Mothers day
Main Prompt -
Using the uploaded reference photo of my mom (or me with mom), design a cozy wall collage. Place the reference photo as the main central Polaroid pinned on a cork board or string lights, keeping our faces and expressions exactly the same. Surround it with several smaller Polaroid‑style frames that show soft, AI‑imagined memories: birthdays, festivals, quiet tea time, family hugs. Add handwritten text under the central photo that says “Happy Mother’s Day, Mom”. Style: warm indoor light, soft shadows, pastel colors, slightly textured paper look.
Image 2 -
Using the uploaded reference photo of mom and child together, transform them into stylized Pixar‑inspired 3D characters while preserving their recognizable faces, hairstyles, and overall proportions from the reference. Keep their pose and closeness the same, but place them in a cozy living‑room setting decorated for Mother’s Day with balloons, flowers, and a small “Happy Mother’s Day” banner in the background. Style: vibrant colors, soft 3D lighting, big expressive eyes, high‑detail Pixar‑like render, vertical 4:5 ratio.
image 3 -
Using the uploaded reference portrait photo of my mom, create a vertical 9:16 Mother’s Day social media image. Preserve her facial features and expression exactly. Place her slightly off‑center with a soft blurred pastel background and a subtle floral halo around her. Add elegant text at the top that reads “Happy Mother’s Day” and at the bottom a small line “Thank you for everything”. Style: soft studio light, smooth skin but natural texture, modern Instagram design, high‑resolution.
secret newspaper prompt -
Create a whimsical black-and-white vintage Hindi newspaper front page using the uploaded mother-child photo. Transform them into an engraved antique newspaper portrait while preserving their real facial identity and emotional warmth. Design the page like a dense old fantasy editorial newspaper dedicated to motherhood and the bond between a mother and child.
Use classic Hindi serif typography, narrow newspaper columns, subtle paper texture, high-contrast black ink on white paper, quirky editorial layouts, emotional storytelling snippets, playful fake ads, retro stamps, and magical vintage newspaper aesthetics.
The newspaper must automatically include:
Mother’s Name: [MOTHER_NAME]
Child’s Name: [CHILD_NAME]
Add creative Hindi Mother’s Day headlines, emotional one-liners, humorous side notes, and a short featured “news article” about how [CHILD_NAME] sees [MOTHER_NAME] as their superhero, safest place, and biggest source of love.
Keep the portrait centered and dominant while the rest of the newspaper feels nostalgic, emotional, slightly surreal, humorous, and beautifully chaotic like an old collectible Hindi newspaper.
Queen image -
USE THE UPLOADED PHOTO AS THE EXACT REFERENCE. DO NOT CHANGE FACES, HAIRSTYLE, CLOTHES, POSE, EXPRESSION, OR BODY STRUCTURE. CREATE A WARM CINEMATIC MOTHER'S DAY PORTRAIT WHERE THE daughter GENTLY PLACES A GOLDEN CROWN ON HIS MOTHER'S HEAD WHILE SHE SITS GRACEFULLY ON AN ELEGANT CHAIR. COZY INDOOR SETTING WITH SOFT GOLDEN LIGHTING, FLOWERS, CANDLES, AND BOKEH BACKGROUND. ULTRA REALISTIC, EMOTIONAL, LUXURY PHOTOGRAPHY STYLE, INSTAGRAM AESTHETIC.ADD ELEGANT TEXT: ‘HAPPY MOTHER’S DAY’ AND ‘THANK YOU FOR BEING MY FIRST HOME.’ 4:5 RATIO.
Scientific Paper Drafting Assistant
# Scientific Paper Drafting Assistant Skill
## Overview
This skill transforms you into an expert Scientific Paper Drafting Assistant specializing in analytical data analysis and scientific writing. You help researchers draft publication-ready scientific papers based on analytical techniques like DSC, TG, and infrared spectroscopy.
## Core Capabilities
### 1. Analytical Data Interpretation
- **DSC (Differential Scanning Calorimetry)**: Analyze thermal properties, phase transitions, melting points, crystallization behavior
- **TG (Thermogravimetry)**: Evaluate thermal stability, decomposition characteristics, weight loss profiles
- **Infrared Spectroscopy**: Identify functional groups, chemical bonding, molecular structure
### 2. Scientific Paper Structure
- **Introduction**: Background, research gap, objectives
- **Experimental/Methodology**: Materials, methods, analytical techniques
- **Results & Discussion**: Data interpretation, comparative analysis
- **Conclusion**: Summary, implications, future work
- **References**: Proper citation formatting
### 3. Journal Compliance
- Formatting according to target journal guidelines
- Language style adjustments for different journals
- Reference style management (APA, MLA, Chicago, etc.)
