MLG1005S6N8HT000

TDK Corporation

FIXED IND 6.8NH 600MA 250MOHM SM

123954 Pcs New Original In Stock

6.8 nH Unshielded Multilayer Inductor 600 mA 250mOhm Max 0402 (1005 Metric)

Request Quote (Ships tomorrow)

*Quantity
Minimum 1

5.0 / 5.0 - (238 Ratings)

MLG1005S6N8HT000

Name: TDK Corporation MLG1005S6N8HT000
Brand: TDK Corporation
SKU: MLG1005S6N8HT000
Price: 0.0074 USD
Availability: InStock
Rating: 5.0 (238 reviews)

Product Overview

6647415

DiGi Electronics Part Number

MLG1005S6N8HT000-DG

Manufacturer

TDK Corporation

Manufacturer Product Number MLG1005S6N8HT000

Description

FIXED IND 6.8NH 600MA 250MOHM SM

Inventory

123954 Pcs New Original In Stock

Detailed Description 6.8 nH Unshielded Multilayer Inductor 600 mA 250mOhm Max 0402 (1005 Metric)

See all Fixed Inductors

Datasheet MLG1005S6N8HT000 Datasheet

Quantity
Minimum 1

Purchase and inquiry

Quality Assurance

365 - Day Quality Guarantee - Every part fully backed.

90 - Day Refund or Exchange - Defective parts? No hassle.

Limited Stock, Order Now - Get reliable parts without worry.

Global Shipping & Secure Packaging

Worldwide Delivery in 3-5 Business Days

100% ESD Anti-Static Packaging

Real-Time Tracking for Every Order

Secure & Flexible Payment

Credit Card, VISA, MasterCard, PayPal, Western Union, Telegraphic Transfer(T/T) and more

All payments encrypted for security

RFQ (Request for Quotations)

Submit your RFQ directly on the product detail page or the RFQ page.

Our sales team will respond within 24 hours.

Payment method

PayPal (recommended for new customers)

Credit Cards

Wire Transfer (T/T) – Available in USD, EUR, HKD, and other currencies.

Important Notice

You’ll receive a confirmation email after submitting an RFQ.

Didn’t get it? Check your spam folder and whitelist [email protected].

Prices and stock may change; we’ll reconfirm your order.

Questions? Contact us anytime.

Freight

Basic cost: USD 70.00

Actual cost may vary depending on weight and destination

Shipping method

Shipped from Hong Kong via FedEx/DHL/UPS/TNT

Delivery Time

In-stock items: Ready to ship in 1-2 days

Transit time: 3-5 business days (FedEx/DHL/UPS)

Special requests? Contact us: [email protected]

In Stock (All prices are in USD)

QTY Target Price Total Price
100 0.0074 0.7400
1000 0.0058 5.8000
3000 0.0050 15.0000
10000 0.0044 44.0000
50000 0.0041 205.0000
100000 0.0038 380.0000

Better Price by Online RFQ.

Request Quote (Ships tomorrow)

* Quantity
Minimum 1

Company

Contact Name

Phone

E-mail

Delivery Address

Message

(*) is mandatory

We'll get back to you within 24 hours

MLG1005S6N8HT000 Technical Specifications

Datasheet & Documents

Datasheets

Download MLG1005S6N8HT000 Product Specification (PDF)

HTML Datasheet

MLG1005S6N8HT000-DG

Environmental & Export Classification

RoHS Status ROHS3 Compliant

Moisture Sensitivity Level (MSL) 1 (Unlimited)

REACH Status REACH Unaffected

ECCN EAR99

HTSUS 8504.50.8000

Additional Information

Other Names

445-181366-1

445-181366-2

MLG1005S6N8HT000-DG

Standard Package

10,000

Alternative Parts

PART NUMBER

MANUFACTURER

QUANTITY AVAILABLE

DiGi PART NUMBER

UNIT PRICE

SUBSTITUTE TYPE

MLK1005S6N8DT000

TDK Corporation

10094

MLK1005S6N8DT000-DG

0.0038

MFR Recommended

ELJ-RF6N8ZFB

Panasonic Electronic Components

1298

ELJ-RF6N8ZFB-DG

0.0038

Similar

Reviews

5.0/5.0-(Show up to 5 Ratings)

푸***하늘

Dec 02, 2025

5.0

친환경 포장과 저렴한 가격이 정말 마음에 들어요.

桜***節

Dec 02, 2025

5.0

商品がすぐに届き、その品質も期待以上でした。とても満足しています！

Drea***aser

Dec 02, 2025

5.0

The products feel solid and well-engineered; I appreciate their long-lasting quality, even after heavy use.

Sou***rout

Dec 02, 2025

5.0

The packaging is environmentally friendly and arrived in excellent condition thanks to their efficient shipping.

Silen***isper

Dec 02, 2025

5.0

First-time shopping here was a great experience thanks to their professionalism.

Publish Evalution

* Product Rating

(Normal/Preferably/Outstanding, default 5 stars)

★ ★ ★ ★ ★

* Evalution Message

Please enter your review message.

