𑄽     bi𖹭s    ✿     𝑓lowers    ૮

✿۟     𝓡𝗈𝗌ᧉ      ๑      𝖻ᧉ𝖽     !

ꮽ       𝒇𝖺𝗅𝗅𝗂𝗇𝗀      ✿𝆬       𝐩𝐞𝐭𝐚𝐥𝐬    

⸙    𝔉lowers     𝒘𝒊𝒕𝒉     thorns     !   

𝓑𝗈𝗍𝖺𝗇𝗂𝖼𝖺𝗅       ❀      𝙶𝙰𝚁𝙳𝙴𝙽    ꒰  𝟷𝟿𝟿𝟾 ꒱

 

✽    𝗌𝗁𝖾   ꒰ 𝐫𝐞𝐦𝐢𝐧𝐝𝐬 ꒱  𝗆𝖾   𝐨𝐟   𝖺   𝒇𝗅𝗈᪲𝗐𝖾𝗋   .

̵✿  :  𝗌𝗁𝖾  𝗂𝗌  𝐥𝐢𝐤𝐞  𝖺  𝑓𝗅𝗈𝗐𝖾𝗋  𝖺𝗇𝖽  𝗇𝖾𝖾𝖽𝗌  𝗍𖹭  𝖻𝖾  𝐰𝐚𝐭𝐞𝐫𝐞𝐝  ꮽ

❀     𝗍𝗁𝖾   𝑓𝗅𝗈𝗐𝖾𝗋   𝗂𝗇   𝗆𝗒   𝐠𝐚𝐫𝐝𝐞𝐧,   𝗍𝗁𝖾   𝗆𝗈𝗌𝗍   𝖻𝖾𝖺𝗎𝗍𝗂𝖿𝗎𝗅   𝗋𝗈𝗌𝖾   ⪨  

✿    𝒯𝖺𝗄𝖾  𝖼𝖺𝗋𝖾  𝗈𝖿  𝗆𝖾  𝐚𝐧𝐝  𝗒𝗈𝗎  𝗐𝗂𝗅𝗅  𝗌𝖾𝖾  𝖺  𝑏𝑒𝑎𝑢𝑡𝑖𝑓𝑢𝑙  𝑔𝑎𝑟𝑑𝑒𝑛 .

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Uncover BIOSTAR’s BIQ67-AHP Motherboard Magic

BIOSTAR’s BIQ67-AHP Motherboard Specifications

BIOSTAR, a leading manufacturer of motherboards, graphics cards, and storage devices, proudly introduces the BIQ67-AHP industrial motherboard, designed for system integration in industrial and business applications. This robust and efficient motherboard manages and streamlines complex processes and operations.

Performance is driven by the BIQ67-AHP’s compatibility with the Intel Core i7/i5/i3 processor (LGA1700), Intel Q670 chipset, and 125 W Thermal Design Power (TDP). The BIQ67-AHP can readily handle demanding industrial and corporate applications because to its strong configuration. With four DDR4 3200 MHz LONG-DIMM slots, the BIQ67-AHP’s large capacity memory support improves system stability and data reliability, making it the perfect choice for applications where data integrity and continuous operation are essential.

A wide range of audiences in the business and industrial sectors have different needs, and the BIQ67-AHP is made to accommodate them. For firms engaged in System Integration (SI), it is the perfect choice because it offers all the capabilities required for effectively managing client data, transaction histories, and general business operations. The BIQ67-AHP provides necessary slots and connections for simple integration of communication modules for those wishing to construct AIOT devices. For AI processing, it supports GPUs or accelerators.

It offers interoperability with a range of processors and connectivity options for peripherals, catering to those interested in building Automation machines, Edge Computing devices, and Human-Machine Interface (HMI) systems respectively. With its support for numerous operating systems, hardware expansion, durability, and stability, the BIQ67-AHP is also an ideal choice for enthusiasts of digital signage. The BIQ67-AHP is an adaptable platform that improves automation accuracy and operational efficiency by integrating smoothly into a range of industrial setups.

Numerous features and functionalities of the BIQ67-AHP are designed to provide excellent performance and versatility in industrial applications. For consumers with different visual output needs, it has VGA, 2x HDMI 2.0, and one DP++. Four USB2.0 and eight USB3.2 ports on the motherboard allow for device communication. The serial ports are 4x RS232 and 2x RS232/422/485. Storage solutions have 8x SATA III connections and M.2 sockets for PCIe Gen 4 x4, 5G, and WIFI/BT. Two PCIE x16, three PCIE x4, and two PCI slots allow for expansion on the motherboard. The BIQ67-AHP is a rugged industrial solution powered by an ATX power input and operating in a wide temperature range of 0 to 60 degrees Celsius.

The BIQ67-AHP is a brazen declaration of BIOSTAR’s dedication to quality and innovation in industrial computing. The BIQ67-AHP is ready to raise the bar for industrial performance and system integration thanks to its powerful design and sophisticated features. In addition to meeting the demands of today’s dynamic industrial environments, BIOSTAR extends an invitation to enterprises and industrial operators to experience the BIQ67-AHP motherboard’s revolutionary potential. This motherboard also lays the way for future breakthroughs in the system integration industry.

Read more on Govindhtech.com

BIOSTAR presenta la combinación definitiva para gaming: AMD Radeon RX 7700 XT y Placa Base B650MT

BIOSTAR, un renombrado fabricante de placas base, tarjetas gráficas y dispositivos de almacenamiento, anuncia una potente combinación para gaming que incluye la tarjeta gráfica AMD Radeon RX 7700 XT y la placa base B650MT. Esta dupla ofrece una experiencia de entretenimiento en casa de primera categoría para jugadores casuales y entusiastas de gama media. La […]

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How to Transition from Biotechnology to Bioinformatics: A Step-by-Step Guide

Biotechnology and bioinformatics are closely linked fields, but shifting from a wet lab environment to a computational approach requires strategic planning. Whether you are a student or a professional looking to make the transition, this guide will provide a step-by-step roadmap to help you navigate the shift from biotechnology to bioinformatics.

