to 225), Nb/Ta (from 0.2 to 5.1), Zr/Hf (from 5 to 30 ) as well as TE1.3 (from 0.97 to 1.48) (see Fig. 2), with most sample parameters having the relationships Nb/Ta < 7, Zr/Hf < 35, TE1.3 > 1.05, Rb/Sr > 2 , K/Rb < 150, indicating that this granite has a high

Has a degree of differentiation and has a potential for forming a tungsten-tin deposit 30 . @ Identify the degree of hydrothermal transformation of magma: this granite has a U concentration from 800ug/g to 15000ug/g, Eu/Eu* from 0 to 0.31, LREE from 15ug/g to 300ug/g , Total REE from 800 µg/g to 8200 µg/g (see Fig. 3), having the properties that igneous zircon is converted into hydrothermal zircon, and the

Relations U>250 ug/g, Eu/Eu*<0.3, LREE>20 ug/g, Total REE>1050 ug/g are satisfied, indicating that this granite has undergone a strong hydrothermal transformation process of magma and a potential to form a tungsten-tin deposit.

In summary, these granites meet the conditions for the formation of a

Tungsten-tin deposit in terms of oxygen volatility, degree of differentiation and degree of hydrothermal conversion of magma. After later investigations, Hahaigang and Jiagang tungsten-tin ore were also found in this area.

Fourth Embodiment: Identifying a Metallogenic Potential of W-Sn Granite in

Bangbule and Chagele in the Gangdise Metallogenic Belt (1) Collecting, according to a selected research area, prospect geological, geophysical and geochemical data, comprehensively analyzing a metallogenic prospect, and delineating a favorable metallogenic zone within metallogenic ones

Girdles of Gangdise; (2) Sampling: Samples will be taken from Bangbule and Chagele W-Sn granites with a metallogenic potential in the favorable metallogenic range in the metallogenic

belts of Gangdise taking a representative set of samples from each granite with metallogenic prospects; (3) Data Analysis and Calculation Referring to steps (3) to (5) in the first

embodiment; (4) Identify, according to step (6) in the first embodiment, one

oxygen volatility, a degree of differentiation and a degree of hydrothermal

Conversion of magma from Bangbule and Chagele samples derived from the metallogenic

belts were taken from Gangdise. The following applies here:

D Identifying the oxygen volatility: a granite from the above area has SiO2 between 72.5 wt% and 78 wt% with the ratio of Fe2O3 to FeO between 0.02 and 7, with most samples in fall within the shaded area (if

SiO2 is between 66 wt% and 75 wt% and the ratio of FezO3 to FeO below one

curve y = 2.6198 * 1077 * e0.8503x falls; when the relationship 75% by weight < SiO2 < 80% by weight and the ratio of Fe2O3 to FeO is less than 10), as shown in Fig. 1a, and wherein the

Temperature (570°C to 850°C) and oxygen volatility (lg(fO2)) (-22 to -2.5) in. data

1b, when this data falls below the y=0.0364x-35.909 curve, it indicates that the granite has a metallogenic potential of tungsten and tin.

2) Identifying the degree of differentiation: using the all-rock data from

Bangbule and Chagele granite has a coefficient of differentiation of Rb/Sr (from 0.18 to 4.0), K/Rb (from 110 to 250), Nb/Ta (from 6.0 to 19), Zr/Hf (from 20 to 44) and TE1.3 (from 0.97 to 1.05) (see Fig. 2), these samples having the relationships Nb/Ta < 7, Zr/Hf < 35,

TE1.3 > 1.05, Rb/Sr > 2, K/Rb < 150, indicating that this

Granite has a small degree of differentiation and no potential to form one

Has tungsten-tin deposit. @ Identify the degree of hydrothermal transformation of magma: this granite has a U concentration from 60ug/g to 360ug/g, Eu/Eu* from 0.25 to 0.51, LREE from 30ug/g to 90ug /g, Total REE from 600 µg/g to 1050 µg/g (see Fig. 3), where the characteristics that igneous zircon is transformed into hydrothermal zircon are not clearly present, and the relationships U>250 µg/g, Eu/Eu*<0.3, LREE>20ug/g, Total REE>1050ug/g are not met, indicating that this granite does not undergo strong hydrothermal transformation process of

experienced magma and has no potential to form a tungsten-tin deposit. In summary, these granites from Bangbule and Chagele show a small

Oxygen volatility on, but their degree of differentiation and degree of hydrothermal

Conversion of magma does not meet the conditions for the formation of a tungsten-tin deposit. Therefore, these granites have no potential to form a tungsten-tin deposit.

Subsequent investigations did not find any tungsten-tin deposits in these areas.

