Quartz
Contact
Surface Science for Solar Assets
SolarEX is built on two distinct nanocoating pathways for photovoltaic glass — passive SiO₂ repellence and active TiO₂ photocatalysis — selected according to irradiance, contamination profile, and operating environment.
Engineering Principle
Surface Engineering Is a Technical Decision
Surface coating selection is not a procurement commodity choice. The mechanism by which a coating modifies glass behavior must be matched to the contamination profile, UV availability, and operating environment of each site. Selecting the correct pathway maximizes the technical and commercial value of the coating system.
SolarEX's two-pathway platform exists precisely because no single surface chemistry addresses every fouling regime. Pathway selection is a technical decision, made upstream, informed by site data — not by generic product preference or availability.
Optical Interface Protection
The glass-air interface is where irradiance is lost to soiling. Nanocoating modifies this interface at the molecular level, reducing adhesion of particulates and preserving optical transmittance over operational cycles.
Adhesion-Energy Control
Surface energy determines how contaminants bond to glass. SiO₂ and TiO₂ films alter surface energy through distinct mechanisms — passive modification versus active photocatalytic decomposition — with measurably different fouling outcomes.
Environment-Matched Mechanism
Contamination profiles vary by geography, climate, and industrial context. Selecting a mechanism matched to the dominant fouling type is the foundational engineering decision that determines whether a coating delivers its intended effect.
Platform Overview
One Platform, Two Surface Pathways
SolarEX offers two mechanistically distinct products — Quartz and Titan — each engineered to deliver a defined surface function. Both products are applied as transparent nano-scale films to photovoltaic glass surfaces. The comparison below is functional and mechanism-led.
Quartz — Passive SiO₂
  • Passive hydrophobic and oleophobic film
  • No UV activation required
  • 100–150 nm transparent film architecture
  • Inorganic soiling focus: dust, pollen, mineral particulates
  • Suited to high-latitude, low-UV, rainfall-assisted environments
  • Surface repellence mechanism — reduces adhesion
Titan — Active TiO₂
  • UV-triggered photocatalytic mechanism
  • Reactive oxygen species (ROS) generation under UV exposure
  • Superhydrophilic rinse response post-UV activation
  • Organic and biological fouling focus
  • Suited to higher-irradiance, desert, tropical, and industrial environments
  • Active decomposition mechanism — breaks down contaminants
Surface Science
What Changes at the Glass Surface
Both SolarEX products operate at the nano-scale interface between photovoltaic glass and its operating environment. The changes they introduce are measurable in surface energy, contact angle, and adhesion behavior — not in bulk optical properties. Understanding each surface function supports better product selection and stronger commercial outcomes.
Surface Energy Modification
Applying SiO₂ or TiO₂ chemistry changes the surface energy of glass. This determines whether water beads and rolls (hydrophobic) or spreads and sheets (superhydrophilic), directly affecting how contaminants deposit and are removed.
Transparent Nano-Scale Films
Quartz forms an invisible SiO₂ film of approximately 100–150 nm. Titan forms a hydrophilic TiO₂ film only a few nanometers thick. Both coatings are designed to preserve optical clarity while modifying surface behavior at the glass interface.
Adhesion Behavior Changes
Modified surface energy reduces the work of adhesion for particulate contaminants. Particles that would otherwise bond firmly to uncoated glass experience reduced adhesion force, making rainfall or low-pressure rinse cycles more effective at removal.
Passive Repellence vs. Active Decomposition
Quartz repels — it prevents adhesion without altering the contaminant chemistry. Titan decomposes — UV-activated ROS breaks down organic molecules at the surface. These are mechanistically distinct responses requiring different site conditions.
Product Deep Dive
Quartz — Passive SiO₂ Film Architecture
Quartz is SolarEX's passive surface engineering product. It applies a 100–150 nm transparent SiO₂-based film to photovoltaic glass, modifying surface energy to produce hydrophobic and oleophobic response without any dependency on UV availability or ambient irradiance levels.
