# Copper sulfide deposition and remobilisation triggered by non-magmatic fluid incursion in the single-intrusion Tongchang porphyry system, SE China

**Authors:** Xuan Liu, Antonin Richard, Jacques Pironon, Kuifeng Yang

PMC · DOI: 10.1038/s41598-024-52978-5 · Scientific Reports · 2024-01-31

## TL;DR

The Tongchang porphyry deposit in China shows how non-magmatic fluids interact with magmatic fluids to form copper sulfide ores through distinct hydrothermal stages.

## Contribution

The study proposes six generic fluid models for porphyry ore deposits based on the Tongchang system, incorporating non-magmatic fluid incursion.

## Key findings

- Magmatic and non-magmatic fluids coexisted and were spatially separated by an impermeable quartz shell.
- Non-magmatic fluid incursion triggered major copper sulfide deposition during the late-intermediate stage.
- Ore remobilization occurred in the late stage due to breaching of the impermeable shell by groundwater.

## Abstract

Porphyry ore deposits are a major source of base and precious metals. Likewise, they bear important fingerprints for understanding magmatic / hydrothermal processes in the convergent margin. For many decades, the sources of non-magmatic fluid and its role in sulfide mineralization in the porphyry hydrothermal systems have been equivocal. The Tongchang porphyry deposit, which is a single intrusive system with a well-established fluid history, is investigated to reconstruct its hydrothermal process that contributed to the ore formation. In-situ oxygen and strontium isotopes in hydrothermal quartz and anhydrite revealed a coexistence of magmatic and non-magmatic fluid reservoirs. The granodiorite—derived magmatic fluid and external groundwater were spatially separated by a hydrologically impermeable shell formed by retrograde mineral deposition (mainly quartz). The location of the impermeable shell coincided with a brittle-ductile transition (BDT) interface established in the host phyllite in response to latent heating by the cooling magmas. It is inferred that the ductile phyllite beneath the impermeable shell may have entrained some amounts of groundwater and remnant metamorphic fluid. The early fluid stage was dominated by the magmatic fluids, forming disseminated chalcopyrite and barren quartz veins in the potassic-altered ductile granodiorite at high temperatures (> 500 °C). The next stage (early-intermediate) was also driven by the circulation of the magmatic fluids, but in a largely brittle zone formed in-between the impermeable shell and the retreated BDT interface (similar to the so-called “carapace” in the orthomagmatic models). In this stage the formation of pyrite and chalcopyrite veins together with chloritic alteration at temperatures of 400–350 °C occurred. The late-intermediate stage was marked by incursion of the trapped non-magmatic fluids due to rupturing of the enlarged carapace. Mixing of the non-magmatic fluids and the magmatic fluids led to deposition of a major phase of vein-type Cu sulfide at temperatures of 350–300 °C. The late fluid stage was characterized by breaching of the impermeable shell in response to volumetric contraction of the fluid system, leading to excessive infiltration of groundwater and ore remobilization. Based on the Tongchang model, six generic fluid models are proposed for porphyry ore deposits that differ in availability of non-magmatic components as well as intrusive histories. The models can account for variabilities in ore and alteration styles found in porphyry ore deposits globally.

## Linked entities

- **Chemicals:** copper sulfide (PubChem CID 165914), chalcopyrite (PubChem CID 19601290), pyrite (PubChem CID 14788), quartz (PubChem CID 24261), anhydrite (PubChem CID 24497)

## Full-text entities

- **Chemicals:** oxygen (MESH:D010100), quartz (MESH:D011791), Cu sulfide (-), pyrite (MESH:C011342), Copper sulfide (MESH:C017846), granodiorite (MESH:C007886), anhydrite (MESH:D002133), chalcopyrite (MESH:C012819), strontium (MESH:D013324), sulfide (MESH:D013440)

## Full text

_Full body text omitted from this summary view._ Fetch the complete paper as Markdown: https://tomesphere.com/paper/PMC11303379/full.md

## Figures

8 figures with captions in the complete paper: https://tomesphere.com/paper/PMC11303379/full.md

## References

4 references — full list in the complete paper: https://tomesphere.com/paper/PMC11303379/full.md

---
Source: https://tomesphere.com/paper/PMC11303379