Why Transition from Biotechnology to Bioinformatics?

Bioinformatics is revolutionizing life sciences by integrating biological data with computational tools to uncover insights in genomics, proteomics, and drug discovery. The field offers diverse career opportunities in research, pharmaceuticals, healthcare, and AI-driven biological data analysis.

If you are skilled in laboratory techniques but wish to expand your expertise into data-driven biological research, bioinformatics is a rewarding career choice.

Step-by-Step Guide to Transition from Biotechnology to Bioinformatics

Step 1: Understand the Basics of Bioinformatics

Before making the switch, it’s crucial to gain a foundational understanding of bioinformatics. Here are key areas to explore:

Biological Databases – Learn about major databases like GenBank, UniProt, and Ensembl.

Genomics and Proteomics – Understand how computational methods analyze genes and proteins.

Sequence Analysis – Familiarize yourself with tools like BLAST, Clustal Omega, and FASTA.

🔹 Recommended Resources:

Online courses on Coursera, edX, or Khan Academy

Books like Bioinformatics for Dummies or Understanding Bioinformatics

Websites like NCBI, EMBL-EBI, and Expasy

Step 2: Develop Computational and Programming Skills

Bioinformatics heavily relies on coding and data analysis. You should start learning:

Python – Widely used in bioinformatics for data manipulation and analysis.

R – Great for statistical computing and visualization in genomics.

Linux/Unix – Basic command-line skills are essential for working with large datasets.

SQL – Useful for querying biological databases.

🔹 Recommended Online Courses:

Python for Bioinformatics (Udemy, DataCamp)

R for Genomics (HarvardX)

Linux Command Line Basics (Codecademy)

Step 3: Learn Bioinformatics Tools and Software

To become proficient in bioinformatics, you should practice using industry-standard tools:

Bioconductor – R-based tool for genomic data analysis.

Biopython – A powerful Python library for handling biological data.

GROMACS – Molecular dynamics simulation tool.

Rosetta – Protein modeling software.

🔹 How to Learn?

Join open-source projects on GitHub

Take part in hackathons or bioinformatics challenges on Kaggle

Explore free platforms like Galaxy Project for hands-on experience

Step 4: Work on Bioinformatics Projects

Practical experience is key. Start working on small projects such as:

✅ Analyzing gene sequences from NCBI databases ✅ Predicting protein structures using AlphaFold ✅ Visualizing genomic variations using R and Python

You can find datasets on:

NCBI GEO

1000 Genomes Project

TCGA (The Cancer Genome Atlas)

Create a GitHub portfolio to showcase your bioinformatics projects, as employers value practical work over theoretical knowledge.

Step 5: Gain Hands-on Experience with Internships

Many organizations and research institutes offer bioinformatics internships. Check opportunities at:

NCBI, EMBL-EBI, NIH (government research institutes)

Biotech and pharma companies (Roche, Pfizer, Illumina)

Academic research labs (Look for university-funded projects)

💡 Pro Tip: Join online bioinformatics communities like Biostars, Reddit r/bioinformatics, and SEQanswers to network and find opportunities.

Step 6: Earn a Certification or Higher Education

If you want to strengthen your credentials, consider:

🎓 Bioinformatics Certifications:

Coursera – Genomic Data Science (Johns Hopkins University)

edX – Bioinformatics MicroMasters (UMGC)

EMBO – Bioinformatics training courses

🎓 Master’s in Bioinformatics (optional but beneficial)

Top universities include Harvard, Stanford, ETH Zurich, University of Toronto

Step 7: Apply for Bioinformatics Jobs

Once you have gained enough skills and experience, start applying for bioinformatics roles such as:

Bioinformatics Analyst

Computational Biologist

Genomics Data Scientist

Machine Learning Scientist (Biotech)

💡 Where to Find Jobs?

LinkedIn, Indeed, Glassdoor

Biotech job boards (BioSpace, Science Careers)

Company career pages (Illumina, Thermo Fisher)

Final Thoughts

Transitioning from biotechnology to bioinformatics requires effort, but with the right skills and dedication, it is entirely achievable. Start with fundamental knowledge, build computational skills, and work on projects to gain practical experience.

Are you ready to make the switch? 🚀 Start today by exploring free online courses and practicing with real-world datasets!

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BIOSTAR introduces new AI-NONXS Developer Kit that augments edge AI applications for modern deployment

BIOSTAR has just rolled out its AI-NONXS Developer Kit, a powerful edge AI platform designed for developers and system integrators looking to build and deploy AI-driven solutions at the edge. Supporting NVIDIA Jetson Orin NX and Orin Nano modules, this compact industrial-grade kit is aimed squarely at enabling next-gen AI capabilities in sectors like smart manufacturing, retail, transportation,…

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BIOSTAR Redefines the Future of Edge AI, Smart Solutions, and Gaming Tech in 2025

BIOSTAR, a leading manufacturer of motherboards, graphics cards, storage devices, and IPC solutions, continues to push boundaries in the tech space. NCN Magazine caught up with Mr. Kevin Cheng, Marketing Manager, BIOSTAR, for an exclusive look at their 2025 lineup—featuring edge AI, industrial solutions, motherboards, and gaming hardware—designed to deliver top-tier performance, reliability, and affordability.