In summary, by identifying the oxygen volatility, des

degree of differentiation and the degree of hydrothermal transformation of magma from granites in Gangdise and in southern China's Xihuashan, Hahaigang, Jiagang, Bangbule and Chagele

Concluded that the Xihuashan, Hahaigang and Jiagang areas have potential to form a tungsten-tin deposit, and Bangbule and Chagele areas have no potential to form a tungsten-tin deposit due to insufficient degree of differentiation and insufficient degree of hydrothermal conversion of magma

Have tungsten-tin deposit. And through subsequent verification work, such as drilling, etc., by the geological team, tungsten-tin deposits in the areas of Xihuashan,

Hahaigang and Jiagang discovered, being through verification work, such as drilling, etc., only

Lead-zinc ore bodies and no tungsten-tin ore body discovered, thereby verifying the evaluation of the method according to the invention. This indicates that the method is a very eligible method for assessing the metallogenic potential of tungsten and

pewter in granite.

Claims (6)

N BE2022/5992 PATENT CLAIMS Claims 1. A multi-indicator based method for assessing a prospecting potential of tungsten and tin in granite, characterized in that it comprises the steps of: (1) delineating a metallogenic zone; (2) sampling; (3) analyzing the samples: the samples are subjected to major and trace element analysis for whole rock to obtain major and trace element data for whole rock and microanalysis of zircon minerals to obtain zircon trace element data; a SiO2 content is determined and a differentiation coefficient of Fe2O3/FeO, Rb/Sr, K/Rb, Nb/Ta, Zr/Hf and TE1.3 is calculated using granite whole rock data; using the zircon trace element data, a U concentration is determined, with parameters including europium anomaly of zircon, light rare earth, heavy rare earth, temperature T at which the granite is formed, and oxygen volatility, be calculated; (4) Identifying the metallogenic potential of tungsten and tin in granite: a ratio of SiO2 to Fe2O3/FeO of the whole rock of granite and a relationship between temperature T and zircon oxygen volatility of granite are used to determine redox properties of magma and identify the level of oxygen volatility; then the parameters of Nb/Ta, Zr/Hf, TE1.3, Rb/Sr, K/Rb of the whole rock of the granite are used to determine an evolution degree of magma and identify a degree of differentiation; finally, the U concentration and the europium anomaly of zircon, the light rare earth and the heavy rare earth are used to identify a degree of hydrothermal transformation of magma and an intensity of hydrothermal transformation of magma; Depending on three indicators, namely, the oxygen volatility of magma, the degree of differentiation of magma, and the intensity of hydrothermal transformation of magma into granite, it can be judged whether the granite has a metallogenic potential of tungsten and tin. 2. The method according to claim 1, characterized in that in step (4) the identification of the metallogenic potential of tungsten and tin in granite takes place as follows: D Identifying oxygen volatility: the bulk and trace element data obtained in step (3) of the whole rock are processed, where if SiO2 is between 66 wt% and 75 wt%, the ratio of Fe2O3 to FeO falls under a curve y = 2.6198 * 1077 * e0.850%, where at 75 wt% < SiO2 < 80 wt% the ratio of Fe2O3 to FeO is less than 10; the zirconium trace element data obtained in step (3) is processed, indicating that when both the temperature T is between 600 °C and 900 °C and the oxygen volatility falls below a curve y=0.0364x-35.909, it indicates that the granite has low oxygen volatility; 2) Identifying the degree of differentiation: the bulk and trace element data obtained in step (3) of the whole rock are processed, where if the parameters of the whole rock have the relationships Nb/Ta<7, Zr/Hf<35, TE1.3>1.05 , Rb/Sr>2, K/Rb<150, indicating that this granite has a high degree of differentiation; @ Identifying the degree of hydrothermal transformation of magma: the zircon trace element data obtained in step (3) is processed, where if the zircon in this granite has the relationships U>250 ug/g, Eu/Eu*<0.3, LREE >20 ug/g, Total REE>1050 met, indicating that the granite has undergone a strong hydrothermal transformation process of magma; @ if a granite satisfies the above three identification conditions D 2) @ simultaneously, it means that the granite has the characteristics of low oxygen volatility, high degree of differentiation and high intensity of hydrothermal transformation of magma, and thus a metallogenic potential of tungsten and tin having. 3. Method according to claim 2, characterized in that if a granite body satisfies the three identification conditions D 2) @ simultaneously, it has a metallogenic potential of tungsten and tin and is judged as a rock forming tungsten-tin ore, depending on the exposed position of the granite a target area is delineated within a specified radius; and that if a granite body does not meet any of the three identification conditions, it is a non-oreforming body of rock with a low probability of finding an ore and no target area is left undefined. 