Quartz does not require sunlight to function. Its mechanism operates through surface chemistry alone — reducing adhesion energy for inorganic particulates including mineral dust, pollen, and atmospheric particulates. Rainfall and low-pressure rinse cycles are sufficient to initiate the cleaning response on a Quartz-coated surface.
Product Deep Dive
Titan — Active TiO₂ Photocatalytic Architecture
Titan is SolarEX's active surface engineering product. It applies a TiO₂-based photocatalytic film that is activated by UV irradiance. Upon sufficient UV exposure, the film generates reactive oxygen species (ROS) that decompose organic and biological contaminants at the glass surface — converting them to removable residues that are then cleared by water contact.
Following UV activation, Titan-coated glass transitions to a superhydrophilic state, enabling water to sheet uniformly across the surface rather than bead. This sheeting behavior facilitates efficient rinse removal of decomposed contaminant residues.
Pathway Selection
UV Dependency Is the Key Decision Divider
The single most important variable in pathway selection is UV availability. This determines whether Titan's photocatalytic mechanism can operate as intended — and where Titan delivers its highest technical value. The decision logic is explicit and site-driven.
Quartz — No UV Required
Operates independently of irradiance conditions. Quartz's passive SiO₂ chemistry modifies surface adhesion energy at the point of application. It requires no ongoing UV input to maintain its hydrophobic and oleophobic behavior. Correct specification for:
  • High-latitude installations (Northern Europe, UK, Scandinavia, Canada)
  • Sites with seasonal low-irradiance periods
  • Shaded or partially shaded arrays
  • Dust and pollen-dominated soiling profiles
  • Rainfall-assisted self-cleaning conditions
Titan — UV Activation Required
Mechanism is contingent on sufficient ambient UV. Titan's TiO₂ photocatalytic film requires UV irradiance to generate reactive oxygen species and trigger superhydrophilic surface behavior. Titan is the correct specification for:
  • High-irradiance environments (MENA, South/Southeast Asia, Australia)
  • Desert and semi-arid installations
  • Tropical and equatorial sites
  • Organic, biological, or industrial contamination profiles
  • Sites with consistent UV availability year-round
Application Engineering
Application as Controlled Surface Engineering
Film performance is directly dependent on application quality. Both Quartz and Titan are applied as liquid formulations to photovoltaic glass surfaces in the field or during installation. Surface preparation, method consistency, and cure management are engineering-grade requirements — core quality-control steps for field performance
Residual surfactants, contamination, or inadequate surface preparation can reduce bonding quality and long-term coating durability, compromising adhesion and long-term durability. HVLP spray and cloth/wipe application methods are both supported, with technique selected based on array configuration and site access.
1
Surface Preparation
Glass must be clean, dry, and free of residual surfactants, cleaning agents, or atmospheric contamination. Inadequate preparation is the primary cause of suboptimal film adhesion.
2
Application Methods
HVLP spray (recommended for large arrays) and cloth/wipe methods (suited to precision or access-constrained applications) are both supported. Uniform coverage is the critical outcome parameter.
3
Cure Timing
Pre-cure: approximately 30 seconds. Full cure: approximately 24 hours. Titan outdoor full effect may develop across 24–48 hours depending on UV availability and ambient temperature.
4
Verification
Post-application visual inspection confirms coverage uniformity. Anomalous sheening or uneven film distribution should be identified and corrected within the cure window.
Evidence Framework
SolarEX Technical Evidence Framework
SolarEX applies a disciplined approach to evidence presentation. SolarEX evidence is linked to documented test conditions, product mechanism, and operating environment. Performance observations, controlled examples, and supporting study data are presented with explicit acknowledgment of the conditions under which they were generated — and the conditions required for them to be transferable.
SolarEX combines validated technical testing, documented field evidence, and project-specific assessment to support confident product selection and deployment planning.
Field Observations
Documented site observations from deployed installations provide real-world performance context. These are presented as site-specific, conditions-specific records. They support mechanism plausibility and application quality standards and support commercial evaluation in comparable operating environments.