Biostar A770E3 emaplaat

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❀  ノ   あな   𝗒𝗈𝗎   𝗀𝖺𝗏𝖾   𝗆𝖾   𝖻𝖺𝖼𝗄   𝗆𝗒   𝗁𝖺𝗉𝗉𝗂𝗇𝖾𝗌𝗌   𝖺𝗇𝖽   𝗍𝗁𝖾𝗇   𝗒𝗈𝗎   𝗅𝖾𝖿𝗍.

𝗇𝖺  𝗇𝗈𝗂𝗍𝖾  𝖾𝗅𝖺  𝖾𝗌𝗍𝖺́  𝖽𝖺𝗇𝖼̧𝖺𝖽𝗈  𝗉𝖺𝗋𝖺  𝖺𝗅𝗂𝗏𝗂𝖺𝗋  𝖺  𝖽𝗈𝗋   ─  𝐢𝐧   𝐭𝐡𝐞   𝐧𝐢𝐠𝐡𝐭    ✦

ノ     𝗍𝗈𝖽𝖺𝗒   𝗐𝖾   𝗍𝗐𝗈   𝗐𝗂𝗅𝗅   𝖻𝖾   𝗈𝗇𝖾   𝑤.    무한    ✿

𝗂   𝗐𝗂𝗌𝗁   𝗂   𝐥𝐨𝐯𝐞𝐝   𝗒𝗈𝗎   𝗈𝗇   𝖺   𝐥𝐨𝐧𝐞𝐥𝐲   𝗇𝗂𝗀𝗁𝗍   .   ☾

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(LAST UPDATED: 21/10/23)

So, this is an absolutely excellent and mostly correct post when it comes to buying systems from what are known as Original Equipment Manufacturers (OEMs) or System Integrators (SIs). Some lesser known SIs that still do good work, though which will likely also be far more expensive, are Falcon Northwest and Puget Systems. For mini PCs (the kind that ms-demeanour up there mentioned mounting behind monitors), Minisforum has a broad and high quality portfolio, as do Beelink, ASRock, and Asus.

Some points I disagree with on this post: Ryzen 5 is perfectly fine for most people who aren't doing AI, ProViz, or CAD work (and if you don't know what those words mean then you probably don't need a Ryzen 7 or 9). As for generations, look for at least Ryzen 2000, ideally 3000 or above. For Intel generations, I would say to try to avoid anything older than 12th Gen, as that generation brought some absolutely massive performance and efficiency improvements, and was preceded by a good few dud gens. Also, 13th Gen and onwards i3s are shockingly powerful, and will do a good turn for a lot of use cases. FOR LAPTOPS ONLY 14th Gen releasing in December might potentially blow all the other advice here out of the water, so if you can afford to wait you probably should.

With all that said, what if none of the SIs have what you need? What if you wanna build your own system to save a buck? Here's some advice if you're in the "building my own PC for the first time" boat.

Part 1: What You Need

If you're building your own computer, it will have to be a desktop. Laptops are built to dance on a razor's edge of not fucking burning down sobbing (unless you're Apple in which case you slip on a banana peel, faceplant on the pavement, and then explode), and you cannot build your own from scratch for reasons which are beyond the scope of this post.

So, while building your own desktop, what exactly do you need?

Components:

Motherboard

Power Supply

CPU

RAM

Storage

Graphics Card

Case

Tools:

1x Phillips Head Screwdriver

A Dream

Part 2: What You Want

Before we start looking for parts, you need to first decide what exactly it is you'll be using the system for. If you're reading this post right now you're either one of my poor hapless mutuals that I just slammed this onto the dash of (I apologize but not sincerely), or you're not the most caught up to current Gen hardware. Assuming the latter case, I'm also going to assume you're not a homelabber or data scientist (but if you are and need help with speccing a workstation system reblog this and I will happily discuss those cases at length).

With that in mind, here's some advice for two fairly common use cases.

Use Case 1: New Reliable

So your parent/child/friend/elderly relative's old shitbox finally gave up the ghost, and now they need something to replace it. This advice is for systems that you want to build once, take apart never. You want this system to last with zero maintenance for the next five to ten years, at which point you will be upgrading it again anyway. This system is not going to be doing much gaming or heavy professional work, but as an Internet browsing machine with some occasional Minecraft and Fortnite this thing will be more than sufficient.

Motherboard: Get the cheapest one with okay reviews on PC Part Picker. ASRock is a safe bet, as is Asus and potentially MSI. Biostar tends to cheap out on quality, but the retail price generally reflects that, similar for Maxsun. Do not spend more than 100 dollars on the motherboard. You do not need anything more advanced than the bare minimum. For Intel systems, look for something with H610 or H610M in the name. For AMD Ryzen systems, look for something with A320 in the name.

Power Supply: NEVER EVER EVER CHEAP OUT ON THE FUCKING POWER SUPPLY, EVER. A bad power supply can kill the rest of your system when it goes. That said, there are still lots of options that are trash, while not being hazardous. Among these the champ is, of course, the Thermaltake Smart lineup of power supplies. They suck poopy ass, but they aren't going to burn your fucking house down or anything. If you've got the budget though, spring for something from EVGA, Silverstone, or Seasonic. For wattages, something 500-650W should be fine for a system like this, and still leaves room for a minor GPU installation down the line should one be desired (though nothing with a high power draw). The extra headroom also helps manage transient spikes in power draw, which are fairly commonplace on modern processors.

CPU: Get a Core i3-13100 or a Ryzen 3 3200G. I could give advice on how to shop for CPUs for a system like this, but I feel it's more helpful to just tell you the specific thing you're gonna want for this usecase, since this part of the product stack is generally pretty barren from both manufacturers.

RAM: Get a 2x8 gigabyte kit. Do not get two separate 8 gig sticks or one 16 gig one. Make sure you are getting the right *type* of memory (for the motherboards and CPUs described here, that is DDR4). Get the cheapest kit you can find. Casual Internet browsing is not going to be feeling bone hurt from shitty slow RAM.

