seawater-freezing-temperature
Calculate the freezing point temperature of seawater from absolute salinity and pressure using GSW thermodynamic equations.
Best use case
seawater-freezing-temperature is best used when you need a repeatable AI agent workflow instead of a one-off prompt.
Calculate the freezing point temperature of seawater from absolute salinity and pressure using GSW thermodynamic equations.
Teams using seawater-freezing-temperature should expect a more consistent output, faster repeated execution, less prompt rewriting.
When to use this skill
- You want a reusable workflow that can be run more than once with consistent structure.
When not to use this skill
- You only need a quick one-off answer and do not need a reusable workflow.
- You cannot install or maintain the underlying files, dependencies, or repository context.
Installation
Claude Code / Cursor / Codex
Manual Installation
- Download SKILL.md from GitHub
- Place it in
.claude/skills/seawater-freezing-temperature/SKILL.mdinside your project - Restart your AI agent — it will auto-discover the skill
How seawater-freezing-temperature Compares
| Feature / Agent | seawater-freezing-temperature | Standard Approach |
|---|---|---|
| Platform Support | Not specified | Limited / Varies |
| Context Awareness | High | Baseline |
| Installation Complexity | Unknown | N/A |
Frequently Asked Questions
What does this skill do?
Calculate the freezing point temperature of seawater from absolute salinity and pressure using GSW thermodynamic equations.
Where can I find the source code?
You can find the source code on GitHub using the link provided at the top of the page.
SKILL.md Source
# Seawater Freezing Temperature Calculation
## Usage
### 1. MCP Server Definition
```python
import asyncio
import json
from mcp.client.streamable_http import streamablehttp_client
from mcp import ClientSession
class OceanClient:
"""OceanGSW-Tool MCP Client"""
def __init__(self, server_url: str, api_key: str):
self.server_url = server_url
self.api_key = api_key
self.session = None
async def connect(self):
try:
self.transport = streamablehttp_client(
url=self.server_url,
headers={"SCP-HUB-API-KEY": self.api_key}
)
self.read, self.write, self.get_session_id = await self.transport.__aenter__()
self.session_ctx = ClientSession(self.read, self.write)
self.session = await self.session_ctx.__aenter__()
await self.session.initialize()
return True
except Exception as e:
print(f"✗ connect failure: {e}")
return False
async def disconnect(self):
try:
if self.session:
await self.session_ctx.__aexit__(None, None, None)
if hasattr(self, 'transport'):
await self.transport.__aexit__(None, None, None)
except Exception as e:
print(f"✗ disconnect error: {e}")
def parse_result(self, result):
try:
if hasattr(result, 'content') and result.content:
content = result.content[0]
if hasattr(content, 'text'):
return json.loads(content.text)
return str(result)
except Exception as e:
return {"error": f"parse error: {e}", "raw": str(result)}
```
### 2. Freezing Temperature Workflow
Calculate the freezing point of seawater based on salinity and pressure.
**Workflow Steps:**
1. **Calculate Absolute Salinity** - Convert practical salinity
2. **Calculate Freezing Temperature** - Compute freezing point
**Implementation:**
```python
## Initialize client
client = OceanClient(
"https://scp.intern-ai.org.cn/api/v1/mcp/34/OceanGSW-Tool",
"<your-api-key>"
)
if not await client.connect():
print("connection failed")
exit()
## Input parameters
input_params = {
'SP': [35.0, 5.0],
'p': [1000.0, 1000.0],
'lon': [120.0, 165.0],
'lat': [30.0, 45.0],
'saturation_fraction': [0.0, 0.0] # 0=air-free, 1=air-saturated
}
## Step 1: Calculate absolute salinity
result = await client.session.call_tool(
"gsw_example_absolute_salinity",
arguments={
"SP": input_params['SP'],
'p': input_params['p'],
'lon': input_params['lon'],
'lat': input_params['lat']
}
)
SA_result = client.parse_result(result)["st"]
## Step 2: Calculate freezing temperature
result = await client.session.call_tool(
"gsw_example_freezing_temp",
arguments={
"SA": SA_result,
"p": input_params['p'],
"saturation_fraction": input_params['saturation_fraction']
}
)
t_freeze_result = client.parse_result(result)["st"]["t_freeze"]
print("Freezing Temperature Results:")
for i, t_freeze in enumerate(t_freeze_result):
print(f"{i+1}. SA={SA_result[i]:.2f} g/kg, p={input_params['p'][i]} dbar")
print(f" Freezing temp: {t_freeze:.3f}°C\n")
await client.disconnect()
```
### Tool Descriptions
**OceanGSW-Tool Server:**
- `gsw_example_absolute_salinity`: Convert practical to absolute salinity
- `gsw_example_freezing_temp`: Calculate freezing temperature
- Args:
- `SA` (list): Absolute salinity (g/kg)
- `p` (list): Pressure (dbar)
- `saturation_fraction` (list): Air saturation (0-1)
- Returns: Freezing temperature (°C)
### Input/Output
**Input:**
- `SA`: Absolute salinity (0-42 g/kg)
- `p`: Sea pressure (0-11000 dbar)
- `saturation_fraction`: 0 (air-free) to 1 (air-saturated)
**Output:**
- Freezing temperature in °C (typically -2 to 0°C)
### Use Cases
- Sea ice formation prediction
- Polar oceanography
- Marine engineering in cold regions
- Climate modeling
### Performance Notes
- **Standards**: TEOS-10
- **Accuracy**: ±0.001°CRelated Skills
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