Controlled Examples
Controlled application and evaluation examples demonstrate film behavior under defined conditions. These are presented with explicit notation of the application protocol, substrate condition, environmental context, and evaluation method. Controlled examples inform engineering decisions — and provide evidence for product positioning, pilot planning, and application guidance.
Expert Rooftop Study
Third-party or expert-led study data is presented with full acknowledgment of methodology, scope, and assumption set. Results are contextualized to the study conditions. The study provides a strong empirical reference for Titan evaluation in UV-sufficient PV environments.

Validation Methodology
Supporting Technical Validation Context
The SolarEX platform draws on established scientific methodologies for surface chemistry validation. The following testing and characterization contexts underpin the technical claims made about Quartz and Titan. Each methodology is presented with scope and limitation transparency.
UV Degradation / Irradiation Testing
Accelerated UV exposure testing characterizes film durability under simulated irradiance loads. Results indicate relative degradation resistance under controlled test conditions — and support assessment of coating durability under irradiance exposure.
Methylene Blue Photocatalytic Activity
Methylene blue (MB) degradation testing is a standardized proxy for photocatalytic activity in TiO₂ systems. MB test results characterize photocatalytic efficiency under controlled conditions and serve as a comparative activity benchmark for Titan formulations.
SEM / Nanostructure Imaging
Scanning electron microscopy provides visual confirmation of film morphology, thickness uniformity, and nanostructure characteristics. SEM imaging supports film architecture claims and supports verification of uniform nano-scale film architecture.
Photon Efficiency Characterization
Quantum yield and photon efficiency measurements characterize the rate of ROS generation relative to UV input in Titan formulations. These characterize the photocatalytic pathway's intrinsic activity — and helps quantify Titan’s photocatalytic activity under UV input.
Decision Reference
Pathway Selection by Environment
The table below provides a structured decision reference for engineering leads and procurement specialists evaluating Quartz versus Titan for specific site conditions. Recommendations are mechanism-driven and reflect the contamination profile, UV availability, and operating environment parameters discussed in preceding sections.
FAQ
Frequently Asked Technical Questions
The following questions address the most common points of technical clarification raised by engineering leads, procurement specialists, and asset owners evaluating SolarEX products. Answers are mechanism-led and framed without unsupported generalization.
What is the difference between easy-clean and active photocatalysis?
Easy-clean (passive) coatings reduce the adhesion energy of contaminants at the glass surface — making them easier to remove through rainfall or low-pressure rinse. Active photocatalytic coatings (such as Titan) generate reactive oxygen species under UV irradiance that chemically decompose organic contaminants before removal. These are mechanistically distinct responses: one prevents adhesion, the other breaks down the contaminant itself.
Does Titan work without UV?
No. Titan's photocatalytic mechanism requires UV irradiance to generate reactive oxygen species and activate superhydrophilic surface behavior. In the absence of sufficient UV — as in high-latitude or seasonally shaded installations — Titan's active mechanism will not operate as intended. Quartz is the appropriate specification in low-UV conditions.
Does Quartz require UV?
No. Quartz is a passive SiO₂ film. Its hydrophobic and oleophobic surface properties are established at the point of application and maintained without ongoing UV input. This makes Quartz suitable for any geographic or irradiance context where inorganic fouling is the primary contamination profile.
Do coatings replace maintenance?
No. Both Quartz and Titan reduce cleaning burden and frequency by modifying the adhesion and removal behavior of contaminants. They do not eliminate the requirement for periodic maintenance. O&M schedules should be reviewed and adjusted in the context of coating deployment — not discontinued.
Does thicker coating improve performance?
Not necessarily. Film performance is determined by chemistry, uniformity, and surface preparation — not by film thickness beyond the functional specification range. Excessive film thickness may introduce optical penalty without functional benefit. Application should follow recommended coverage protocols.

SolarEX — Surface Engineering for Photovoltaic Glass
Platform