Graphics Card: Don't bother. For a system like this, a graphics card is just one more thing that can break down and fail (since fans gradually wear out over time and eventually need to be replaced). The integrated graphics on the above CPUs will be more than sufficient for day to day use. However, if you do need or want a graphics card, do *not* get anything from Nvidia in the 30 tier (i.e GT 730, GT 1030, or GTX 1630), or anything from AMD below the "600" tier (RX 550, RX 5500, RX 6400, et cetera). From Intel, anything above an A380 is more than sufficient. The A580 is an especially tempting value proposition if you're buying new, but if you're okay with used and refurbished cards you can get an RX 580 for less than 100 USD, and it is still very much a card worth your consideration.

Case: Get something cheap, but not too cheap. Anything from Cooler Master's MasterBox lineup should be perfectly sufficient. Built-in case fans suck poopy ass. Replace them. More on cooling in a sidebar later in the post.

With a system built on the above specs, internet browsing, Zoom calls, sending emails, typing up Word documents, and spreadsheets that deal with anything less than the net accounts of a multimillion dollar corporation should be handled without breaking a sweat, as well as some light gaming like Minecraft or Fortnite, though don't expect it to be smoking Starfield at max settings. Then again, nothing can really run Starfield at max settings because it's such an unoptimized piece of shit, but I digress.

Use Case 2: Budget Bruiser

A whole lot of power in a very cramped budget. The real "most gamers still play at 1080p" build, this is going to be comfortable for a lot of people building their own because they can't afford the assembly surcharges of SI systems

Motherboard: Similar advice as New Reliable on this one. ASRock is good, don't spend more than 100 USD on this unless you absolutely cannot get the features you need otherwise. However, when you're not just looking for the bare minimum that works, there are some other things to keep an eye out for. For starters, rear I/O.

This is what a fairly "standard" rear I/O arrangement looks like. Bunch of USB-A Ports, one or two USB-C ports, audio, Ethernet, and some video outputs like HDMI and DVI. Combined with the USB ports on your case, these will be more than enough for pretty much everyone. Seriously, even with a mouse, keyboard, USB mic, flash drive, DAC, and pen tablet all plugged in simultaneously, I still don't run out of USB-A connectors, just on the motherboard, before accounting for the ones on my case or those added by a USB hub. Unless you need SPDIF or cleaner power delivery out of your USB ports for sensitive audio equipment or something else that just isn't available in the sub-100 dollar price segment, 80-90 dollar motherboards like the one pictured above (the ASRock B450M Pro4 R2.0, currently available for 78 dollars on Amazon) are the way to go.

Another crucial consideration when it comes to motherboards is the chipset. The sweetspot on price-to-performance is generally found in the B-series chipsets from both vendors (B450/B550/B650 from AMD, B460/B550/B660 from Intel). They provide more than the bare minimum of features, but unlike their X (for AMD) or Z (for Intel) series sisters, they won't bankrupt you. Finally, expansion:

The slots outlined in red are RAM slots. You will generally get at least two of these in any desktop motherboard, though you're going to want to get four for the extra capacity potential it affords you at a lower price compared to going for extremely high densities.

The other three slots are Peripheral Component Interconnect Express or PCIe slots. You will want at least one of the big ones, preferably more, and ideally one of the small ones. However, if you look closely and compare the slots highlighted in green and yellow, you will notice that the green one has "pins" all along the top of its length, while the yellow one only has a handful. You want a big slot with pins all the way down, as having fewer electrical connections means a slower slot that will reduce performance significantly.

Power Supply: ONCE AGAIN I CANNOT STATE ENOUGH THE IMPORTANCE OF NOT CHEAPING OUT ON YOUR PSU. For finding high quality PSUs that are efficient, quiet, and possess all the protections you need to make sure a power surge doesn't fry your system, Cybenetics' database of power supplies is an absolutely amazing resource. As for wattage, it depends on your CPU and graphics card, but generally something in the 850W-1000W range is probably safe so as to leave ample headroom for upgrading down the line.

CPU: Choosing a CPU and graphics card pairing is one of the most difficult and infuriating parts of any build. However, some general advice to make the process less painful is as follows: Firstly, aim for components within the same place in the product stack. A Core i9 with an RTX 3060 is going to result in the i9 spending most of its time twiddling its thumbs waiting for the 3060 to play catch-up. Given that we're aiming to not break the bank here, I'd recommend aiming in the Ryzen 5/Core i5 category, and getting something recent and modern. Good picks for this are the Ryzen 5 3600X, the Ryzen 5 5600, Ryzen 7 5700X (if you're lucky you can snag them shockingly cheap on sales), and Ryzen 5 7600 from the AMD side of the aisle. Intel's Core i5-12600KF spent a solid year as the uncontested price-to-performance dominator, and its newer siblings, the 13600KF and 14600KF, have both carried on that legacy admirably. Aiming for the 7 tier, the Ryzen 7 7700(X) is largely the same as its little sister, the 7600, and can be mostly safely ignored. The Core i7-14700K brings a noticeable amount of performance over the 13700K, but depending on pricing in your region the single-digit uplift might not be worth the extra cost.

RAM: Regarding capacity, 16 gigs is a good amount that'll handle most tasks without difficulty. When using DDR4 RAM, get two 8 gig sticks rather than 1 16 gig one to take advantage of dual channels. When using DDR5, one stick is fine, though it may be more expensive due to higher density. YMMV, choose according to your own circumstances. When it comes to speed, 3200 MT/s (NOT MHz, that is a LIE, and it makes me ANNOYED) is pretty much always a safe bet on DDR4. On DDR5, 6000 is the max that AMD can safely handle. Anything over that is playing with fire. Intel can in many cases handle 7200 without breaking a sweat.