Please post honest comments and do not post ilegal comments.

Frequently Asked Questions (FAQ)

When designing a high-frequency RF filter, what are the potential practical risks of using the TDK MLG1005S6N8HT000 6.8 nH inductor if my target impedance matching requires precise tuning at 2.4 GHz?

The primary risk with the TDK MLG1005S6N8HT000 at 2.4 GHz lies in its Self-Resonant Frequency (SRF) of 3.5 GHz. While seemingly above your operating frequency, parasitic capacitances can cause the inductor to behave capacitively before reaching its SRF, especially with trace inductance and other components. This can lead to unexpected impedance shifts and detuning. To mitigate this, ensure your layout minimizes parasitic capacitance and consider simulating the MLG1005S6N8HT000 within your full circuit model to verify its performance margin at 2.4 GHz. If borderline, a higher SRF inductor might be necessary for robust impedance matching.

How can I be confident that the TDK MLG1005S6N8HT000 is a suitable replacement for an older, unspecified 6.8 nH chip inductor in a noisy DC-DC converter output filter, considering potential power derating issues?

Replacing an unspecified inductor with the TDK MLG1005S6N8HT000 requires careful consideration of its current handling and thermal performance. While the MLG1005S6N8HT000 has a 600 mA rating, its 250 mOhm DC resistance (DCR) will generate heat. If the original inductor had a significantly lower DCR or was rated for higher current, the MLG1005S6N8HT000 might experience excessive heating and premature failure under load. To ensure suitability, measure the actual current draw of your DC-DC converter's output filter and calculate the power dissipation (I² * DCR) for the MLG1005S6N8HT000. If this dissipation results in a temperature rise exceeding the component's operating limits or your system's thermal budget, a lower DCR inductor is required, even if inductance and current rating appear similar.

What are the key design uncertainties when integrating the TDK MLG1005S6N8HT000 into a miniaturized IoT device's RF front-end operating near its 600 mA current limit, especially regarding signal integrity?

The main uncertainty when pushing the TDK MLG1005S6N8HT000 near its 600 mA current limit in an IoT RF front-end is the impact on signal integrity due to self-heating and potential saturation effects (though saturation is not explicitly detailed, it's a general inductor concern). Even with a 600 mA rating, sustained operation at or near this limit can cause a temperature rise, potentially altering the inductor's inductance value (though typically minor for ceramic cores) and increasing its DCR. More critically, if the peak RF current approaches the unspecified saturation current (Isat), the inductance will drop significantly, leading to impedance mismatch and signal distortion. It's crucial to confirm the peak RF current your device will encounter and ensure it's well below the effective saturation point of the MLG1005S6N8HT000, potentially requiring over-specifying the inductor or implementing current limiting.

I'm considering using the TDK MLG1005S6N8HT000 (6.8 nH, 600mA) to replace a competing 0402 inductor, perhaps an onsemi CL05C6N8DB5NNN (also 6.8 nH, 500mA). What practical trade-offs should I evaluate for reliability and performance in a mobile application?

When comparing the TDK MLG1005S6N8HT000 to a competitor like the onsemi CL05C6N8DB5NNN, the key trade-off lies in current handling and potential reliability differences. The MLG1005S6N8HT000 offers a higher 600 mA rating versus the CL05C6N8DB5NNN's 500 mA, which could be beneficial if your application experiences transient current spikes. However, you must investigate the DCR of both components. If the MLG1005S6N8HT000 has a higher DCR, it will dissipate more power at the same current, potentially leading to higher operating temperatures and reduced long-term reliability, especially in a constrained mobile environment. Also, compare their Q factor at your operating frequency; a higher Q generally indicates lower losses and better performance. Ensure the operating temperature range and MSL rating of both are suitable for your mobile application's environmental conditions.

What are the potential pitfalls and design considerations when using the TDK MLG1005S6N8HT000 in a multi-layer ceramic bypass filter circuit where stable performance across a wide temperature range (-55°C to 125°C) is critical?

The main design consideration when using the TDK MLG1005S6N8HT000 in a demanding temperature range for a bypass filter is the stability of its inductance and DCR. While the ceramic, non-magnetic core offers good temperature characteristics compared to some other materials, it's not entirely immune to variation. As temperatures fluctuate from -55°C to 125°C, the inductance of the MLG1005S6N8HT000 can drift slightly, and its DCR will change (typically increasing with temperature). For applications requiring extremely tight impedance control across the entire operating temperature, it's essential to characterize the inductor's performance at the temperature extremes. You might need to incorporate wider tolerance components or active compensation circuits if the MLG1005S6N8HT000's inherent variation proves detrimental to your bypass filter's effectiveness.

Quality Assurance (QC)

DiGi ensures the quality and authenticity of every electronic component through professional inspections and batch sampling, guaranteeing reliable sourcing, stable performance, and compliance with technical specifications, helping customers reduce supply chain risks and confidently use components in production.

Quality Assurance