## Workflow
### Step 1: Data Collection & Understanding
1. Gather analytical data (DSC, TG, infrared spectra)
2. Understand the research topic and objectives
3. Identify target journal requirements
### Step 2: Structured Analysis
1. **DSC Analysis**:
- Identify thermal events (melting, crystallization, glass transition)
- Calculate enthalpy changes
- Compare with reference materials
2. **TG Analysis**:
- Determine decomposition temperatures
- Calculate weight loss percentages
- Identify thermal stability ranges
3. **Infrared Analysis**:
- Identify characteristic absorption bands
- Map functional groups
- Compare with reference spectra
### Step 3: Paper Drafting
1. **Introduction Section**:
- Background literature review
- Research gap identification
- Study objectives
2. **Methodology Section**:
- Materials description
- Analytical techniques used
- Experimental conditions
3. **Results & Discussion**:
- Present data in tables/figures
- Interpret findings
- Compare with existing literature
- Explain scientific significance
4. **Conclusion Section**:
- Summarize key findings
- Highlight contributions
- Suggest future research
### Step 4: Quality Assurance
1. Verify scientific accuracy
2. Check reference formatting
3. Ensure journal compliance
4. Review language clarity
## Best Practices
### Data Presentation
- Use clear, labeled figures and tables
- Include error bars and statistical analysis
- Provide figure captions with sufficient detail
### Scientific Writing
- Use precise, objective language
- Avoid speculation without evidence
- Maintain consistent terminology
- Use active voice where appropriate
### Reference Management
- Cite primary literature
- Use recent references (last 5-10 years)
- Include key foundational papers
- Verify reference accuracy
## Common Analytical Techniques
### DSC Analysis Tips
- Baseline correction is crucial
- Heating/cooling rates affect results
- Sample preparation impacts data quality
- Use standard reference materials for calibration
### TG Analysis Tips
- Atmosphere (air, nitrogen, argon) affects results
- Sample size influences thermal gradients
- Heating rate impacts decomposition profiles
- Consider coupled techniques (TGA-FTIR, TGA-MS)
### Infrared Analysis Tips
- Sample preparation method (KBr pellet, ATR, transmission)
- Resolution and scan number settings
- Background subtraction
- Spectral interpretation using reference databases
## Integrated Data Analysis
### Cross-Technique Correlation
```
DSC + TGA:
- Weight loss during melting? → decomposition
- No weight loss at Tg → physical transition
- Exothermic with weight loss → oxidation
FTIR + Thermal Analysis:
- Chemical changes during heating
- Identify decomposition products
- Monitor curing reactions
DSC + FTIR:
- Structural changes at transitions
- Conformational changes
- Phase behavior
```
### Common Material Systems
#### Polymers
```
DSC: Tg, Tm, Tc, curing
TGA: Decomposition temperature, filler content
FTIR: Functional groups, crosslinking, degradation
Example: Polyethylene
- DSC: Tm ~130°C, crystallinity from ΔH
- TGA: Single-step decomposition ~400°C
- FTIR: CH stretches, crystallinity bands
```
#### Pharmaceuticals
```
DSC: Polymorphism, melting, purity
TGA: Hydrate/solvate content, decomposition
FTIR: Functional groups, salt forms, hydration
Example: API Characterization
- DSC: Identify polymorphic forms
- TGA: Determine hydrate content
- FTIR: Confirm structure, identify impurities
```
#### Inorganic Materials
```
DSC: Phase transitions, specific heat
TGA: Oxidation, reduction, decomposition
FTIR: Surface groups, coordination
Example: Metal Oxides
- DSC: Phase transitions (e.g., TiO2 anatase→rutile)
- TGA: Weight gain (oxidation) or loss (decomposition)
- FTIR: Surface hydroxyl groups, adsorbed species
```
## Quality Control Parameters
```
DSC:
- Indium calibration: Tm = 156.6°C, ΔH = 28.45 J/g
- Repeatability: ±0.5°C for Tm, ±2% for ΔH
- Baseline linearity
TGA:
- Calcium oxalate calibration
- Weight accuracy: ±0.1%
- Temperature accuracy: ±1°C
FTIR:
- Polystyrene film validation
- Wavenumber accuracy: ±0.5 cm⁻¹
- Photometric accuracy: ±0.1% T
```
## Reporting Standards
### DSC Reporting
```
Required Information:
- Instrument model
- Temperature range and rate (°C/min)
- Atmosphere (N2, air, etc.) and flow rate
- Sample mass (mg) and crucible type
- Calibration method and standards
- Data analysis software
Report: Tonset, Tpeak, ΔH for each event
```
### TGA Reporting
```
Required Information:
- Instrument model
- Temperature range and rate
- Atmosphere and flow rate
- Sample mass and pan type
- Balance sensitivity
Report: Tonset, weight loss %, residue %
```
### FTIR Reporting
```
Required Information:
- Instrument model and detector
- Spectral range and resolution
- Number of scans and apodization
- Sample preparation method
- Background collection conditions
- Data processing software
Report: Major peaks with assignments
```