Storage: 1 TB SSDs are extremely cheap now, you can get high speed NVMe ones for around 50 bucks. Do so. I would recommend something from Intel or Solidigm (same engineers, they just work for a different sticker now). If you want or need more storage, you can get dirt cheap SATA SSDs and HDDs, but they should generally not be used for storing games or other things that require high performance.

Graphics Card: And now, the part where I get egged off stage for being too right for people to handle. There are currently three major graphics card manufacturers, all of whom are worth consideration depending on your needs and your budget. Nvidia holds the performance crown, and never fails to remind us of this fact as it charges exorbitantly inflated prices for its products. Their current gen products are largely a waste of sand. However, their last generation, the RTX 30-series, is definitely worth considering, especially the RTX 3060 and 3060 Ti, if they can be found at a sub-300 dollar price point (though the Intel Arc A770 16GB does have them beat in many cases). AMD and Intel both bring compelling offerings to the table across the whole stack, with some highliths being the AMD Radeon RX 7600 and 7800 XT, and the Intel Arc A750 and A770 16GB.

Case: The case is going to be the part of your system you look at the most, so make it the one you like looking at the most. Fractal Design, Lian Li, and InWin all make excellent cases, as does Corsair. The Fractal Design North, Corsair 4000D Airflow, and Lian Li O11 Dynamic are all excellent cases, and if you can get me an In Win DUBILI I will eat you out.

Sidebar: Cooling

PC components give off heat, and that heat needs to be managed. This is a significant aspect of PC building, and I felt it deserved its own little heading rather than to just be lost in the sauce of the rest of the post. The main concerns with cooling are thermal transfer, airflow, and noise. Let's go through them one by one.

Thermal Transfer

This refers to taking heat from a heat-generating component, and moving it away from it. Graphics cards will already come with their own in-built cooling solution, and SSDs and stuff don't give off enough heat for it to be a serious concern for the most part. The main place where thermal transfer becomes a relevant concept is the CPU. We can move heat away from the CPU by using a CPU cooler. Many CPUs come with one in the box, but you can also buy a separate one. There are two main types of coolers, air, and liquid. Air coolers use large, dense aluminium finstacks which are exposed to a lot of moving air (discussed more in the section on airflow) to move heat away from the CPU and then away from the inside of the computer entirely assuming you can afford a decent thermal solution that has both intake and exhaust rather than just intake like I have at the moment please send help. Liquid coolers use thermally-conductive liquids like ethylene glycol, which come into indirect contact with the CPU through a copper coldplate before flowing up into a radiator, where dense aluminium finstacks get air blown through them to dissipate heat. Air coolers are generally cheaper and more reliable due to less moving parts (i.e none aside from the fans), but liquid coolers can oftentimes match them in price and performance while retaining similar sound profiles (more on that in a bit). However, neither type of cooler will perform to their fullest without the use of something known as a Thermal Interface Material, or TIM. The most common TIM is thermal paste, which is an electrically non-conductive gooey thing you put on your CPU before installing the cooler to fill the microscopic airgaps between the cooler's coldplate and the CPU, improving cooling performance significantly. However, thermal paste will dry out gradually, and lose performance. If you want something that won't need to be replaced every few years, try using something like Thermal Grizzly Kryosheet, which due to being a sheet of solid graphene rather than paste doesn't dry out ever.

Airflow

Airflow is the next major consideration for cooling. Congratulations, you got the heat away from the components! Now what. That hot air is now stagnating inside your case, driving up ambient temperature and making your components run far hotter than they should. To avoid such a fate, you need strong intake and exhaust airflow. For this purpose, we use fans mounted on and in the case, to move air from the outside, into the case, through the case, and then out of the case again. A lot of people on the Internet have very strong opinions about airflow, but honestly so long as your case isn't completely garbage, a few filtered (most cases nowadays come with magnetic dust filters) intakes and an exhaust should be more than sufficient to cool most modern components within acceptable margins.

Noise

Your components might run cool, but that's not of much use if the fans screech like banshees. The third and final consideration in your cooling solution is how loud and obnoxious it is going to be. The main culprit here is going to be fans, which, if impeded, will have to work doubletime to maintain temperatures, resulting in higher noise levels (though decent fans will manage this by making their sound profiles less SCREECHING BANSHEE and more of a hiss or a rumble, which isn't perceived as being as loud by human ears). However, the pumps in liquid coolers can also create an obnoxious whine if installed incorrectly, so make sure to look up the proper orientation for their installation to avoid such a fate, or to rectify it if it is already suffered.

I have no idea why I spent the past six or so hours writing this guide that no one is going to ever read but uh...I did! I might at some later point actually write up something on how to put a system together, but there's oodles of tutorials for that stuff on the Internet, so it's hardly needed.

So You Need To Buy A Computer But You Don't Know What Specs Are Good These Days

Hi.

This is literally my job.

Lots of people are buying computers for school right now or are replacing computers as their five-year-old college laptop craps out so here's the standard specs you should be looking for in a (windows) computer purchase in August 2023.