4. The method according to claim 1, characterized in that in step (3) using the zirconium trace element data in combination with comprehensive analysis software Geo-fO2 for oxygen volatility and Geokit software parameters are calculated, the parameters including zircon europium anomaly, light rare earth, heavy rare earth, temperature T at which the granite is formed and oxygen volatility .. 5. The method according to claim 1, characterized in that step (3) comprises: major and trace element analysis for the whole rock: the samples of granite are pulverized to allow them to pass through a 200 mesh sieve, after which the major elements are separated by a X-ray fluorescence spectrometer and a potassium dichromate method to obtain the content of SiO2, TiO2, Al2O3, FeO, Fe2O3, MnO, MgO, CaO, Na2O, K2O, P2O5, after which the trace elements of the granite samples were analyzed by an ICP-MS Analysis are analyzed so that the content of Li, Be, Sc, V, Cr, Co, Ni, Cu, Zn, Ga, Rb, Sr, Y, Zr, Nb, Sn, Cs, Ba, La, Ce, Pr , Nd, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, Lu, Hf, Ta; Microanalysis and testing of minerals: part of the samples taken in step (2) are used to select zircon, after which the properties of the corresponding zircon are observed under a microscope and a cathodoluminescent image, recording the type of zircon in detail, and where in situ micro-array elemental analysis for inductively coupled plasma mass spectrometry is performed by laser ablation to obtain trace element data for each test point. 6. The method according to claim 1, characterized in that in step (4) criteria for identifying oxygen volatility, identifying degree of differentiation and identifying degree of hydrothermal conversion of magma are obtained specifically as follows: Step 1: at least five samples each are taken from an ore-forming body of rock and a non-ore-forming body of rock; Step 2: the sample is subjected to major and trace element analysis for whole rock to obtain major and trace element data for whole rock and microanalysis of zircon minerals to obtain zircon trace element data; using granite whole rock data, a differentiation coefficient of Fe2O3/FeO, Rb/Sr, K/Rb, Nb/Ta, Zr/Hf and TE1.3 is calculated; using the zircon trace element data, parameters showing a zircon europium anomaly, a light rare earth, a heavy rare earth, a temperature T at which the granite is formed and including oxygen volatility calculated; Step 3: the criteria for identifying oxygen volatility, identifying the degree of differentiation and identifying the degree of hydrothermal conversion of magma are determined, where: D Identifying oxygen volatility: the data obtained in step 2 are processed, using the content of SiO2 as the abscissa and the ratio of Fe2O3 to FeO as the ordinate, the following criteria being determined: at an SiO2 between 66% by weight and 75% by weight, the ratio of Fe2O3 to FeO falls under a curve y= 2.6198 * 1027 * e98503x and at 75 wt% < SiO2 < 80 wt% the ratio of Fe2O3 to FeO is less than 10; a graph is constructed using the temperature T as the abscissa and the oxygen volatility as the ordinate, determining the following criteria: when both the temperature T is between 600 °C and 900 °C and the oxygen volatility is under a curve y=0.0364x- 35,909 indicates that the granite has low oxygen volatility and has potential to form a tungsten-tin deposit; 2) Identifying the degree of differentiation: the major and trace element data of the whole rock obtained in step 2 are processed, constructing a graph using TE1,3 as abscissa and Nb/Ta as ordinate, using TE1,3 as abscissa and Zr/Hf as the ordinate, a graph is constructed using Zr/Hf as the abscissa and Nb/Ta as the ordinate, wherein a graph is constructed using K/Rb as the abscissa and Rb/Sr as the ordinate, based on these graphs, the following criteria are obtained: if the parameters of the whole rock meet the relationships Nb/Ta <7, Zr/Hf<35, TE1.3>1.05, Rb/Sr>2, K/Rb<150, indicated that this granite has a high degree of differentiation and potential to form a tungsten-tin deposit; @ Identify the degree of hydrothermal transformation of magma: the zircon trace element data obtained in step 2 is processed, constructing a graph using Eu/Eu* as the abscissa and U as the ordinate, using Eu/Eu* as the abscissa and Hf as ordinate, graphing using Total REE as abscissa and LREE as ordinate, graphing using Total REE as abscissa and Eu/Eu* as ordinate, from which Graphene following criteria is obtained: if the zircon in this granite the Relations U>250ug/g, Eu/Eu*<0.3, LREE>20ug/g, Total REE>1050 are met, indicating that the granite has undergone a strong hydrothermal transformation process of magma and has a potential to form a Has tungsten-tin deposit.