Automotive Solar Heat Control

Kriya ATO (antimony tin oxide) nanoparticles block near-infrared solar radiation while maintaining full visible transparency. The result: cooler cabins, lower AC loads, extended EV range, and reduced CO2 penalties.

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-9°CCabin temperature reduction

35%AC power reduction

16 kmEV range extension (premium segment)

<0.3%Haze (Tier-1 validated)

Where Kriya sits in the automotive glazing stack

Automotive glazing is a laminated structure: two sheets of glass bonded by a polyvinyl butyral (PVB) interlayer. In a solar heat control configuration, NIR-absorbing nanoparticles are embedded in the PVB interlayer, applied as a film on the glass inner surface, or coated directly via sol-gel.

Kriya’s ATO nanoparticles absorb near-infrared radiation — the portion of sunlight that heats the cabin — while transmitting visible light and maintaining full transparency to 5G, RF, and LiDAR signals.

Solar radiation reaching a vehicle interior comprises roughly 53% near-infrared (780–2500 nm), 44% visible (380–780 nm), and 3% ultraviolet. NIR-selective absorbers block the heat-carrying wavelengths while preserving cabin aesthetics and visibility.

Automotive laminated windshield cross-section with Kriya ATO in PVB interlayer. NIR blocked, visible light transmitted.

Automotive laminated windshield cross-section with Kriya ATO in PVB interlayer. NIR blocked, visible light transmitted.
Layer	Refractive index	Kriya material	Product
Exterior (air)		No	N/A
Windshield outer glass	1.52	No	N/A
PVB interlayer + ATO nanoparticles		Yes	KM-701
Windshield inner glass	1.52	No	N/A
Interior (cabin)		No	N/A

The bottom-up synthesis advantage

Kriya synthesises ATO from atoms up through proprietary chemistry. Most competitors ball-mill bulk ATO down to nano size (top-down). This top-down approach produces irregular particle shapes and broad size distributions. The measured consequence:

Haze of 0.2–0.3% validated by a Tier-1 PVB interlayer partner in lamination trials with 2.0 mm green glass — the only samples passing the partner’s automotive-grade haze threshold.

Haze after lamination

0.2–0.3%

vs >1.7% (competitor)

Effectiveness at equal SHGC vs incumbent Japanese supplier

vs 1x (baseline) (competitor)

Cost vs incumbent Japanese supplier

~60%

vs Comparable to ITO (competitor)

5G/RF/LiDAR transparency

100%

vs 100% (competitor)

Haze below 0.3% meets automotive-grade optical clarity. Haze above 1.7% does not. This is the critical threshold that bottom-up synthesis crosses and top-down milling cannot.

Three delivery systems

PVB masterbatch

ATO nanoparticles pre-dispersed in PVB-compatible masterbatch for direct addition during interlayer extrusion. The mass-market pathway — the interlayer manufacturer adds Kriya’s masterbatch to their existing process. Zero CAPEX at the customer plant.

ValidatedTier-1 PVB interlayer partner

Window film

ATO-loaded film applied to glass surfaces. Suitable for aftermarket retrofits and fleet upgrades. Enables solar heat control without changes to the OEM glazing supply chain.

RetrofitNo OEM supply chain change

Sol-gel direct coating

ATO nanoparticles deposited directly on glass via sol-gel. The lightest integration — no additional layer mass. Suitable for weight-sensitive applications and lightweight vehicle architectures.

LightweightZero added mass

Quantified impact: Calculation Model 887

Validated against Grundstein et al. field measurements (r² = 0.999). Reference conditions: 28 °C ambient, 600 W/m² solar radiation.

Cabin thermal performance

Interior temperature (AC off, baseline)58.9 °C

Interior temperature reduction-9 °C

NIR blocked250 W/m²

AC power (baseline)1.44 kW

AC power (with Kriya ATO)0.93 kW

AC power reduction35%

Total solar transmittance41%

EV range extension

Premium EV segment

+16km range extension

8.5kg battery saving

Avg 85.6 kWh battery, 442 km WLTP. Battery saving ~EUR 325.