PROCESSOR

Intel i5 (no older than 10th Gen)

Ryzen 7

You can get away with a Ryzen 5 but an intel i3 should be an absolute last resort. You want at least an intel i5 or a Ryzen 7 processor. The current generation of intel processors is 13, but anything 10 or newer is perfectly fine. DO NOT get a higher performance line with an older generation; a 13th gen i5 is better than an 8th gen i7. (Unfortunately I don't know enough about ryzens to tell you which generation is the earliest you should get, but staying within 3 generations is a good rule of thumb)

RAM

8GB absolute minimum

If you don't have at least 8GB RAM on a modern computer it's going to be very, very slow. Ideally you want a computer with at least 16GB, and it's a good idea to get a computer that will let you add or swap RAM down the line (nearly all desktops will let you do this, for laptops you need to check the specs for Memory and see how many slots there are and how many slots are available; laptops with soldered RAM cannot have the memory upgraded - this is common in very slim laptops)

STORAGE

256GB SSD

Computers mostly come with SSDs these days; SSDs are faster than HDDs but typically have lower storage for the same price. That being said: SSDs are coming down in price and if you're installing your own drive you can easily upgrade the size for a low cost. Unfortunately that doesn't do anything for you for the initial purchase.

A lot of cheaper laptops will have a 128GB SSD and, because a lot of stuff is stored in the cloud these days, that can be functional. I still recommend getting a bit more storage than that because it's nice if you can store your music and documents and photos on your device instead of on the cloud. You want to be able to access your files even if you don't have internet access.

But don't get a computer with a big HDD instead of getting a computer with a small SSD. The difference in speed is noticeable.

SCREEN (laptop specific)

Personally I find that touchscreens have a negative impact on battery life and are easier to fuck up than standard screens. They are also harder to replace if they get broken. I do not recommend getting a touch screen unless you absolutely have to.

A lot of college students especially tend to look for the biggest laptop screen possible; don't do that. It's a pain in the ass to carry a 17" laptop around campus and with the way that everything is so thin these days it's easier to damage a 17" screen than a 14" screen.

On the other end of that: laptops with 13" screens tend to be very slim devices that are glued shut and impossible to work on or upgrade.

Your best bet (for both functionality and price) is either a 14" or a 15.6" screen. If you absolutely positively need to have a 10-key keyboard on your laptop, get the 15.6". If you need something portable more than you need 10-key, get a 14"

FORM FACTOR (desktop specific)

If you purchase an all-in-one desktop computer I will begin manifesting in your house physically. All-in-ones take away every advantage desktops have in terms of upgradeability and maintenance; they are expensive and difficult to repair and usually not worth the cost of disassembling to upgrade.

There are about four standard sizes of desktop PC: All-in-One (the size of a monitor with no other footprint), Tower (Big! probably at least two feet long in two directions), Small Form Factor Tower (Very moderate - about the size of a large shoebox), and Mini/Micro/Tiny (Small! about the size of a small hardcover book).

If you are concerned about space you are much better off getting a MicroPC and a bracket to put it on your monitor than you are getting an all-in-one. This will be about a million percent easier to work on than an all-in-one and this way if your monitor dies your computer is still functional.

Small form factor towers and towers are the easiest to work on and upgrade; if you need a burly graphics card you need to get a full size tower, but for everything else a small form factor tower will be fine. Most of our business sales are SFF towers and MicroPCs, the only time we get something larger is if we have to put a $700 graphics card in it. SFF towers will accept small graphics cards and can handle upgrades to the power supply; MicroPCs can only have the RAM and SSD upgraded and don't have room for any other components or their own internal power supply.

WARRANTY

Most desktops come with either a 1 or 3 year warranty; either of these is fine and if you want to upgrade a 1 year to a 3 year that is also fine. I've generally found that if something is going to do a warranty failure on desktop it's going to do it the first year, so you don't get a hell of a lot of added mileage out of an extended warranty but it doesn't hurt and sometimes pays off to do a 3-year.

Laptops are a different story. Laptops mostly come with a 1-year warranty and what I recommend everyone does for every laptop that will allow it is to upgrade that to the longest warranty you can get with added drop/damage protection. The most common question our customers have about laptops is if we can replace a screen and the answer is usually "yes, but it's going to be expensive." If you're purchasing a low-end laptop, the parts and labor for replacing a screen can easily cost more than half the price of a new laptop. HOWEVER, the way that most screens get broken is by getting dropped. So if you have a warranty with drop protection, you just send that sucker back to the factory and they fix it for you.

So, if it is at all possible, check if the manufacturer of a laptop you're looking at has a warranty option with drop protection. Then, within 30 days (though ideally on the first day you get it) of owning your laptop, go to the manufacturer site, register your serial number, and upgrade the warranty. If you can't afford a 3-year upgrade at once set a reminder for yourself to annually renew. But get that drop protection, especially if you are a college student or if you've got kids.

And never, ever put pens or pencils on your laptop keyboard. I've seen people ruin thousand dollar, brand-new laptops that they can't afford to fix because they closed the screen on a ten cent pencil. Keep liquids away from them too.

LIFESPAN

There's a reasonable chance that any computer you buy today will still be able to turn on and run a program or two in ten years. That does not mean that it is "functional."

At my office we estimate that the functional lifespan of desktops is 5-7 years and the functional lifespan of laptops is 3-5 years. Laptops get more wear and tear than desktops and desktops are easier to upgrade to keep them running. At 5 years for desktops and 3 years for laptops you should look at upgrading the RAM in the device and possibly consider replacing the SSD with a new (possibly larger) model, because SSDs and HDDs don't last forever.

COST

This means that you should think of your computers as an annual investment rather than as a one-time purchase. It is more worthwhile to pay $700 for a laptop that will work well for five years than it is to pay $300 for a laptop that will be outdated and slow in one year (which is what will happen if you get an 8th gen i3 with 8GB RAM). If you are going to get a $300 laptop try to get specs as close as possible to the minimums I've laid out here.

If you have to compromise on these specs, the one that is least fixable is the processor. If you get a laptop with an i3 processor you aren't going to be able to upgrade it even if you can add more RAM or a bigger SSD. If you have to get lower specs in order to afford the device put your money into the processor and make sure that the computer has available slots for upgrade and that neither the RAM nor the SSD is soldered to the motherboard. (one easy way to check this is to search "[computer model] RAM upgrade" on youtube and see if anyone has made a video showing what the inside of the laptop looks like and how much effort it takes to replace parts)

Computers are expensive right now. This is frustrating, because historically consumer computer prices have been on a downward trend but since 2020 that trend has been all over the place. Desktop computers are quite expensive at the moment (August 2023) and decent laptops are extremely variably priced.

If you are looking for a decent, upgradeable laptop that will last you a few years, here are a couple of options that you can purchase in August 2023 that have good prices for their specs:

14" Lenovo - $670 - 11th-gen i5, 16GB RAM, and 512GB SSD

15.6" HP - $540 - 11th-gen i5, 16GB RAM, and 256GB SSD

14" Dell - $710 - 12th-gen i5, 16GB RAM, and 256GB SSD

If you are looking for a decent, affordable desktop that will last you a few years, here are a couple of options that you can purchase in August 2023 that have good prices for their specs:

SFF HP - $620 - 10th-gen i5, 16GB RAM, 1TB SSD

SFF Lenovo - $560 - Ryzen 7 5000 series, 16GB RAM, 512GB SSD

Dell Tower - $800 - 10th-gen i7, 16GB RAM, 512GB SSD

If I were going to buy any of these I'd probably get the HP laptop or the Dell Tower. The HP Laptop is actually a really good price for what it is.

Anyway happy computering.

North America Organic Fertilizers Market Research, Review, Applications and Forecast to 2027

North America Organic Fertilizers Market Forecast to 2027 – COVID-19 Impact and Analysis – By Source (Plant, Animal, and Mineral), Crop Type (Cereals and Grains, Oilseed and Pulses, Fruits and Vegetables, and Others), and Form (Dry and Liquid)

Exploring Growth Opportunities in the North America Organic Fertilizers Market

The North America Organic Fertilizers Market is witnessing steady growth, driven by increasing consumer demand for chemical-free agricultural produce and heightened awareness about sustainable farming practices. As the agricultural industry shifts toward eco-friendly alternatives, organic fertilizers are becoming a critical component in ensuring soil health and long-term productivity.

📚 𝐃𝐨𝐰𝐧𝐥𝐨𝐚𝐝 𝐒𝐚𝐦𝐩𝐥𝐞 𝐏𝐃𝐅 𝐂𝐨𝐩𝐲@ https://www.businessmarketinsights.com/sample/TIPRE00016297

One of the primary drivers of the North America Organic Fertilizers Market is the rising preference for organic food. Consumers are becoming more health-conscious, leading to a surge in demand for organically grown fruits, vegetables, and grains. This growing preference is encouraging farmers across the region to adopt organic fertilizers derived from natural sources such as compost, animal manure, and plant residues.

The North America Organic Fertilizers Market is also benefiting from strong governmental support. Various federal and state-level initiatives promote sustainable agricultural practices and offer subsidies and incentives to farmers who use organic inputs. These policies are fostering a favorable environment for the expansion of the organic fertilizer industry across the United States and Canada.

Technological advancements in organic fertilizer production are further fueling the growth of the North America Organic Fertilizers Market. Innovations in composting techniques, microbial inoculants, and biofertilizer formulations are enhancing product efficiency and shelf-life. These developments help address the traditional concerns related to the slower nutrient release of organic fertilizers, making them more competitive with synthetic alternatives.

📚𝐅𝐮𝐥𝐥 𝐑𝐞𝐩𝐨𝐫𝐭 𝐋𝐢𝐧𝐤 @ https://www.businessmarketinsights.com/reports/north-america-organic-fertilizers-market

𝐓𝐡𝐞 𝐋𝐢𝐬𝐭 𝐨𝐟 𝐂𝐨𝐦𝐩𝐚𝐧𝐢𝐞𝐬

AgroCare Canada

Biostar Renewables, LLC

Coromandel International Limited

Italpollina SpA

Midwestern BioAg

Perfect Blend, LLC

ScottsMiracle-Gro

Suståne Natural Fertilizer, Inc.

In addition, the North America Organic Fertilizers Market is witnessing increased participation from both established agrochemical companies and new entrants focused on sustainable solutions. Strategic collaborations, mergers, and product innovations are shaping the competitive landscape. Companies are expanding their product portfolios to meet the diverse needs of farmers in different climatic and soil conditions across the region.

The market is segmented by source, crop type, and form. Based on source, the North America Organic Fertilizers Market includes plant-based, animal-based, and mineral-based fertilizers. Among these, animal-based fertilizers hold a significant share due to their high nutrient content and effectiveness. By crop type, the market serves cereals, fruits and vegetables, oilseeds, and others. Fruits and vegetables dominate the segment, given the high demand for fresh organic produce.

From a geographical perspective, the United States holds the largest share in the North America Organic Fertilizers Market, followed by Canada and Mexico. The U.S. market benefits from robust agricultural infrastructure, a well-established organic farming community, and strong consumer demand. Meanwhile, Canada is also emerging as a promising market, with increasing investments in organic agriculture and favorable trade policies.

Despite the positive outlook, the North America Organic Fertilizers Market faces challenges such as high production costs and inconsistent nutrient content in organic fertilizers. However, continuous research and development, coupled with rising awareness and education among farmers, are expected to overcome these barriers in the coming years.

In conclusion, the North America Organic Fertilizers Market is poised for significant growth, backed by strong consumer trends, supportive policies, and technological advancements. As the region continues to prioritize sustainability and food safety, the demand for organic fertilizers will continue to rise, making the North America Organic Fertilizers Market a key player in the global shift toward greener agricultural practices.