Compact EV segment

+7km range extension

4.6kg battery saving

Avg 39.3 kWh battery, 227 km WLTP. Battery saving ~EUR 159.

Model your fleet impact

EU CO₂ penalty context

EU Regulation 2019/631 (amended by 2023/851) imposes penalties of EUR 95 per g CO₂/km per vehicle above the fleet-average target.* Industry-wide penalty exposure is estimated at up to EUR 16 billion** under the 2025 targets (according to ACEA and Transport & Environment analyses). For volume manufacturers registering 800,000 or more vehicles in the EU, every single gram of fleet-average reduction avoids approximately EUR 76 million*** in annual penalties.

The EU Commission has granted a 3-year compliance averaging window (2025–2027), allowing penalties to be calculated on average fleet performance across the period. However, this does not reduce total exposure — it spreads the financial impact but does not eliminate it. OEMs that remain above target throughout 2025–2027 face the same cumulative penalties. By 2030, with the target dropping to 49.5 g/km (−55% vs 2021), even hybrid-heavy fleets cannot comply without every available efficiency measure.

Period	Target	Reduction vs 2021
2025–2029	93.6 g CO₂/km	-15%
2030–2034	49.5 g CO₂/km	-55%
2035+	0 g CO₂/km	-100%

Penalty scale

Illustrative exposure for a major OEM fleet (approximately 800,000 EU registrations):

2025 scenario

Fleet avg ~105 g/km, target 93.6 g/km, gap ~11 g/km

~EUR 836M

2030 scenario

Fleet avg ~80 g/km, target 49.5 g/km, gap ~30 g/km

~EUR 2.28B

Rule of thumb: every 1 g/km fleet-average reduction over 800,000 vehicles avoids approximately EUR 76 million in penalties.

Illustrative figures based on published 2023-2024 fleet trajectories and EU regulation parameters. Actual penalties depend on full fleet composition, pooling, and manufacturer-specific targets.

Eco-innovation credit pathway

EU Regulation 2019/631 Article 12 allows manufacturers to claim eco-innovation credits for technologies that reduce real-world CO₂ emissions but are not captured by the WLTP test cycle. Since WLTP is run with AC off, AC efficiency improvements from solar control glazing are invisible to type-approval — making them eligible.

Preliminary estimates suggest 2–4 g/km credit potential for solar control glazing.**** At 800,000 vehicles, a 2 g/km credit translates to EUR 152 million in avoided penalties annually per manufacturer.

Previously approved eco-innovations include efficient mobile air conditioning systems and solar-powered ventilation — directly analogous to ATO solar control glazing. Maximum credit available: up to 7 g/km per vehicle until 2029.****

Application pathway

Define test methodologyStandardized solar load, cabin thermal model, AC system reference

Demonstrate real-world benefitShow CO₂ savings not captured by WLTP (AC off during test)

Quantify g/km creditEnergy savings x fuel/electricity conversion factor

Submit to European CommissionFull technical dossier; typical 12–18 month approval

OEM adoptionOnce approved, any OEM using the technology can claim the credit

NIR performance data

250W/m²NIR blocked (reference config)

64.4%VLT at 515 nm

1.8%NIR transmission at 1400 nm

0.2–0.7SHGC range (tuneable)

Sources & disclaimers

* EUR 95/g CO₂/km penalty — Source: EU Regulation 2019/631.
** Up to EUR 16B industry-wide exposure — Source: ACEA / Transport & Environment analysis.
*** EUR 76M avoided per 1 g/km — Based upon Calculation Model 887.
**** 2-4 g/km eco-innovation credit, up to 7 g/km max until 2029 — Source: EU Regulation 2019/631, Article 12.
Cabin temperature reduction, AC power reduction, EUR 76M avoided, and EUR 16B exposure figures are based upon Calculation Model 887.

Interested in ATO for your vehicle platform?

Our automotive team can provide application-specific data, lamination samples, and access to Calculation Model 887.

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