Organic fertilizers are generally obtained from natural sources such as human excreta, animal matter, vegetable matter, manure, etc. They are the vital elements that help to promote the growth of micro-organisms present in the soil. The nutritional content of the organic fertilizers depends upon their composition. Organic fertilizers are easy to use and are also food safe when compared to synthetic fertilizers. Synthetic fertilizers cause-specific harmful effects on the environment and the living creatures, due to which the companies have developed organic fertilizers to reduce the damage.

North America Organic Fertilizers Strategic Insights

Strategic insights for the North America Organic Fertilizers provides data-driven analysis of the industry landscape, including current trends, key players, and regional nuances. These insights offer actionable recommendations, enabling readers to differentiate themselves from competitors by identifying untapped segments or developing unique value propositions. Leveraging data analytics, these insights help industry players anticipate the market shifts, whether investors, manufacturers, or other stakeholders. A future-oriented perspective is essential, helping stakeholders anticipate market shifts and position themselves for long-term success in this dynamic region. Ultimately, effective strategic insights empower readers to make informed decisions that drive profitability and achieve their business objectives within the market.

North America Organic Fertilizers Regional Insights

The geographic scope of the North America Organic Fertilizers refers to the specific areas in which a business operates and competes. Understanding local distinctions, such as diverse consumer preferences (e.g., demand for specific plug types or battery backup durations), varying economic conditions, and regulatory environments, is crucial for tailoring strategies to specific markets. Businesses can expand their reach by identifying underserved areas or adapting their offerings to meet local demands. A clear market focus allows for more effective resource allocation, targeted marketing campaigns, and better positioning against local competitors, ultimately driving growth in those targeted areas.

Market Overview and Growth Dynamics

The organic fertilizers market in North America was valued at approximately US$ 1,001.48 million in 2018. It is projected to grow at a compound annual growth rate (CAGR) of 10.5% during the forecast period from 2019 to 2027, reaching an estimated US$ 2,442.15 million by the end of 2027. This rapid growth is underpinned by several interrelated factors, including rising consumer awareness of health and food safety, a shift toward environmentally sustainable farming practices, and supportive government policies and subsidies.

Key Market Drivers

1. Surge in Organic Farming Practices

One of the primary growth drivers is the expanding organic farming landscape in North America. Farmers are increasingly transitioning from conventional methods to organic practices, motivated by both consumer demand and economic incentives. Organic farming not only eliminates the use of synthetic pesticides and fertilizers but also emphasizes biodiversity, soil fertility, and ecological balance.

The demand for organic food products continues to rise, fueled by the perception that they are healthier, safer, and more environmentally friendly. This consumer-driven trend is encouraging farmers to adopt organic inputs, including organic fertilizers, to meet the market expectations and maintain certification standards set by agencies like the USDA National Organic Program.

𝐀𝐛𝐨𝐮𝐭 𝐔𝐬:

Business Market Insights is a market research platform that provides subscription service for industry and company reports. Our research team has extensive professional expertise in domains such as Electronics & Semiconductor; Aerospace & Defense; Automotive & Transportation; Energy & Power; Healthcare; Manufacturing & Construction; Food & Beverages; Chemicals & Materials; and Technology, Media, & Telecommunications

You can see this-

North America Electrophysiology Market- https://businessmarketresportsnews.blogspot.com/2025/04/north-america-electrophysiology-market.html

North America HVAC System Market- https://sites.google.com/view/bmi-351/home

North America Debt Collection Software Market- https://postyourarticle.com/north-america-directed-energy-weapons-market-key-players-growth-trends-share-opportunities-forecast-2028/

Motherboard Biostar A68N-2100K http://dlvr.it/TKh1S3

Organic Fertilizers Market set to hit $21.7 billion by 2035

Industry revenue for Organic Fertilizers is estimated to rise to $21.7 billion by 2035 from $11.0 billion of 2024. The revenue growth of market players is expected to average at 6.4% annually for the period 2024 to 2035.

Organic Fertilizers is critical across several key applications including agriculture, landscaping & gardening, animal husbandry and horticulture. The report unwinds growth & revenue expansion opportunities at Organic Fertilizers’s Product Type, Distribution Channel, Application and Consumer Type including industry revenue forecast.

Industry Leadership and Competitive Landscape

The Organic Fertilizers market is characterized by intense competition, with a number of leading players such as Scotts Miracle-Gro, Tata Chemicals Ltd, National Fertilizers Limited, Midwestern Bioag, Italpollina Spa, Ilsa SPA, BioStar Organics, True Organic Products Inc, The Fertrell Company, Sustane Natural Fertilizer Inc, Perfect Blend LLC and Nature Safe.

The Organic Fertilizers market is projected to expand substantially, driven by growing environmental consciousness and rise in organic farming practices. This growth is expected to be further supported by Industry trends like Technological Advancements in Fertilizer Production.

Detailed Analysis - https://datastringconsulting.com/industry-analysis/organic-fertilizers-market-research-report

Moreover, the key opportunities, such as expanding residential gardening, bio-fertilizer technology and developing markets, are anticipated to create revenue pockets in major demand hubs including U.S., China, India, Germany and Brazil.

Regional Shifts and Evolving Supply Chains

North America and Europe are the two most active and leading regions in the market. With challenges like high production cost and lack of awareness, Organic Fertilizers market’s supply chain from raw material procurement / organic fertilizer production / distribution & wholesale to retail & end user applications is expected to evolve & expand further; and industry players will make strategic advancement in emerging markets including Indonesia, Brazil and South Africa for revenue diversification and TAM expansion.

About DataString Consulting

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DataString Consulting is a professional market research company which aims at providing all the market & business research solutions under one roof. Get the right insights for your goals with our unique approach to market research and precisely tailored solutions. We offer services in strategy consulting, comprehensive opportunity assessment across various sectors, and solution-oriented approaches to solve business problems.